construction industry research topics

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179 Construction Research Topics & Essay Examples

Are you looking for current construction research topics? StudyCorgi has compiled a list of research topics in the construction industry for you! Here, you’ll find hot topics in construction management, safety, building materials, technology, and other construction-related civil engineering ideas. Feel free to use these titles for your essays, presentations, research papers, projects, or even as a starting point in your dissertation research.

🏆 Best Construction Topics for Research Papers

✍️ construction essay topics for college, 👍 good construction research topics & essay examples, 🌶️ hot construction topics, 🎓 most interesting construction essay examples, 💡 current construction article topics, 📌 easy construction essay topics.

• The Social Construction of Gender
• The Social Construction of Gender Roles
• Construction of Wembley’s Stadium: Project Management Methodologies
• Social Construction of Gender and Sexual Dichotomy
• Childhood: The Concept of Social Construction
• Assessing Learning and Test Construction
• Stakeholder Management in Construction Projects
• Environmental Impact of the Football Stadium Construction The construction of Football Stadium in the district of Tipner, Portsmouth, UK is a great challenge for the site’s environments and ecological situation.
• Wood as a Construction Material: History, Properties, Use Today, wood is still a common material in the building of boats and houses. The use of wood in the construction of the frames of a majority of domestic houses is also common.
• Renata SA Construction Company’s Project Management Renata SA is one of the prominent construction companies based in the European Union. It is proficient in handling both private and public construction projects.
• Silver Fiddle Construction Project Risk Management When it comes to defining the key risks associated with the project one must point to the fact that the project is very costly and requires a substantial amount of time.
• Construction Waste Management Managing construction waste is often a difficult process because its poor implementation could lead to unintended consequences for contractors, clients, and the public.
• The Social Construction of Aging The social construction of age states that aging occurs because people explain in their mind and physical stages that the body changes are the aging symptoms.
• Risk Management in Healthcare Construction Projects A risk is any occurrence that has the potential to alter the progress of a project significantly. A risk may be positive or negative.
• Construction of Fertilizer Blending Plants in Nigeria: Cost and Schedule Impact Delving deeper into the development of the project under analysis, one will realize that a unique impediment was encountered as OCP Africa started expanding its services.
• Speech Defending the Construction of Bicycle Lanes The purpose of my appeal to the city authorities and the local community is to build bicycle lanes and to create new bicycle routes.
• Postmodern Feminism and Its Theory of Gender as Social Construction Post modern feminists argue that there are no natural building blocks between genders. It is the society that structures human being in a particular way to keep differences.
• Motivation and Performance in UAE Construction Industry One of the most important revelations in the research was that workers and managers in the UAE construction industry were not motivated.
• A Business Plan for a Home Construction Company This paper is a personal business plan for a small company constructing various buildings for disadvantaged individuals, it will also discuss the key strategies for its foundation.
• Fundamentals of Building Construction Foundations are the basis for any construction object, and it is essential for any project to determine the most fitting type of foundation.
• Concrete as a Construction Material Concrete is one of the most widely used construction materials on Earth, so a more detailed analysis of concrete was taken to realize its pros and cons for construction purposes.
• Investment Strategy: Construction of Portfolio The report selects four best-performing equities based on evaluation taste from ten promising stocks listed in New York Stock Exchange.
• Societal and Gender Construction Affecting Incidents of Domestic Violence The paper intends to explore how societal and gender construction can affect the incidences of domestic violence.
• Evaluating Performance of Public Construction Projects in Abuja, Nigeria The purpose of the paper is to provide an in-depth inquiry into the need for a stakeholder performance evaluation framework for public construction projects in Abuja Nigeria.
• Top Ten Construction Site Hazards. In the construction industry, the laborers and site workers are liable to face innumerable dangers and risks of health and safety each day.
• Construction Project Management and Communication As a project manager, I will communicate with the necessary stakeholders and develop a construction project for the client who purchased the property five years ago.
• Role of Tribes in the Construction of Identity Sine tribes create a sense of belonging by reinforcing the significance of the marker of social hierarchy and the importance of compliance with set traditions.
• Engineering, Procurement and Construction Strategy Saudi Arabia boasts one of the largest oil and gas reserves in the world. The resource is characterized by high price fluctuations that impact the government’s budget.
• Achieving Success in Construction Project Management The effective implementation of construction programs depends on many factors, among which the management of construction organizations can be identified.
• Schedule Delay Analysis in Construction Projects Within a construction environment, it is rather common that both the contractor and employer are worried about the time for performance.
• Dubai Construction Cost and Its Political Factors This research paper determines how political factors affect the construction industry in Dubai and what can be done to lower these costs.
• Lobby Café Construction Project Evaluation The report aimed to analyze three aspects of the Lobby Café Construction project: external factors, stakeholder analysis, and assessment of corporate social responsibility.
• Use of Modern Construction Materials Concrete is an architectural material composed of a strong, noncorrosive particle material called aggregates, typically sand and pebbles.
• Construction and Operation of the London Eye The current assignment examines the construction and operation processes of the London Eye and provides a comprehensive analysis of the project.
• The Construction Management Position Observation Construction projects constantly need modifications, and in this sense, construction management is the key to the stability of the entire procedure.
• Social Construction of Serial Killers Serial killing is a homicide category occurring when an offender murders more than three victims unknown to the criminal.
• Shortage of Skilled Workers in Middle East Construction Industry The construction industry in the Middle East has been facing the risk of rising labour costs and labour shortages, which in turn is squeezing up the smaller contractors.
• Construction Law. Negligence, Tort and Duty of Care The cases Chapman v. Hearse and Voli v IngleWoodshire Council are both legal cases that were tried in the High Court of Australia in the years 1961 and 1963 respectively.
• Construction Industry Disputes in the UAE There is still very little literature in the UAE on the negotiation strategies and how the same impacts on the outcomes in the dispute resolution.
• Soil Mechanics in Construction Engineering Soil mechanics is a relatively new discipline in civil engineering, which entails the study of the engineering properties of soil relative to the design of various engineering structures.
• WestProp Development Ltd.’s Construction Projects WestProp Development Ltd has shown interest in developing 25 North Row W1K6DJ buildings for mixed purposes in Mayfair, London.
• Construction: Characteristics and Reliability of Piles and Props The construction requires a solid and water-resistant system. The secant pile wall provides this opportunity and increased alignment flexibility in construction
• Critical Path Method in Construction Practice The critical path method has a significant role to play in managing resources on construction projects by relating time and money.
• Construction Management and Law in United Kingdom: An Analysis The essay discusses the current legal requirements for constructing a building in the UK and details various legal procedures involved in handling the building projects in the UK.
• The Construction Industry in Australia. The construction industry in Australia commands some significant linkages with other key sectors, and this has led to its major impact on the economy.
• Sexual Orientation as a Social Construction and Reality Even if sexual orientation, gender roles, and sex are all socially constructed, it does not mean that they are not real.
• Gray Construction Company’s Business Communication Gray Construction is a family-owned construction company that, by utilizing the system of open forums, tries to increase the success of business-related communications.
• Saudi Marine Construction Projects and Risks The Saudi Arabian marine construction works revolve around the establishment of ports and harbors. The ports must be constructed to facilitate tourist arrival.
• Construction Project Implementation There are many variations of construction project implementation, the most common are Design-Bid-Build and Multiple Prome Contracts.
• Enhancing Construction Safety Through ASTM Standards and Technology This text discusses the importance of construction safety, focusing on ASTM standards and technological advancements.
• Construction Management at Risk: A New Hospital in Baton Rouge Construction management at risk is the most appropriate project delivery method for the health organization’s plan to build a new hospital in Baton Rouge.
• R. G. Letourneau’s Contributions to the Construction Industry Field The paper states that LeTourneau made tremendous contributions to the construction industry field. His legacy has been a foundation of modern scholars.
• Construction Safety and Its Importance Construction safety is important because working together, the owner and the contractor secure the high quality of work and enhance the general well-being of employees.
• Aspects of Social Construction The paper states that social construction examines how people learn about their surroundings and the world in general, which influences some changes.
• R&B Construction Company: Organizational Culture One of the essential factors in an organization’s success is its culture which are the values, beliefs, and visions that unite an organization.
• The Social Construction of Reality SOLO taxonomy should be considered a valuable analytical instrument in terms of application to the complex challenges of the modern era.
• Why to Learn Construction and Engineering Skills Basic construction and engineering skills can enable a person to successfully engage in the work of their own house and be able to start a new technical career.
• Towards Green Construction: Timber as Material Timber appears to be a beneficial option for the construction of a variety of buildings. Its cost efficiency is evident in the construction process.
• The Aircraft Runways Construction The construction of aircraft runways must be constructed by individual runway design, based on the direction of the winds and aeronautical paths, and immediate terrain.
• Development Plan at Olive Construction Company Olive Construction Company was founded in 2019 to tap into the booming construction industry in Miami Dade County.
• Construction of Knowledge in Society Knowledge is constructed by society facing informational cascades and being disinformed. As a result, people lose confidence in particular institutions.
• Civil Rights Movement and Construction of US Racism Racism is associated with slurs, Islamophobia, police brutality, and Donald Trump. This list signals that racism today is a more insidious, politicized form of discrimination.
• The Influence of the Gospel on the Construction of the Christian Worldview The paper considers the essentials of the Gospel that influence the construction of the Christian worldview and form a behavioral framework.
• Drug Dependency: Construction of a Rehabilitation Center Creating a program that would act as a foundation to help drug addicts recover from drug usage would help lessen drug dependency.
• Progressivism and Its Role in American Social Construction Progressivism arose as political development, its center thought was that administration played a significant part in monetary guidelines and colonial government assistance.
• Social Construction of Race and Gender in the United States and Brazil Being able to categorize the general population into specific groups based on certain characteristics is vital for understanding how people see themselves and others.
• Social Construction of Gender. Sociology in Modules Sociobiology entails the scientific study of social behavior’s biological bases among humans and even animals. It assumes that such behavior arises from the evolution.
• Power Suburbs and the Construction of Race by Nicolaides & Wiese Becky M. Nicolaides and Andrew Wiese discuss suburbanization and its effects on racial segregation in postwar America.
• Foodmart vs. Masterpiece Construction Dispute: Contract Formation The subcontracting of Masterpiece construction in the renovation of Foodmart’s Main Street store is valid and the former has the right to delegate its duties of the contract.
• Construction Materials and Building Codes Platform framing system is commonly used in the building industry because the building that is made using this method is always durable and have high structural integrity.
• Construction Management: Organizations, Cash Flow & Controls on Site This paper discusses organizations, cash flow, and controls on-site: types of organizations, project cash flows, certification programs, cost control as a management tool.
• Water Cooling Tower Construction Site’s Problems The paper highlights three major problems at the construction site. They are security, scheduling, and safety problems.
• The Deployment of WLAN (WI-FI) on Open Area Construction Projects This paper sets out to illustrate that implementation of mobile communication technologies in the construction industry is not only technologically and economically feasible.
• Economic Environment for a Construction Firm The construction industry is plagued by a lot of difficulties in the UK and other parts of the world. This study mainly focuses on economic conditions affecting construction firms.
• GPS Surveying and Laser Total Station Surveying Within Construction This essay intends to establish the main differences between GPS surveying and Laser total station surveying within the construction and single out their respective applications.
• Race: Genetic or Social Construction One of the most challenging questions the community faces today is the following: whether races were created by nature or society or not.
• Tunnel Design and Construction The paper concerns the many significant advances in technology that have facilitated tremendous growth in the tunneling industry.
• Construction of the Sense of Meaning and Identity The most contributing factors to the construction of human sense of meaning and identity are relational processes between person and group, as well as different social processes.
• A New Building Construction Project Analysis The management of AXBC PLC needs to allot more time for constructing a new building as the analysis has clearly shown that the management may be overly optimistic.
• Gender Construction and Heterosexism Homophobia, or the aversion for people who have same-sex preferences, are categorized under personal, interpersonal, institutional and societal.
• The Study of the Construction Methods for Firefighters The study of the construction methods allows the fire officers to predict the effects of the demolition and possible way to preserve the construction in a better condition.
• Construction Companies and Ethics Many construction companies do not have an ethical program at all. It is important that people in the company undergo training in order to understand the ethical standards that have been set.
• Project for the Construction of a New Cottage Town The project is devoted to the building of the new cottage town in the country and is aimed at the satisfaction of citizens’ needs and providing them with a new wonderful way of life.
• Shortage of Skilled Workers and Its Impacts in Middle East Construction Industry Presently there is a huge shortage of structural and civil engineers, project managers, safety managers, on-site supervisors and tradesman, like welders and fitters.
• Construction. The Hines Group and Babcock & Brown The Hines Group and Babcock & Brown provide the highest standards of security of workers and the best organization of the material delivery, storage, and usage.
• The Range of Regulations Applicable to Health and Safety in Construction The regulatory systems have done more good than bad in the general growth of safety conditions for workers in the European Union.
• Carillion Construction Company’s Story of Decline This report analyses the Carillion company’s performance, identifies some causes for its decline, and discusses the roles of the directors and auditors in it.
• Generational Differences in Galliford Try Construction Industry The study illuminates how various challenges affect the company and aligns them with theories such as transformational, authentic, servant leadership and leader-member exchange (LMX).
• Authentic Leadership in the Construction Industry This paper seeks to examine the concept of authentic leadership and why it can become the best option for improving management and supervision in the construction industry.
• Family, Work, and Social Construction of Intimacy The paper examines various aspects of family life and the real problems of families. The work-family relationship may sometimes result in work-family conflict.
• “Uncoupling: The Social Construction of Divorce” by Robboy et al. This paper aims to analyze the article “Uncoupling: The Social Construction of Divorce” by Robboy et al. and summarize the main ideas from it.
• Ethics: Tellico Dam Construction vs. Snail Darter Fish The argument against the Tellico dam construction concerns the role of the snail darter in the ecological system of the Little Mississippi River.
• Poverty and Homelessness: Dimensions and Constructions With the growth of the economy and the failure of employment, the number of people living in poverty and without shelter increases.
• Race as a Social Construction in the US The idea of the social construction of race is the basis on which modern theory refutes the initial assumptions used to justify the American practice of slavery.
• Cultural Rift in the UAE Construction Industry This paper will explore cultural differences and organizational cultures in the UAE. It will also explore ways of harmonizing the two to minimize conflicts.
• Portfolio Construction: Choosing a Suitable Investment Option Investing in trustworthy and promising ventures so that the specified goal can be achieved can be viewed as the secondary objective of the project.
• Risk Management of Construction Megaprojects Long-term projects can be considered an integral part of the modern world. At the same time, the management of projects is a complex task because of many issues and obstacles.
• Construction Company’s Operational Risk Management This work presents an operational risk assessment connected to standard masonry techniques and procedures in the development of five-story apartment blocks.
• Canadian Housing and Construction Statistics Growth for housing starts, completions, and under construction was negatively affected by the economic downturn in 2008 with only 187,923 units registered.
• Truss Construction Shop Workplace Incident This paper analyzes the incident that occurred in the Truss Construction Shop when a worker was injured while performing his work with the help of a machine.
• Quality Improvement in the Construction Industry’ Context Focusing on quality improvement is essential in the context of a multicultural corporation. The introduction of the Six Sigma DMAIC framework was tested as a possible tool.
• Construction Company’s Staff’s Quality Performance The purpose of the study is the identification of the links between the application of the diversity-related strategies, the motivation of the employees, and the staff’s rates.
• Madina Azahra Palace Construction Medina Azahara means the City of Flowers and it represents the ruins of the fortified Arab Muslim medieval palace in Spain. The palace was built in 929 by Abd al-Rahman.
• Social Construction of Technologies: Tablet Computer This paper is aimed at discussing the development of such a technology as the tablet computer. In particular, it is necessary to apply such a concept as social construction.
• “The Construction of Homosexuality” a Book by David Greenberg The book, The Construction of Homosexuality by David Greenberg presents the reflection of the author on historical timeline of the struggle by homosexuals to get their rights.
• Construction of the America’s Great Wall The paper highlights some of the reasons why the Great Wall was a bad idea. The government realized that the control act did not give the expected results.
• Social Community Constructions, Expected Social Conduct, and Economic Structures Within the Society This paper outlines social community constructions, expected social conduct, and economic structures within the society.
• Intermediate Institutions and Technology Transfer in Developing Countries: Construction Industry in Ghana
• Building for the Future: The Potential Importance of the Construction Industry in Welsh Economic Development Policy
• Global Construction Equipment Market Industry Analysis
• Waste Processing Plants Construction in Saudi Arabia
• Investigation Into Waste Management on Construction Sites in South Western Nigeria
• Waste Processing Plants Construction in India
• Improving Health and Safety on Construction in Romania
• Channel Tunnel Construction: Project Management
• Indonesia Residential Construction: Market Update
• Improving Higher Education for Construction Management
• Worker’s Attitudes Towards Safety in the Construction Field
• Case Studies About Australian Construction Firms
• Chinese Culture and Successful Implementation of Partnering in Singapore’s Construction Industry
• Iowa River Bridge Steel Method Construction
• Civil Engineering: Bridge Construction Issues
• Good Research Paper About Planning of Construction of Tall Buildings
• Transforming Municipal Solid Waste Into Construction Materials
• Chemical and Pharmaceutical Plants Construction in India to 2019
• Building Information Modelling Analysis Construction
• Ethical Case Study Bhopal Disaster Construction
• Global Market for Agricultural and Construction Equipment
• Ireland Industrial Construction: Market Update
• Incorporating the Lean Cell Process Into Repair Stations Construction
• Environmental Impacts From Dam Construction
• Improving Construction Site Safety
• Internet Marketing Strategy for Small Construction Firms
• Cdm Baseline Construction for Vietnam National Electricity Grid
• Analyzing the Malaysian Construction Industry
• Building Plan Commission, Construction, and Alterations
• Commercial Bank Lending Practices and the Development of Black-Owned Construction Companies
• Industry Research- Construction, Homebuilding
• Housing Demand and Residential Construction in Thailand
• Establishing Quantitative Indicators for Measuring the Partnering Performance of Construction Projects in Hong Kong
• Establishing the Association Between Collaborative Working and Construction Project Performance Based on Client and Contractor Perceptions
• Institutional Capacity for Climate Change Responses: An Examination of Construction and Pathways in Mexico City and Santiago
• Innovative Construction Technology for Affordable Mass Housing in Tanzania, East Africa
• Collaboration Environments for Small and Medium-Sized Architecture, Engineering and Construction Enterprises
• Total Quality Management and the Learning Organization: A Dialogue for Change in Construction
• Client-Led Strategies for Construction Supply Chain Improvement
• Indian Construction Industry and Risk Assessment Construction
• Analyzing the Drivers for Early Contractor Involvement Adoption by Construction Clients
• International Construction: Floor Packaging Method
• How Dilation Was Used in the Construction of the Pyramids of Egypt
• Workplace Injuries and Fatalities in the UK Industry Construction
• Close Entanglements: Aligning the Construction and Finance Industries
• Interaction Between the Economic Growth and the Construction Industry
• Germany’s Construction Industry: Stabilization on the Horizon
• Welfare Facilities During Construction Work
• The Ethical Issue, or Issues, Affecting the Construction Industry Today
• Whether the Construction Industry Is the Pillar Industry in Hong Kong?
• United Kingdom Residential Construction: Market Update
• Issues, Problems and Risks in Construction Projects and Ways of Mitigating Them
• Good Faith and Co-operation Under Construction Contracts in UK
• Health and Safety Considerations for the Construction
• Worker Flows, Entry and Productivity in the New Zealand Construction Industry
• Building Methods and Policies That Govern the Construction
• Building Construction Types for People in the Fire Service Field
• Ziggurats Their Construction and Uses in Ancient Mesopotamia Irrigation Systems
• Greece Industrial Construction: Market Update
• Business E-solutions for Small Construction Companies
• Architect E.j Lennox’s American Courthouse Construction
• Houston and the Global Market for Engineering and Construction
• Waste Minimizing and Recycling in Construction
• Understanding the Divergence Between Output and Employment in the UK Construction Industry
• Information Technology and the Construction Contractor
• Capital Structure and Return on Capital Employed of Construction Companies in Nigeria
• Intellectual Capital, Knowledge Sharing, and Innovation Performance: Evidence From the Chinese Construction Industry
• Workflow Software for Building and Construction Companies
• German Construction Industry: New Residential Construction at Cyclical Peak – Public Construction Gaining Ground
• Transaction-Related Issues and Construction Project Performance
• Chinese Urban Residential Construction to 2040
• Work Health and Safety, Competitive Advantage, and Organisational Performance in Small Construction Firms

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StudyCorgi . 2021. "179 Construction Research Topics & Essay Examples." September 9, 2021. https://studycorgi.com/ideas/construction-essay-topics/.

These essay examples and topics on Construction were carefully selected by the StudyCorgi editorial team. They meet our highest standards in terms of grammar, punctuation, style, and fact accuracy. Please ensure you properly reference the materials if you’re using them to write your assignment.

This essay topic collection was updated on June 21, 2024 .

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Construction Engineering Dissertation Topics

Published by Carmen Troy at January 5th, 2023 , Revised On May 20, 2024

The development of construction engineering has significantly influenced the way our society has grown over the last few decades. Recent research in sustainable construction has been much emphasised in the civil engineering industry. The world is now moving towards systems that are considered adaptable, sustainable, viable, and environmentally friendly.

Many developed countries, including the United Kingdom, have developed pathways towards this future in Vision 2030 and even 2050. There are various exciting research opportunities for students when selecting their construction engineering dissertation topic .

To help you get started with brainstorming for construction engineering topic ideas, we have developed a list of the latest topics that can be used for writing your construction engineering dissertation.

These topics have been developed by PhD-qualified writers of our team , so you can trust to use these topics for drafting your dissertation.

You may also want to start your dissertation by requesting  a brief research proposal  from our writers on any of these topics, which includes an  introduction  to the topic,  research question ,  aim and objectives ,  literature review  along with the proposed  methodology  of research to be conducted.  Let us know  if you need any help in getting started.

Check our  dissertation examples  to get an idea of  how to structure your dissertation .

Review the full list of  dissertation topics for 2022 here.

Latest Construction Engineering Dissertation Topics

Topic 1: the impact of virtual reality on enhancing customer experience and decreasing on-site visits to construction projects.

Research Aim: The aim is to evaluate the impact of virtual reality on enhancing customer experience and decreasing on-site visits to construction projects

Objectives:

• To understand the significance of incorporating VR in the UK construction projects
• To analyse the effect of VR on enhancing customer experience
• To examine the impact of VR on reducing the number of on-site visits

Topic 2: The incorporation of AI in UK based construction projects to forecast costs accurately and mitigate safety and productivity issues

Research Aim: The aim focuses on examining how the incorporation of AI in UK construction projects can help in forecasting costs accurately and mitigating safety and productivity issues

• To explore the significance of incorporating AI in construction projects
• To evaluate how forecasting of costs can be done accurately with the incorporation of AI in the UK construction projects
• To understand how safety and productivity issues can be mitigated effectively with the integration of AI in UK construction projects

Topic 3: The impact of workforce restrictions and supply chain disruptions due to the coronavirus pandemic on the growth of the UK construction sector

Research Aim: The research aim concentrates on exploring the impact of workforce restrictions and supply chain disruptions due to the coronavirus pandemic on the growth of the UK construction sector

• To evaluate the different impacts of the coronavirus pandemic on the UK construction sector
• To determine how supply chain disruptions due to the pandemic have influenced the growth of the UK construction sector
• To examine how workforce restrictions due to this pandemic have impacted the growth of the UK construction sector

Topic 4: The importance of five elements of Business Information Modeling and how these elements of BIM are minimising operation costs and increasing the productivity in UK construction projects

Research Aim: The aim is to evaluate the importance of five elements of Business Information Modeling and how these elements of BIM are minimising operation costs and increasing productivity in UK construction projects

Objectives :

• To understand Business Information Modeling and its five elements
• To determine how these elements of BIM are minimising operation costs in the UK based construction projects
• To examine how these elements of BIM are increasing the productivity  in the UK based construction projects

Topic 5: An examination of different ways through which a site waste management plan in UK construction projects helps in using recyclable products and mitigating contamination

Research Aim: The research aim explores different ways through which a site waste management plan in UK construction projects helps in using recyclable products and mitigating contamination

• To examine the importance of the site waste management plan in UK construction projects
• To determine how an efficient site waste management plan can help in recycling waste products
• To evaluate how an efficient site waste management plan can aid in mitigating contamination

List Of Top Construction Engineering Dissertation Topics

• Utilisation of renewable energy resources in the development of sustainable homes
• Sustainability and its impact on societies; Visualising a constructive future.
• Achieving sustainability from properties of concrete; Analyses of the recent research and developments.
• The lean manufacturing techniques and the role of management in construction
• Construction Safety; is there a need to revise or re-model the practices/legislations, reviewing the accidental trends and role of legislation?
• Multilingual safety in construction; reviewing the current industrial practices and the need to improve, highlighting the actual issues of migrant workers in the construction industry
• Analysis of the impact of the latest technology in the construction Industry
• The role of Business Information Modelling (BIM) in the Construction Industry; assessment of practices, management, and productivity through such computer-aided tools
• Procurement techniques; analyses of the most suited procurement strategies in the construction industry
• Is there a need for an integrated model that can replace all other management tools? Review of how the construction industry can be revolutionised through the use of state-of-the-art computer-aided techniques
• Construction Management; highlighting the best practices in modern construction projects
• Zero carbon structures; use of technology to develop zero-carbon buildings
• Waste minimisation in construction projects; identifying the best practices
• Use of Waste in construction; how demolition can be modelled to construct new structures
• Construction materials analyses; timber, steel, or concrete? Investigation of materials for optimum material utilisation.
• Design of Effective ventilation systems in high-rise buildings
• How Is Building Information Modeling (BIM) Transforming Construction Project Delivery?
• Is Prefabricated Construction A Sustainable Solution for Affordable Housing?
• The Role of Virtual Reality (VR) in Construction Design and Training
• Can drones be used in construction to increase transparency and traceability?
• The Impact of Brexit on Construction Material Supply Chains and Costs
• The Impact of big data analysis in prediction in the construction industry 
• The Impact of Autonomous Vehicles on Construction Logistics and Transportation
• The Role of Community Engagement in Large-Scale Construction Projects
• The Challenges and Opportunities of High-Performance Buildings

COVID-19 Civil Engineering Research Topics

Construction engineering after coronavirus: identify the consequences of covid-19 on construction engineering in the uk or any country of your choice..

Research Aim: This research will focus on identifying the impacts of Coronavirus on construction engineering in the selected country.

Research to study the damage caused to the construction projects due to the lack of workers on site.

Research Aim: This study will focus on identifying the damage caused to construction projects as the workers are staying away from the sites. What measures are taken to complete these projects and recover the loss?

Contractors and Builders after COVID-19: business industry, tender opportunities, and planning to continue business.

Research Aim: This research aims to identify the conditions faced by contractors and builders. What is their plan to deal with the COVID-19 crisis? How did it affect the business industry and tender opportunities?

Cite Operating Procedures: research the various safety measures for workers, contractors, and engineers working on construction sites.

Research Aim: This research is conducted to know about various safety measures taken by the government and private organisations for workers, contractors, and engineers working on construction sites.

Investigate how civil engineers are working from home: Identify whether remote working can be a long-lasting solution to recover the loss caused by COVID-19.

Research Aim: Remote working has emerged as a ray of hope for mechanical engineers amid this pandemic. This research will focus on the advantages and disadvantages of remote working and also answer the question of whether it is a long-lasting solution or not.

Research to study the economic and labour crisis as a result of Coronavirus.

Research Aim: This research will focus on the financial loss and labour crisis caused by the outbreak of the Coronavirus pandemic.

Research to study the disruption of the supply chain, shortage of contractors, workers, and material, and cancellation of contracts due to COVID-19

Research Aim: This research will focus on identifying the disruption of the supply chain, shortage of contractors, workers, and materials, and cancellation of contracts due to COVID-19.

Research to throw light on the future of the construction Industry after the Coronavirus pandemic.

Research Aim: This research will predict how the construction industry will transform after the COVID-19 pandemic. What challenges it may face, and what could be the possible ways to meet those challenges?

Also Read:   Mechanical Engineering Dissertation Topics

Note: Some of these topics may require students to undertake primary research, which includes developing questionnaires, survey forms, and interviews, whilst others are based on desk-based research.

How Can ResearchProspect Help?

ResearchProspect writers can send several custom topic ideas to your email address. Once you have chosen a topic that suits your needs and interests, you can order for our dissertation outline service , which will include a brief introduction to the topic, research questions , literature review , methodology , expected results , and conclusion . The dissertation outline will enable you to review the quality of our work before placing the order for our full dissertation writing service !

Important Notes

As a construction engineering student looking to get good grades, it is essential to develop new ideas and experiment with existing construction engineering theories – i.e., to add value and interest to your research topic.

The field of construction engineering is vast and interrelated to so many other academic disciplines like  civil engineering , chemical engineering , mechanical engineering , engineering and more. That is why it is imperative to create a construction engineering dissertation topic that is particular and sound and actually solves a practical problem that may be rampant in the field.

We can’t stress how important it is to develop a logical research topic; it is the basis of your entire research. There are several significant downfalls to getting your topic wrong: your supervisor may not be interested in working on it, the topic has no academic creditability, the research may not make logical sense, and there is a possibility that the study is not viable.

This impacts your time and efforts in  writing your dissertation , as you may end up in a cycle of rejection at the very initial stage of the dissertation. That is why we recommend reviewing existing research to develop a topic, taking advice from your supervisor, and even asking for help in this particular stage of your dissertation.

While developing a research topic, keeping our advice in mind will allow you to pick one of the best construction engineering dissertation topics that fulfil your requirement of writing a research paper and add to the body of knowledge.

Therefore, it is recommended that when finalising your dissertation topic, you read recently published literature to identify gaps in the research that you may help fill.

Remember- dissertation topics need to be unique, solve an identified problem, be logical, and be practically implemented. Take a look at some of our sample construction engineering dissertation topics to get an idea for your own dissertation.

How to Structure Your Dissertation on Construction Engineering

A well-structured   dissertation can help students   to achieve a high overall academic grade.

• A Title Page
• Acknowledgements
• Declaration
• Abstract: A summary of the research completed
• Table of Contents
• Introduction : This chapter includes the project rationale, research background, key research aims and objectives, and the research problems. An outline of the structure of a dissertation can also be added to this chapter.
• Literature Review :  This chapter presents relevant theories and frameworks by analysing published and unpublished literature available on the chosen research topic in light of the research questions to be addressed. The purpose is to highlight and discuss the relative weaknesses and strengths of the selected research area whilst identifying any research gaps. Break down of the topic, and key terms can positively impact your dissertation and your tutor.
• Methodology: The  data collection  and  analysis methods and techniques employed by the researcher are presented in the Methodology chapter, which usually includes  research design, research philosophy, research limitations, code of conduct, ethical consideration, data collection methods, and  data analysis strategy .
• Findings and Analysis: Findings of the research are analysed in detail under the Findings and Analysis chapter. All key findings/results are outlined in this chapter without interpreting the data or drawing any conclusions. It can be useful to include  graphs , charts, and   tables in this chapter to identify meaningful trends and relationships.
• Discussion and  Conclusion: The researcher presents his interpretation of the results in this chapter and states whether the research hypothesis has been verified or not. An essential aspect of this section of the paper is to link the results and evidence from the literature. Recommendations with regard to the implications of the findings and directions for the future may also be provided. Finally, a summary of the overall research, along with final judgments, opinions, and comments, must be included in the form of suggestions for improvement.
• References:  This should be completed in accordance with your University’s requirements
• Bibliography
• Appendices: Any additional information, diagrams, and graphs used to complete the  dissertation  but not part of the dissertation should be included in the Appendices chapter. Essentially, the purpose is to expand the information/data.

About ResearchProspect Ltd

ResearchProspect is a  UK based academic writing service that provides help with  Dissertation Proposal Writing ,  PhD Proposal Writing ,  Dissertation Writing ,  Dissertation Editing, and Improvement .

Our team of writers is highly qualified. They are experts in their respective fields. They have been working in the industry for a long time and thus are aware of the issues and trends of the industry they are working in.

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How to find dissertation topics about construction engineering.

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• Investigate emerging technologies.
• Explore sustainability challenges.
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• Consider safety innovations.
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• Consult experts and industry sources.

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Discovering the research topics on construction safety and health using semi-supervised topic modeling.

1. Introduction and Background

2. research methods, 2.1. latent dirichlet allocation (lda) and correlation explanation (corex), 2.2. semi-supervised topic modeling, 2.3. methods of the proposed study, 2.3.1. data collection, 2.3.2. text mining, 2.3.3. topic modeling, 3. results and discussion, 3.1. publication trends, 3.2. trigrams and bigrams, 3.3. topic models results, 3.4. research trends and insights, 4. conclusions and future work.

• The application of NLP techniques on a large dataset containing the titles, keywords, and abstracts of research papers from the construction safety and health domain;
• The comparison between the performances of four different topic models, two unsupervised ones and two semi-supervised ones, and the identification of the best-performing model;
• The identification of research topics in the construction safety and health domain and the analysis of their chronological trends over the past three decades;
• The discovery of the interconnection between different research topics as well as the discussion on their standalone most representative publications.

Author Contributions

Data availability statement, conflicts of interest.

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Zhou, K.; Wang, J.; Ashuri, B.; Chen, J. Discovering the Research Topics on Construction Safety and Health Using Semi-Supervised Topic Modeling. Buildings 2023 , 13 , 1169. https://doi.org/10.3390/buildings13051169

Zhou K, Wang J, Ashuri B, Chen J. Discovering the Research Topics on Construction Safety and Health Using Semi-Supervised Topic Modeling. Buildings . 2023; 13(5):1169. https://doi.org/10.3390/buildings13051169

Zhou, Kai, Jun Wang, Baabak Ashuri, and Jianli Chen. 2023. "Discovering the Research Topics on Construction Safety and Health Using Semi-Supervised Topic Modeling" Buildings 13, no. 5: 1169. https://doi.org/10.3390/buildings13051169

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Home » Blog » Dissertation » Topics » Construction » Construction Dissertation Topics (26 Examples) For Research

Construction Dissertation Topics (26 Examples) For Research

Mark Jun 12, 2020 Jun 12, 2020 Construction No Comments

If you are looking for some highly interesting construction dissertation topics, you have visited the right place. Here, you can find a range of construction dissertation topics and project topics on construction. Along with the list of construction dissertation topics and research topics on construction, we also help in formulating your objectives, proposal, literature review, […]

If you are looking for some highly interesting construction dissertation topics, you have visited the right place. Here, you can find a range of construction research topics for your research project.

Along with the list of construction dissertation topics and research topics on construction, we also help in formulating your objectives, proposal, literature review, methodology, and analysis. You can also explore the list of building surveying dissertation topics to get more ideas for your dissertation topics.

List of Construction dissertation topics

Exploring a forward-thinking solution to the housing crisis in Australia by evaluating the modern methods of construction..

A study of innovative solutions in the construction industry reviewing the events and trends of 2014 to 2018.

Exploring the driving factors of construction industrialisation development in the developing countries.

An evaluation of the traditional methods for maintenance of mud houses to promote environmental sustainability in Nigeria.

Analysing the solution for future designs using techniques from vernacular architecture in developing countries.

Investigating and identifying the key indicators for sustainable construction materials.

An analysis of user criteria in the context of sustainability of modern methods of construction based on wood.

A literature review on dilemmas faced by the architects and designers related to the paradigms of sustainable development.

The importance of materials management in construction – an exploratory study.

A comparative analysis of the modern practices in project management of engineering and construction projects in the UK.

A review of some of the factors leading to construction project delays.

Exploring government construction projects in Australia and finding ways to improve the construction contract management.

The study of virtual information modelling acceptance based on project management knowledge areas.

Analysing the importance of cost management in construction projects.

Evaluating the effects of cost overrun in construction projects.

Studying the importance of construction health and safety management and its impact on the success of construction projects.

Reviewing the simulating uncertainties in the construction projects.

Analysing the new measures of circular economy thinking in construction companies.

Investigating the losses and productivity parameters in construction projects.

Studying the recent trends related to construction automation.

A study on the green tunnel construction technology and application.

An analysis of the construction technology of roof steel structure in developing countries.

How is technology shaping the future of the construction industry around the world?

What are the political and economic risks in international construction projects?

An evolution of the modular construction industry growth and its impact on the built environment.

Analysing the impact of IT technology convergence innovation on the performance of construction projects.

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The importance of research in construction

The construction industry has an established history of research focusing on project design, planning and execution. While this work has advanced and improved the industry, in recent years the role of the craft professional has emerged as another topic of study. This type of research blends traditional construction research methods with human research methods from the social sciences.

This area of research can have a major influence on the business of construction. It provides a great opportunity to improve company performance and change the lives of individuals across the industry. It can also help show industry leaders and decision makers where we are, where we're going and what threats or opportunities there may be out there. 

At the National Center for Construction Education and Research (NCCER) , we believe research is important enough to include in our name. The research our organization conducts helps guide us in our mission to develop a safe, productive and sustainable workforce. 

Here are some of the ways research provides benefits for the construction industry.

Research helps set industry benchmarks

Basic research is important to set year-to-year data benchmarks for the construction industry. Some examples of these types of numbers include the amount of active construction companies, the number of people employed by the industry  and the monetary value of the projects being worked on.

Having these basic facts available for reference helps us understand the size and scale of the industry as it currently stands. It’s also useful to compare data to previous years. By having the same data recorded for multiple years, you can discover trends and make predictions. Is the industry growing, or is it downsizing? What are some events on the timeline that may be affecting those figures? What can we expect future years to look like, and how can we best prepare for them?

Research helps the industry understand the workforce shortage

It’s no secret the construction industry has long been facing a shortage of skilled professionals. Doing research and gathering relevant information about the causes of the skills gap and the resulting symptoms helps us understand the situation and develop appropriate solutions.

One example of a revealing statistic is the average age of a construction craft professional. The average construction worker is 42.9 years old , compared to the average age of a U.S. citizen of 38.5 years old. This indicates that most craft professionals tend to be older – with many nearing retirement age – and there are not enough younger entrants into the industry to offset or balance this aging workforce.

The workforce shortage is a complex issue with numerous factors. Research helps to outline those factors, and analysis can provide prescriptions for efforts to make a difference. 

Research helps the industry with recruiting and marketing

While research can reveal some areas of needed improvement, it can also showcase the ways the industry is succeeding and excelling. In the ongoing efforts to recruit new talent into the skilled trades, it can be effective to highlight these positive statistics.

In a recent study, NCCER found the average base salaries for construction careers continues to rise. Research also indicates that people working in the construction industry have a higher rate of job satisfaction than other industries do. 

Data like this can be used in marketing efforts by construction companies and training organizations to attract individuals to the industry. Combining anecdotal or testimonial content about the benefits of working in construction with true research that backs up those statements creates a more well-rounded and persuasive campaign.

Construction research from NCCER

How can research and data benefit your construction business? 

Visit NCCER’s research page to check out our studies and analysis about the construction industry, workforce development and construction education.

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102 Construction Essay Topic Ideas & Examples

Inside This Article

Construction is a vast field that encompasses various aspects, ranging from building structures to project management. If you are studying construction or related disciplines, you may find yourself in need of essay topics to explore and analyze. To assist you in your academic journey, we have compiled 102 construction essay topic ideas and examples. Whether you need to write a research paper, argumentative essay, or any other type of construction-related essay, these topics will provide you with ample inspiration.

• The impact of climate change on construction practices.
• The role of sustainable materials in green building.
• The challenges of implementing Building Information Modeling (BIM) in construction projects.
• The advantages and disadvantages of prefabricated construction methods.
• The impact of robotics and automation on construction industry jobs.
• The importance of safety regulations in the construction industry.
• The impact of COVID-19 on the construction industry.
• The role of construction project management software in improving efficiency.
• The ethical considerations in construction project bidding processes.
• The role of architects in the construction industry.
• The future of construction: exploring innovative technologies.
• The impact of urbanization on construction practices.
• The challenges of managing construction projects in developing countries.
• The role of government regulations in sustainable construction practices.
• The use of drones in construction site monitoring and surveying.
• The impact of globalization on the construction industry.
• The importance of effective communication in construction projects.
• The challenges of constructing earthquake-resistant buildings.
• The role of construction industry apprenticeships in fostering skilled workers.
• The impact of social media on construction marketing strategies.
• The use of virtual reality (VR) in architectural design and visualization.
• The role of construction industry trade unions in protecting workers' rights.
• The challenges of implementing green building certification systems.
• The impact of Building Energy Management Systems (BEMS) on energy efficiency in buildings.
• The role of construction waste management in sustainable construction practices.
• The challenges of managing construction projects with limited resources.
• The importance of risk management in construction projects.
• The impact of cultural diversity on construction project teams.
• The advantages and disadvantages of public-private partnerships in construction projects.
• The role of construction industry associations in promoting professionalism.
• The challenges of incorporating renewable energy sources in construction projects.
• The impact of artificial intelligence (AI) in construction site monitoring.
• The importance of quality control in construction projects.
• The role of Building Control in ensuring compliance with regulations.
• The challenges of constructing environmentally friendly infrastructure.
• The impact of population growth on urban construction.
• The role of Building Performance Evaluation (BPE) in assessing building performance.
• The importance of sustainable water management in construction projects.
• The challenges of constructing in remote and harsh environments.
• The impact of modular construction on affordable housing.
• The role of construction industry certifications in career development.
• The challenges of integrating renewable energy systems in existing buildings.
• The importance of inclusive design in construction projects.
• The impact of cultural heritage preservation on construction practices.
• The role of construction industry research and development in innovation.
• The challenges of managing construction projects with tight deadlines.
• The importance of stakeholder engagement in construction projects.
• The impact of building codes on construction practices.
• The role of construction industry training programs in addressing skills shortages.
• The challenges of sustainable transportation infrastructure construction.
• The impact of Building Performance Simulation (BPS) on energy-efficient design.
• The importance of construction project risk assessment and mitigation.
• The role of construction industry collaborations in fostering innovation.
• The challenges of sustainable materials sourcing in construction projects.
• The impact of building envelope design on energy performance.
• The role of construction industry standards in ensuring quality.
• The importance of effective project scheduling in construction management.
• The challenges of constructing in areas prone to natural disasters.
• The impact of building information exchange platforms on project coordination.
• The role of construction industry mentorship programs in developing future leaders.
• The challenges of integrating smart technologies in buildings.
• The importance of construction project cost estimation and control.
• The impact of construction site waste management on environmental sustainability.
• The role of construction industry collaboration platforms in streamlining communication.
• The challenges of constructing tall buildings and skyscrapers.
• The importance of construction project documentation and record-keeping.
• The impact of mass timber construction on sustainable building practices.
• The role of construction industry professional ethics in decision-making.
• The challenges of constructing in areas with limited infrastructure.
• The importance of building information handover in facility management.
• The impact of construction industry mergers and acquisitions on competition.
• The role of construction industry insurance in risk management.
• The challenges of constructing in areas with extreme climates.
• The importance of construction project procurement strategies.
• The impact of 3D printing in construction.
• The role of construction industry research centers in advancing knowledge.
• The challenges of constructing in historic and heritage sites.
• The importance of construction project quality assurance and control.
• The impact of off-site construction on project timelines.
• The role of construction industry digitalization in improving productivity.
• The challenges of constructing sustainable healthcare facilities.
• The importance of value engineering in construction projects.
• The impact of construction industry globalization on labor rights.
• The role of construction industry sustainability certifications in market differentiation.
• The challenges of constructing in areas with limited access to resources.
• The importance of construction project dispute resolution mechanisms.
• The impact of construction site noise pollution on worker health.
• The role of construction industry software in project collaboration.
• The challenges of constructing in areas with unstable soil conditions.
• The importance of construction project change management.
• The impact of construction industry gender diversity on organizational performance.
• The role of construction industry professional associations in knowledge sharing.
• The challenges of constructing sustainable educational facilities.
• The importance of construction project value management.
• The impact of construction site safety culture on accident prevention.
• The role of construction industry sustainability reports in corporate social responsibility.
• The challenges of constructing in areas with limited access to utilities.
• The importance of construction project procurement ethics.
• The impact of construction industry workforce aging on skills shortages.
• The role of construction industry innovation hubs in fostering creativity.
• The challenges of constructing sustainable sports facilities.
• The importance of construction project lessons learned and knowledge transfer.

These 102 construction essay topics cover a wide range of subjects within the field. Whether you are interested in sustainability, technology, project management, or any other aspect of construction, you are sure to find a topic that piques your interest. Remember to conduct thorough research and analyze different perspectives to develop a well-rounded essay. Good luck with your construction-related academic endeavors!

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Construction Research

Construction research at Oregon State focuses on a wide variety of topics related to the design and construction of infrastructure projects. Construction faculty have extensive expertise and experience in the following signature research areas:

• Human Factors in Construction – addressing the needs and abilities of humans involved in the construction process
• Advanced Methods and Materials – efficient use of materials, equipment, and labor to optimize construction operations and project success
• Virtual Design and Construction – utilizing technology to plan, manage, maintain, visualize, and simulate the project design and construction process
• Management Science – scientific investigation and understanding of the project delivery and management process

Construction faculty lead and participate in research sponsored by a variety of local, regional, and national organizations including the National Science Foundation (NSF), Construction Industry Institute (CII), National Cooperative Highway Research Program (NCHRP), Oregon Department of Transportation (ODOT), Federal Highway Administration (FHWA), Center for Construction Research and Training (CPWR), Electric Power Research Institute (EPRI), and PacTrans.

Construction faculty and research interests: 

Ingrid Arocho

Assistant professor of construction engineering: Research interests include construction equipment fleet management, pollution production during construction activities, and construction methods improvement to reduce environmental impact.  Her previous research included the estimation and forecasting of pollution emissions from construction equipment fleets. Dr. Arocho’s teaching interests include cost estimating, project management for construction projects, and advanced topics in project controls.

Joseph Fradella III

Senior instructor II: Extensive industry experience both nationally and internationally, with particular focus on historic building restoration and conservation, retaining walls and hardscape work, and other building renovation and maintenance projects. During his career he has worked for several engineering and construction firms, primarily focusing on mechanical and electrical systems. Mr. Fradella’s teaching interests include mechanical and electrical construction, cost estimating, planning and scheduling, project management, and professional development.

John Gambatese, P.E. (CA)

Professor of construction engineering: Technical and research interests include construction safety, work zone design, constructability, sustainability, design-construction interface, temporary construction structures, construction site operations, and systems engineering.  Current and recent research projects address issues related to construction worker health and safety, design of construction and maintenance work zones, Prevention through Design (PtD), formwork risk and reliability, and the impacts of lean design and construction on safety. Dr. Gambatese’s teaching interests include designing for safety, construction site systems, temporary construction structures, planning and scheduling, and construction contracts and specifications.

Joseph Louis

Assistant professor of construction engineering and Robert C. Wilson Faculty Scholar: Research interests lie at the intersection of simulation, visualization, and automation within the context of construction operations. He draws upon concepts in these areas to provide construction managers with better means of planning, monitoring, and controlling their operations to improve safety, maximize productivities, and minimize equipment idle times. Dr. Louis’s teaching interests include undergraduate and graduate classes in heavy civil operations and equipment, and analytical techniques for construction encompassing construction simulation, visualization, and risk management.

Catarina Pestana

Instructor: Research interests lie the area of project management, including lean management and risk management. Her research interests focus on the enhancement of the performance of production systems and products in different stages of their life-cycle and supply chain in the AEC industry. Current research addresses multi-criteria risk-based decision methodologies to identify and validate improvements to processes and on-site operations in the AEC industry. Dr. Pestana’s teaching interests include scheduling and planning, construction contracts, heavy civil, building construction, and lean construction courses at the undergraduate and graduate levels.  As an academic, who has spent years in the field, Dr. Pestana creates conditions for students to learn, bringing real world problems to the classroom and guiding students to organize information in a personally meaningful way, helping them grow and prepare for their career ahead.

Yelda Turkan

Assistant professor of construction engineering: Research interests are centered on the areas of remote sensing, automation, and information technology applications for construction engineering and management, infrastructure asset management, and transportation. Her recent research projects have focused on building information modeling (BIM) for visualization and facility energy management; bridge information modeling (BrIM) for bridge inspections; and investigating how 3D laser scanning, and virtual design and construction (VDC) technologies can help improve project controls. Dr. Turkan’s teaching interests include virtual design and construction, engineering planning, project management in construction, planning and scheduling, and construction contracts and specifications.

Construction Graduate Program Alumni

Following their time at Oregon State, our students are often recruited by leaders in academia, government, and industry in order to make a positive impact around the globe. Here are a few of our recent graduates and their current positions:

• Serey Raksa Moeung, Staff Engineer, Civil West Engineering Services, Inc. (MS, 2022)
• Ziyu Jin, Assistant Professor, Colorado State University, (PhD, 2021)
• Ola Al-Saffar, Baghdad, Iraq (MS, 2020)
• Ali Karakhan, Faculty Member, University of Baghdad, Iraq (PhD, 2020)
• Mohammed Azeez, Baghdad Governorate, Iraq (PhD, 2020)
• Ding Liu, Lecturer, Qingdao Technical University, China (PhD, 2019)
• Chukwuma (Chuma) Nnaji, Assistant Professor, Texas A&M University (PhD, 2018)
• Kasim AlOmari, Associate Professor, University of Thi-Qar, Iraq (PhD, 2017)

Latest CII Research Publications - Now Available

Explore CII's research publications of 2021.

FR-362 - Breaking through to Collaborative Scheduling: Approaches and Obstacles

This publication examines collaborative scheduling (CS) practices. After a high-level introduction to CS for organizations that are willing to adopt collaboration, the report offers a Maturity Model for Collaborative Scheduling (MMCS), which shows how projects can be improved by increasing collaboration across five pillars: scheduling significance, planners and schedulers, scheduling representation, goal alignment with owner, and communication. Finally, the report identifies collaboration improvement opportunities at the project level in terms of five key performance indicators (KPIs): cost, schedule, safety, quality, and teamwork.

FR-363 - Modernizing the Supply Chain and Increasing the Value of AWP

This report examines the ways capital projects could be improved by involving suppliers earlier than typically has been done, increasing the quality of orders placed with suppliers, and leveraging information systems to support both better supplier engagement and more accurate reporting. The report also introduces enhancements to Advanced Work Packaging (AWP) processes, including the Procurement Work Package (PWP) and the role of Digital Supply Chain Coordinator.

FR-370 - Workforce 2030: What You Need to Know Now About Your Future Workforce

The industry requires new approaches to developing and managing the construction workforce of 2030. RT-370 approached the challenge by examining the changing nature of construction work with evolving technologies, workforce skills, and workforce culture. This report presents the team's findings and recommendations. FR-371 - Getting Ready for 2030: A People, Process, and Technology Roadmap for Offsite Construction This publication addresses many topics associated with offsite construction: key technologies; impacts on the workforce, including needed skillsets; factors that affect labor productivity; and lessons learned, strategic solutions, and pain points. The report lays out a maturity model for offsite construction and includes an Excel-based scoring tool to help organizations self-assess their readiness.

FR-372 - Improving the Data-centric Maturity of the Construction Industry

RT-372 identified the barriers to data-centric operations in the capital projects industry. It developed two Excel-based assessment tools to measure the maturity of data-centric approaches at the organizational and project levels. Finally, RT-372 developed a data-centric maturity framework that highlights how to use the tools and how to measure data-centric actions at both the organizational and project levels. This report includes two proof-of-concept Excel-based tools. 

FR-373 - How Modular Chemical Process Intensification Compares with Conventional Approaches

Modular chemical process intensification (MCPI) has recently emerged as a strategic opportunity for chemical manufacturers to gain a stepwise advantage over their competitors, but businesses are hesitant to depart from conventional methods of plant design and construction to adopt these new approaches. This report offers industry readers some economic case studies to consider when process intensification and plant modularization make sense. This project was a collaboration between CII and the RAPID Module Manufacturing Focus Area (MMFA), and the CII Downstream and Chemicals Sector Committee co-sponsored this project. 

FR-DCC-06 - After the Revolution: Understanding a Decade of Change in Project Delivery Systems and Their Impact on Project Performance

This report serves as an owner’s manual for selecting a project delivery system (PDS). The authoring team identified, defined, and classified the various delivery systems currently employed in the downstream and chemicals sector. It then created this easy-to-use resource, which describes a methodology by which an owner may discern which PDS is most appropriate for a given project. FR-UMM-01 - Achieving Higher Levels of Facility Standardization in the UMM Commodity Market, Version 2.0 This second edition expands the report to capture the findings from another phase of research and to offer even more resources for a total of two books and four Excel tools.

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55 Construction Management Topics & Essay Examples

Looking for interesting construction management topics? Look no further! This list contains writing ideas related to all things construction industry: building materials, newest technology, and more. With our construction management research topics, you’re sure to get an A+!

🏆 Best Construction Management Topic Ideas & Essay Examples

✅ interesting topics to write about construction management, 🔍 good essay topics on construction management.

• Villa Construction Project Management The project I have chosen is the construction of a villa. The aim of the project is to construct a villa and have it ready for use within three months.
• The UK Construction Industry’s Risk Management The construction industry is a major generator of waste, and accounts for 50% of the waste deposited in a typical landfill.
• Exposition for the Application to Master in Construction and Real Estate Management at HTW Berlin Countries around the world have realized that the best way of managing the competitiveness of the market is to successfully government and private projects completed in time and as per the expectations.
• JP Phentar: Construction Project Management Tools Due to the unique nature of the project, there is a need for the establishment of an effective managerial framework. One of the most crucial aspects of the construction project is the quality of work.
• SWOT and Construction Management In another study that concentrated on the Azzaro Construction Project, contractors were asked to detail the relevance SWOT had on the effectiveness of the project. In the study of the Azzaro construction project, the contractors […]
• Evolution of Construction Management From 1960s to Today Thus, the basic features of management within the scope of construction were visible already throughout the undertakings of the first people.
• Software Tools in Construction: Design and Management of Projects Application of software is relevant in simulation and visualization of project scope, schemes projection, and monitoring of changes in plan in terms of cost and design.
• Procurement Opportunities in Construction Management The choice between the four types of procurement available in the construction industry leads to a sharp rise in the quality of the result.
• Robotics in Construction Management: Impacts and Barriers The assessment of the economic feasibility of the robotization of individual construction processes is based on cost analysis and the calculation of payback.
• Integrating Building Information Management (BIM) Into Construction Supply Chain Management The events are part of the whole production process, starting with the inception of the facility and all materials involved, to the end users and products delivered at the last phase.
• Construction Project Management Strategic Issues The task of the project managers is to oversee the activities of the project until its completion. The money would be used to purchase equipment that would be used in the whole project and pay […]
• Caspian Construction PLC: Security Management It will be the duty of the contracted local firm to carry out all the duties concerning the provision of security within the site.
• The U.S. Housing Construction Sector Risks Management The probability of the occurrence of the risk measures the degree of certainty within which the risk may occur. The consequences associated with the risk describe the seriousness of the effects of the occurrence of […]
• Rules of Negotiation in Construction Contract Management When the term negotiation is mentioned various aspect comes into play such as the venue, when or the time for negotiation, aggression in the push of the agenda, the role played among many other issues. […]
• Improving the Construction Management Process
• Construction Business and Law: Construction Management
• Linking Construction Management and Construction Project Management
• Construction Industry: The Integrated Project Delivery (IPD) System
• Overview of Contemporary Construction Management Changes
• Construction Management and Economics: New Directions
• Unresolved Conflict Between Two Construction Management Paradigms for Contingency Project Environments
• Construction Management and Economics: The Epistemology of a Multidisciplinary Design Science
• Improving Higher Education for Construction Management
• Construction Management and Property for Environmental Analysis
• Powerful Construction Management Software Solutions
• Project and Construction Management Guidelines
• Correlation Between Quantity Surveying and Construction Management
• Sustainable Construction Management: Introduction of the Operational Context Space
• Systems Principles for Construction Management
• Tacit and Explicit Knowledge in Construction Management
• The Baby and the Bathwater: Research Methods in Construction Management
• Overview of the Contract Construction Management Law
• Thinking About Materiality: Value of a Construction Management and Engineering View
• Total Quality Management and the Learning Organization: Dialogue for Change in Construction
• Linking Construction Project Management and Business Management
• Applying the Project Management in the Construction Industry
• Importance of Risk Management in Construction
• Project Management Issues in Construction Sites Environment
• Importance of Facility Management in the Construction Industry
• Construction Management Safety Program: Safe Driving
• Importance of Quality Management in the Construction Industry
• Overview of the Importance of Construction Management
• Precautionary Construction Management for Sustainability
• Elements of Cost Overruns, Delays, and Risk Involved in Construction Management
• Construction Management With Focus on Life-Time Health
• Application of Automation for Construction Management
• Construction Management and Process Design Around Construction Robots on the Construction Site
• Risk Management as the Key in Construction Management
• Roles of BIM in Construction Management
• Use of Building Information Model to Improve Construction Management in the UK
• Is Construction Management Education Irrelevant?
• The Effect of Socio-Economic Cultures on Local Construction Management
• The Role of Social Media in Construction Management
• Construction Management: Common Issues in Construction Projects
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11 Construction Industry Trends to Watch (2024-2027)

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According to McKinsey, construction is the largest industry in the world .

And it makes up about 13% of global GDP.

But it is also one of the slowest growing.

However, new construction technologies are looking to speed up the rate of change.

Read on to learn about some of the most important trends in the construction industry.

1. The Virtual Construction Market Sees Rapid Growth

The construction industry is increasingly adopting a variety of new technologies.

Many of these technologies involve virtual design and visualization.

And they range from Building Information Modeling (BIM) to Construction Management Software.

Virtual design and construction (VDC) describe the growing use of virtual environments to engineer and visualize the construction of structures before they're actually built in the physical world.

These virtual environments can be accessed via desktop, and mobile devices, along with augmented and virtual reality hardware.

And there’s no wonder why this is catching on.

It’s estimated that reworks of faulty or incorrect builds account for nearly 30% of construction industry costs.

Virtual design helps cut down on this by allowing builders to first build structures in a virtual environment.

Building Information Modeling (BIM) is probably the most popular VDC tool.

It allows architects, engineers, or anyone else to generate a virtual model of a physical building or structure

As of 2023, the BIM market was worth $8.06 billion and is expected to grow to $9.43 billion this year . 

The construction industry took somewhat of a hit during the pandemic.

But it is expected to rebound over the next few years.

North America is expected to be the market leader over this time period, capturing over 30% of the market.

McKinsey found that BIM technology has now achieved an adoption rate of about 60-70%.

However, this adoption has been relatively slow, taking about 35 years.

The last decade, though, offers some hope.

NBS’s 2020 BIM Report found that 73% of its respondents were using BIM as of 2020.

Compare this to 2011, when almost half of all NBS respondents had never heard of BIM.

Combined with modular construction and prefabrication, BIM is consistently helping construction firms maintain budgets and keep tight construction schedules.

Construction Management Software (CMS) is also now an important tool for many major construction companies.

A construction project is a very fragmented procedure. There are typically a variety of parties involved. And there are a lot of tasks happening at once.

CMS helps construction managers by allowing them to store and access data, blueprints, and documents all in one place.

The global construction management software industry is estimated to be worth $9.3 billion .

It is expected to grow to $23.9 billion by 2031 (a CAGR of 10.2%).

Autodesk is the largest player in the architecture and construction software market.

The company brought in over $3.2 billion in 2020 revenue.

Its AutoCAD, BIM 360, and REVIT technology are basically the standard in virtual modeling.

Its traditional AutoCAD software is used by 85% of the market . And it’s estimated that the company captures about 31% of the overall market.

Autodesk’s software consistently ranks  at the top of industry best lists.

2. Prefabrication and Modular Construction Change How Structures are Built

Modular construction typically involves constructing at least 60-90% of a building or other structure before bringing it to the construction site.

Prefabrication, while technically part of modular construction, occurs when certain components of a structure are assembled or manufactured off-site.

The prefabricated parts are then easily affixed to the building.

The global modular construction market was worth about $91 billion as of 2022. And it is expected to grow to $120.4 billion by 2027.

And while it has been relatively small compared to the entire construction market, the modular construction industry has experienced rapid growth in the past few years.

McKinsey estimates that the North American permanent modular construction industry’s share of new construction projects rose by 51% between 2015 and 2018.

Over the same period, the industry’s total revenue more than doubled.

Increasingly, general contractors (GC’s), architects, and developers are finding that prefabrication and modular construction helps keep costs low, shortens the construction timeline, and reduces waste.

Because of this, roughly 90% of respondents to Dodge’s 2020 Prefabrication and Modular Construction Report said that prefabrication and modular construction methods were more beneficial than traditional construction.

Certain kinds of buildings do, however, lend themselves better to this kind of construction.

Dodge found that, overall, healthcare facilities are expected to benefit the most from modular construction and prefabrication over the next three years.

Hotels and motels, as well as multifamily residential structures, didn’t trail far behind though.

Between 2018 and 2020, hotels and motels have led the pack as major beneficiaries of modular construction.

According to Dodge, roughly 43% of architects and engineers and 29% of general contractors and construction managers said that hotels and motels were the fastest-growing industry for modular construction (2018-2020).

As the modular construction market grows, it is attracting new entrants.

One of the most promising new startups is Katerra .

It is focused on completely modularizing the construction process.

The company manufactures certain parts of a building (like a wall) in its facilities, allowing developers to assemble buildings on job sites.

For now, Katerra is focused mainly on the residential real estate market.

Katerra has raised $1.6 billion in funding, including $865 million from Softbank in 2018.

And although Katerra has had its recent problems , the company still generated about $2 billion in revenue in 2020.

3. Smart Cities Change the Way Construction Companies Operate

One of the biggest trends affecting the construction industry is the rise of smart cities.

A smart city is a city that is basically fully integrated with the Internet of Things (IoT).

The infrastructure and buildings all assist in collecting data to help everything run more efficiently.

It’s estimated that global smart city spending totaled $124 billion in 2020. That’s an increase of almost 20% over 2019.

IDC predicts that investments in smart cities will grow to $203 billion in 2024.

Some estimates also indicate that the market will double again to over $676 billion by 2028.

As this concept matures, it will likely change the way most of the construction industry operates.

More and more construction industry participants will have to start using tech advancements like IoT in their building materials.

A recent study shows that about 60% of US building managers are familiar with IoT technology.

And 43% expect IoT technologies to impact their business in the next few years.

The construction industry will have to adjust soon, as large corporations and cities are making agreements to construct smart cities within the next year.

Toyota has announced a 2,000-person smart city outside of Tokyo.

The company plans to test autonomous vehicles and “smart buildings” in an environment with actual citizens. Construction began in February 2021.

4. Green Building Helps Tackle Environmental Issues

Green building involves building environmentally sustainable buildings using an environmentally sustainable construction and design process.

As governments and regulatory bodies around the world focus on environmental factors in every industry, more construction and design firms are implementing green building methods.

According to Dodge’s World Green Building Report, almost half of all construction and design respondents said they expected the majority of their projects to be green by the end of this year.

And a McKinsey study found that 90% of construction industry respondents believe that a shift toward environmental sustainability is imminent.

As of 2018, Canada had the largest percentage of builders engaged in green building in North America. And the US was a close second.

Mexico is expected to be the leader in North America.

Over half of their builders expect the majority of their buildings to be green.

The green building revolution is doing particularly well in the residential building market.

Over one-third of single-family and multi-family builders build at least half of their projects using green building techniques.

Energy efficiency is widely regarded as the top practice of home builders in improving green home performance. In fact, 96% of green home builders build their homes to be energy efficient.

This makes sense, considering building operations themselves account for the vast majority of greenhouse gas emissions in the construction and real estate sectors.

Because of this, over 90% of single-family residential builders said they used some kind of energy efficiency practices in the construction of at least some of their buildings. 69% claim they use it in most of their buildings.

5. Living Building Materials Go Mainstream

One of the most radical new trends in the construction industry is the use of living building materials .

This part of the industry is still very young, but there are signs of increased adoption.

When looked at from an environmental standpoint, the decision to switch to this kind of material is clear.

The entire construction supply chain accounts for 11% of global greenhouse gas emissions.

And embodied carbon (carbon released in the construction process) accounts for close to 30% of greenhouse gas emissions in the construction and real estate sectors.

The number of new buildings being built also isn’t expected to slow anytime soon.

To accommodate growing populations, the global building stock is expected to double by 2060.

Cement is one of the main areas targeted by the living material sector.

Cement production alone accounts for 8% of global CO2 emissions .

And emissions will need to fall by 16% before 2030 for the sector to come in line with the Paris Agreement on climate change.

According to the BBC, if the cement sector were a country, it would be the third-largest carbon emitter , behind China and the US.

That’s why new products like self-replicating concrete and self-mending biocement are being developed.

Biocement is grown using biological materials instead of created from non-renewable materials. And the process actually absorbs CO2 instead of emitting it.

Innovations like this can allow “manufacturers” to grow building materials that self-replicate, making it much easier and more efficient to scale.

BioMason Inc. is one of the most interesting companies in this area.

The company was founded in 2012, and it uses biological processes to grow biocement blocks.

According to Crunchbase, bioMason has raised over $95 million in venture funding so far.

And it increased its headcount by 50% in 2020.

6. The Construction Industry Benefits Heavily from Drone Technology

Another way that the construction industry is becoming more efficient is through the use of drone technology.

Once thought of as novelty items, drones are now responsible for huge cost savings on major construction projects.

It’s estimated that drone usage has significantly cut down on the annual $160 billion in waste that occurs on construction sites.

In fact, using drones to measure stockpiles of building materials in real time has resulted in a 61% increase in measurement accuracy.

Many are hoping drones will significantly reduce construction worker injuries and deaths.

In the US, 20% of workplace deaths occur in the construction industry – an industry that only makes up 6% of the US labor force.

By using drones, construction companies are able to survey and inspect various locations without putting any actual humans in harm’s way.

As a result of drone technology, the construction industry has seen a 55% increase in safety standards.

In 2018, DroneDeploy – a drone cloud computing company – completed a study that found that the construction industry was adopting drone technology faster than anyone else.

7. Tech Solutions Improve Safety

Concerns about construction site safety are on the rise.

From 2011 to 2019, injuries from falls increased by 41% and the number of nonfatal injuries rose by 8%.

Sadly, more than 365 people in the construction industry died from falls, slips, or trips in 2020.

Statistics like this are leading to a call for improved safety equipment using tech.

Hard hats have been one of the most prevalent pieces of safety equipment at construction sites for the past several decades. However, there’s now a “ helmet revolution ” taking place in the industry.

Safety helmets, like the ones you see people wearing while rock climbing, are becoming popular for a number of reasons.

For example, because they have a chin strap, they stay on even if the worker falls.

They also provide a greater field of vision and a more compact, ergonomic fit for the user.

Many of the latest developments in safety helmets focus on reducing impact in order to prevent injuries to the head and neck.

One helmet from HexArmor features a Kinetix suspension system that’s able to absorb and direct impact out and away from the neck and spinal cord. When compared to other helmets, this system reduces 40% more of the impact force.

There are even some safety helmets, like those offered by twICEme technology, that integrate the user’s medical information, emergency contact information, and coordinate directly into the helmet.

Since twICEme technology works via NFC technology, no GSM, wi-fi, or 3G/4G/5G is needed for communicating.

Wearables are another example of tech-enabled safety equipment that’s becoming popular on construction sites.

Kenzen , a tech company focused on predicting and preventing industrial workforce injuries, has developed a continuous health monitoring program for construction workforces.

Workers wear a small device on their upper arm to monitor core body temperature, heart rate, sweat rate, and activity level. The data feeds into an app that’s visible to the worker and to the manager.

8. Construction Firms Face Major Labor Shortage

The construction industry has been facing a labor shortage for the past several years. But in 2022, it reached “crisis level”. That’s according to the CEO of the Home Builders Institute.

In April 2022, there were 494k jobs open in the construction industry . That’s a 40% increase over April 2021 and the largest total openings since they began tracking the data in 2000.

In May 2022, there were fewer jobs open, only 466k. However, that still represented a 39% year-over-year jump and was the largest total ever for May.

This crisis is expected to get even worse with a portion of the $1.2 trillion from the recent Infrastructure Investment and Jobs Act starting to flow into the industry.

The Association of Builders and Contractors estimated that the industry would need to hire 650k additional workers on top of the normal hiring pace in 2022 in order to keep up with demand.

The shortage of workers is impacting project timelines and completion rates.

In a recent survey, 89% of construction firms reported having difficulty in filling positions and 61% said they are experiencing project delays due to the labor shortage.

The Home Builders Institute says the lack of construction workers is a main factor in the shortage of housing inventory and affordability. Their data shows that nearly 42% of the construction labor force works in residential construction.

One industry analyst says there are 25% more unfilled positions than hired . He expects that “jobs that were predicted to cost $500 million end up costing $600 million because you’re going to need to pay people more”.

In addition to higher salaries, the industry is trying a variety of strategies in order to recruit and retain workers.

Some are launching programs to reach kids as early as grade school and get them interested in construction jobs.

Other firms are focused on diversity in hiring, attracting interest through social media, and offering retention bonuses.

One bright spot is enrollment in construction industry trades courses at community colleges. Enrollment in these courses was up 5% between 2019 and 2021.

9. Material Costs Soar as Shortages Remain

For many construction firms, certain materials are hard to come by. And, even if they can source the materials, the cost is soaring.

More than 90% of builders say they’re facing material shortages.

In that survey, builders were presented with a list of 24 materials and asked to specify which shortages they were experiencing. More than  70% of builders marked half of the items.

In June 2022, the Associated General Contractors of America released data that showed prices for construction materials used in nonresidential projects were up nearly 17% since June 2021.

Construction inputs with the highest price increases were diesel fuel (doubled since June 2021), asphalt roofing products (up 22% YOY), and plastic construction products (up 27% YOY).

The demand and cost for aluminum are up considerably, too.

In 2021, demand for the material jumped 7.7% .

And the first quarter of 2022, demand was up another 5.3% .

Aluminum prices are the highest they’ve ever been. Industry experts estimated an average  price-per-ton of $3,450 in 2022.

Steel is another material that’s scarce and expensive.

The Bureau of Labor Statistics Producer Price Index showed the price of steel mill products increased 123% year-over-year in August 2021.

During the last decade, the average price for hot-rolled coil steel was about $400 per metric ton . An executive from Tata Steel says that steel will cost $600 per metric ton in the coming years.

More than one-third of contractors are seeing a steel shortage.

These shortages and price hikes mean that many construction firms are worried about their bottom line.

Input costs have increased much more quickly than the average prices construction firms are bidding on projects. In December 2021, the average input cost was up nearly 20% while the average bid price had only increased 12.5%.

In a recent Deloitte survey, 20% of E&C (engineering and construction) respondents reported that their operating profitability and industry margins are likely to get worse.

10. 3D Printing Use Increases

The construction 3D printing market is growing at an incredible rate. Reports show a CAGR of 100.7% through 2030.

This type of 3D printing can use a variety of materials: concrete, geopolymers, fiber, sand, and others.

Some innovators have even used biodegradable materials , like mud, soil, and straw in 3D-printed houses.

In most instances, only the frame and walls of a building can be manufactured with 3D printing . However, technology is advancing so fast that plumbing and electrical fixtures can also be integrated into the building via 3D printing.

The construction industry stands to reap several benefits from 3D printing.

The first benefit is time-savings. Technology works faster than we do and California-based Mighty Buildings has the proof.

The company built its Mighty Duo B , a 700-square-foot 3D prefabricated home, in just eight weeks. And, it only cost $314 per square foot.

The company reports that its projects reduce construction timelines by up to 75%.

The lower price is another notable feature of 3D printing in construction.

Far less manpower and time is needed to build these structures, resulting in less wages paid.

One commercial building was built in Dubai using 50% less labor than a typical building.

Black Buffalo 3D, the provider of a large-scale 3D construction printer, says that using its machine to build a 1,000-square-foot space costs 40% less than traditional wooden frames that are built on-site.

ICON, a company that constructs homes using 3D printing, built a 650-square-foot home in 24 hours at a cost of $10,000. They say they’ll be able to get the price down to just $4,000 in the future.

Because of the cost-savings of 3D printing construction, Habitat for Humanity has been watching the trend closely.

The organization built its first 3D-printed house in Virginia in late 2021.

They have a second 3D-printed home in Arizona. The organization says nearly 80% of the 2,400-square-foot home is made with 3D technology.

11. Construction Robotics and Automation Enhance Productivity

Reduced waste, improved safety, enhanced productivity, closing the workforce gap—early adopters in the construction industry are achieving all of these goals by employing robotics and other automation strategies .

The market for construction robots is expected to reach $359 million by 2031.

A survey commissioned last year by ABB showed that more than half of construction companies are currently using robots and 81% expect to introduce robots within the next 10 years.

Construction firms are deploying robots to complete a variety of tasks on-site and off-site.

The TyBOT , a device that ties rebar, is one of the most popular construction robots.

Tying rebar without a robot requires workers to make repeated hand and arm twisting movements while stooping or bending at the waist. It’s literally back-breaking work.

TyBOT takes less than four hours to set up and ties rebar at a rate of 1,100 intersections per hour . That provides up to a 40% productivity boost compared to human labor. And, it reduces the occurrences of worksite injuries.

In 2022 TyBOT’s creator, Advanced Construction Robotics, plans to release IronBot . This robot self-places up to 5,000-pound bundles of rebar. When used alongside TyBOT, the robots can improve productivity by at least 250%.

Another firm seeing success with construction automation and robots is Dusty Robotics .

The company’s FieldPrinter can autonomously mark layouts on the concrete slab of construction sites. The process usually involves workers manually measuring and using a chalk line to show where features should be in an interior construction site. The automated process is up to 10x faster than the traditional method.

It fully integrates with CAD and BIM models to mark specifications for all trades in a single pass. Only one operator and a tablet interface is required for operation.

In June 2021, the company raised $16.5 million in a Series A funding round and followed that up with a $45 million Series B in May 2022, bringing the company up to a $250 million valuation.

Autonomous construction vehicles represent an even larger market than construction robots.

In 2022, the market was valued at $11.86 billion and is expected to grow at a CAGR of nearly 18.5% through 2026.

Built Robotics , founded in 2016, develops software and hardware to automate construction equipment.

The company’s Exosystem installs on late-model excavators in just minutes. The vehicle is then geofenced in a specific area and monitors itself with a 360-degree camera. One trained operator can start the machine and walk away.

The system has a base cost of $3,000 per machine per month.

Built Robotics recently raised $64 million in a Series C funding round, bringing their total funding to $112 million.

That's about it for our list of important construction industry trends for the next few years.

Overall, environmental sustainability and software adoption seem to be the overriding themes that tie many of these trends together.

Interestingly, these themes also tend to result in cost savings. Which should help speed up the rate of adoption.

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• Construction Management

Top 50 Innovative Construction Management Project Topics for 2024

Last Updated on February 19, 2024 by Admin

As we rapidly approach 2024, the construction industry stands at the forefront of innovation and progress, with construction management playing a pivotal role in shaping the sector’s future. With increasing emphasis on sustainability , technological advancements, and ever-changing market dynamics, professionals and students constantly seek fresh ideas and inspiration for their projects and research.

In response to this demand, we have compiled an extensive list of the top 50 innovative construction management project topics for 2024 . These topics encompass diverse areas, including cutting-edge technologies , green building practices , workforce development, and much more. By exploring these forward-thinking topics, you can stay ahead of industry trends, enhance your knowledge, and contribute to the ongoing evolution of construction management.

Whether you are a seasoned construction management professional, a curious student seeking a captivating research project, or an industry expert searching for new ideas, this comprehensive list promises to inspire and inform. So, without further ado, let’s delve into the exciting world of construction management and discover the groundbreaking project topics that will define the industry in 2024 and beyond.

Top 50 Latest Construction Management Project Topics

In this comprehensive collection, we have meticulously curated a list of 50 cutting-edge construction management project topics that will provide valuable insights for industry practitioners, students, and researchers.

These topics span many areas, including project planning, risk management , sustainable construction, BIM, and Lean construction .

Exploring these trends will enhance your understanding of the industry’s challenges and opportunities and position yourself at the forefront of innovative construction management practices.

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Construction management projects play a crucial role in the development and success of the construction industry. By exploring various construction management project topics, professionals and students can gain valuable insights and stay informed about the latest trends.

A project for construction management often involves interdisciplinary collaboration, combining technical knowledge with management skills. Exploring project topics in construction management, such as sustainable building practices and innovative technologies, helps advance the field by promoting efficiency and improving overall project outcomes.

Similarly, project topics for construction management can focus on workforce development and safety management , ensuring the well-being and productivity of workers.

Project topics on construction management address unique industry challenges, such as labor shortages and regulatory compliance. In contrast, a project on construction management provides an opportunity to apply knowledge and skills in real-world scenarios.

By engaging in construction management projects, professionals and students can contribute to the ongoing growth and success of the construction sector .

So, whether you are a seasoned construction professional , a student searching for a thesis topic, or simply an enthusiast eager to learn more about the industry, this blog section is your one-stop destination for discovering the latest construction management project topics are shaping the future of the built environment.

Dive in, and let’s embark on this journey of knowledge and innovation together!

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1. Integration of Building Information Modeling (BIM) and Internet of Things (IoT) for Smart Construction Management

This project explores the potential of combining BIM and IoT technologies to improve construction management processes. It aims to develop a framework that allows for real-time monitoring, analysis, and decision-making based on the data generated by IoT devices in the construction environment.

2. The Impact of Modular Construction on Project Delivery and Cost Efficiency

This project investigates the benefits of modular construction in terms of project delivery and cost efficiency. It aims to compare traditional construction methods with modular approaches and provide recommendations for improving construction processes and reducing overall costs.

3. Implementation of Artificial Intelligence in Construction Risk Assessment and Mitigation

This project examines the application of artificial intelligence in identifying, evaluating, and mitigating risks in construction projects . The study will focus on developing AI-based tools and algorithms to enhance decision-making and increase the efficiency of risk management .

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4. Advancements in 3D Printing Technologies for Sustainable Construction

This project explores the latest advancements in 3D printing technologies for construction and their implications for sustainability. The study aims to analyze the potential benefits of 3D printing in construction projects and how it can reduce waste and improve resource efficiency.

5. The Role of Big Data Analytics in Construction Project Management

This project investigates the potential of big data analytics in optimizing construction project management processes. It aims to develop a comprehensive understanding of the various data sources, analytical techniques, and tools that can be used to enhance decision-making and project outcomes.

6. Enhancing Construction Safety through Virtual Reality (VR) Training

This project examines the effectiveness of using virtual reality (VR) technology for construction safety training. The study will evaluate the impact of VR-based training on workers’ understanding of safety procedures and their ability to identify and avoid potential hazards.

7. Green Building Materials and Technologies: Assessing Their Potential in Sustainable Construction

This project evaluates the potential of various green building materials and technologies in promoting sustainable construction practices . It aims to analyze these materials and technologies’ performance, cost-effectiveness, and environmental benefits.

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8. The Influence of Lean Construction Principles on Project Performance

This project investigates the impact of implementing lean construction principles on project performance. The study will analyze the key principles of lean construction and assess their effectiveness in reducing waste, improving productivity, and enhancing overall project outcomes.

9. Resilient Construction Practices for Climate Change Adaptation

This project examines the role of resilient construction practices in adapting to climate change . The study will focus on identifying innovative materials, technologies, and design strategies that can enhance the resilience of buildings and infrastructure to extreme weather events and other climate change-related risks.

10. The Future of Construction Robotics: Opportunities and Challenges

This project explores the current state of construction robotics and its future potential to transform the industry. The study will analyze the latest developments in construction robotics, including autonomous construction equipment , drones , and exoskeletons , and discuss the challenges and opportunities associated with their widespread adoption.

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11. Evaluating the Benefits of Prefabrication in Modern Construction Projects

This project investigates the advantages of using prefabrication techniques in modern construction projects. The study aims to evaluate the impact of prefabrication on project timelines, cost efficiency, quality control, and overall sustainability.

12. Integrating Renewable Energy Systems into Building Design and Construction

This project explores the potential of incorporating renewable energy systems into building design and construction practices. The study will focus on identifying innovative strategies for integrating solar, wind, and geothermal energy systems into buildings and assessing their potential benefits regarding energy efficiency and environmental performance.

13. The Role of Augmented Reality (AR) in Construction Project Collaboration and Quality Control

This project investigates the potential of augmented reality (AR) technology i n enhancing construction project collaboration and quality control. The study will focus on developing AR-based tools and applications to improve communication and visualization of construction plans , promote real-time collaboration between team members, and streamline quality control processes. Additionally, the project will explore the benefits and challenges associated with adopting AR technology in the construction industry , including its impact on project timelines, cost efficiency, and overall outcomes.

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16. Life Cycle Assessment (LCA) of Construction Materials: A Comparative Study

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17. The Influence of Digital Twins on Construction Project Management

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18. Optimizing Construction Supply Chain Management through Advanced Technologies

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19. A Study on Construction Workforce Development and Retention Strategies

This project explores the challenges and opportunities associated with construction workforce development and retention. The study aims to identify effective strategies for attracting, training, and retaining skilled workers in the construction industry.

20. The Role of Smart Contracts in Construction Project Procurement and Contract Management

This project examines the potential of smart contracts in streamlining construction project procurement and contract management processes. The study will focus on developing a comprehensive understanding of the benefits and challenges associated with the adoption of smart contracts in the construction industry.

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21. Assessing the Impact of Offsite Construction on Housing Affordability

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22. The Role of Circular Economy Principles in Sustainable Construction Practices

This project explores the potential of applying circular economy principles in construction practices. The study will focus on identifying strategies for reducing waste, extending the life cycle of materials, and promoting resource efficiency in the construction industry.

23. Evaluating the Performance of Green Roofs in Urban Environments

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24. The Impact of Autonomous Construction Equipment on Productivity and Safety

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25. Investigating the Potential of Machine Learning in Construction Cost Estimation

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26. The Impact of Globalization on Construction Management Practices

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27. Construction Workforce Diversity and Inclusion: Challenges and Opportunities

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28. The Role of Public-Private Partnerships (PPPs) in Infrastructure Development

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29. Evaluating the Effectiveness of Building Certification Systems

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30. Construction Waste Management: Strategies and Best Practices

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31. The Influence of Cultural Factors on Construction Project Management

This project explores the impact of cultural factors, such as communication styles, decision-making processes, and organizational structures, on construction project management practices.

32. Investigating the Relationship between Construction Management and Real Estate Development

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33. The Role of Geospatial Technologies in Construction Management

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34. Developing Sustainable Construction Education and Training Programs

This project focuses on creating and evaluating education and training programs that promote sustainable construction practices and foster a culture of continuous improvement.

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35. The Impact of Climate Change Policies on Construction Project Planning and Design

This project explores the influence of climate change policies on construction project planning and design, considering how regulatory frameworks and industry standards are evolving in response to global environmental challenges.

36. The Future of the Construction Industry: Predicting Trends and Technologies

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37. Assessing the Role of Construction Management in Urban Planning

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38. Evaluating the Impact of Building Automation Systems on Construction Management

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39. Construction Project Management in Post-Disaster Reconstruction

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40. Exploring the Potential of Blockchain Technology in Construction Supply Chain Management

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41. Construction Quality Management: Tools, Techniques, and Best Practices

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42. Investigating the Role of Construction Management in Heritage Conservation

This project explores the potential contributions of construction management practices to heritage conservation efforts, focusing on the unique challenges and opportunities associated with preserving historical and culturally significant structures.

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• People, Technology and the Future of Mobility
• Real Estate Economics and Finance

43. Assessing the Impact of Social Media on Construction Project Marketing and Communication

This project investigates the influence of social media platforms on construction project marketing and communication strategies, identifying best practices and potential pitfalls.

44. Evaluating the Effectiveness of Construction Management Software Solutions

This project examines the effectiveness of various construction management software solutions in streamlining project management processes and improving project outcomes.

45. The Role of Construction Management in Promoting Occupational Health and Well-being

This project explores the potential contributions of construction management practices to promoting occupational health and well-being among construction workers, focusing on strategies for reducing stress and improving overall job satisfaction.

46. Investigating the Relationship between Construction Management and Facility Management

This project examines the connections between construction and facility management , aiming to identify opportunities for increased efficiency and collaboration throughout the building lifecycle.

• Introduction to Portfolio Construction and Analysis with Python
• Future Development in Supply Chain Finance and Blockchain Technology
• Technology Entrepreneurship
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47. Exploring the Role of Drones in Construction Site Safety Management

This project investigates the potential applications of drones in construction site safety management, focusing on their ability to monitor hazards, track worker behavior, and support incident response efforts.

48. The Impact of Building Information Modeling (BIM) on Facilities Management

This project explores the influence of Building Information Modeling (BIM) on facilities management practices, focusing on the potential benefits and challenges of integrating BIM data into building operations and maintenance processes.

49. Investigating the Potential of Augmented Reality (AR) in Construction Site Safety Training

This project examines the potential applications of augmented reality (AR) technology in construction site safety training, aiming to assess the effectiveness of AR-based training in improving worker knowledge and hazard recognition skills.

50. Assessing the Role of Construction Management in Sustainable Urban Development

This project explores the potential contributions of construction management practices to sustainable urban development efforts, focusing on strategies for improving resource efficiency, reducing waste, and promoting social and economic sustainability in urban construction projects.

• Transportation, Sustainable Buildings, Green Construction
• Business Sustainability Management
• Smart Urban Green Infrastructure

Key Resources and Strategies for Final Year Construction Management Projects

Final-year construction management projects are essential to a student’s academic journey, allowing them to apply their knowledge and skills to real-world scenarios.

To ensure success, students should explore resources like “successful construction project management pdf,” which offers insights and best practices for managing construction projects effectively.

Pursuing an M.E. in construction engineering and management projects can further enhance their expertise in the field. Construction project planning is a critical aspect of these projects, as it helps students develop a comprehensive strategy for managing resources, timelines, and budgets.

Students can consult the “construction management project topics pdf” to find inspiration for their project ideas and explore various aspects of construction management , such as construction planning, to ensure a well-rounded understanding of the discipline.

The construction management system project practically applies various construction management principles and processes. Students can learn from examples of construction projects, gaining insights into different challenges and approaches to ensure the completion of their final-year projects.

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In conclusion, the t op 50 innovative construction management project topics for 2024 serve as a testament to the ever-evolving nature of the construction industry . By embracing these cutting-edge concepts and staying informed about the latest trends, professionals and students alike can contribute to the ongoing transformation of construction management. As we progress, all industry stakeholders must remain adaptable, open to new ideas, and committed to fostering sustainable, efficient, and technologically advanced practices . By doing so, we can collectively shape the construction industry’s future and ensure its continued growth and success for years to come. So, as you embark on your next construction management project or research endeavor, remember to draw inspiration from these innovative topics and strive to make a lasting, positive impact on the industry and the world at large.

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Key trends for 2024 include sustainable construction, digital transformation, modular and prefabrication techniques, and advanced project management software.

Start by researching and understanding the latest trends, invest in training for your team, and adopt advanced tools and technologies to improve efficiency and collaboration.

Sustainable construction promotes energy efficiency, waste reduction, and eco-friendly materials, leading to new project management practices and cost-saving opportunities.

Digital transformation will streamline project management through automation, improved communication, and real-time data analysis, resulting in increased productivity and reduced costs.

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Building for Tomorrow: Global Enterprise and the U.S. Construction Industry (1988)

Chapter: 4. research and development in construction.

Below is the uncorrected machine-read text of this chapter, intended to provide our own search engines and external engines with highly rich, chapter-representative searchable text of each book. Because it is UNCORRECTED material, please consider the following text as a useful but insufficient proxy for the authoritative book pages.

4 Research and Development in Construction Research and development (R&D) in construction includes a broad range of activities directed toward improving quality, pro- ductivity, and efficiency of the materials, equipment, labor, and management of construction. The value of R&D activities is well accepted as means for improving productivity and generating new ideas in electronics, telecommunications, genetic engineering, and other technical fields. The linkages between construction research and application, however, have been more difficult to document, de- spite advances made during the twentieth century in new equipment and materials, largely because of the great number of mostly small- scaTe builders and equipment and materials producers. For this same reason, the construction industry has greater difficulty mobilizing resources needed to support substantial research programs. As a result, the committee observed several troubling trends: . Other countries appear to be putting more effort than the United States into construction R&D; . Other countries are working hard to improve the "hardware" of construction by improving construction methods and developing technology for automation (including robotics); . A more innovative environment exists in most foreign firms because R&D has been integrated into overall operations; 55

56 BUILDING FOR TOMORRO W . Other countries are willing to back longer-range research ef- forts through the slow but methodical methods needed; ~ R&D in other countries tends to be proprietary to the com- pany sponsoring it, leading to some duplication but increasing com- mercial rewards for success; . Vertical integration within large foreign construction firms has made easier the utilization of research results by the operating units of their companies; . There is less emphasis on research related to the "manage- ment" of construction by firms in other countries, since they tend to acquire these technologies through joint ventures with American firms or by sending their young professionals to U.S. universities for training. U.S. CONSTRUCTION RESEARCH AND DEVELOPMENT Accurate appraisals of R&D investments in the U.S. design and construction industries are stubbornly elusive. Available statistics are scarce and often recorded in a manner that can be misleading. In another study* done by the Building Research Board the following observations were made on R&D expenditures in the U.S. design and construction industries: . Construction contractors (both general and specialty)-$54 million . $838 million million Manufacturers of construction materials and equipment Federal agencies (both consumers and nonconsumers) $200 All other sectors (based on estimate) $111 million Total annual construction-related R&D $1,223 million Based on a total volume of construction of some $312 billion in 1984, these estimates represent about 0.4 percent of sales invested in R&D, far less than other mature industries such as appliances at 1.4 percent, automobiles at 1.7 percent, or textiles at 0.8 percent. (This expenditure level is also well below Japanese construction R&D expenditure rates.) U.S. contractors, architects, end engineersinvest less than 0.05 percent in R&D as a group, a fraction of the amount they spend on liability insurance alone. ~ Construction Productivity' National Academy Press, Washington, D.C., 1986.

RESEARCH AND DEVELOPMENT IN CONS TR ACTION 57 Both lack of resources and competing priorities are factors in this low level of R&D expenditure. Faced with intense price compe- tition, many designers and constructors find it difficult to appropriate substantial resources for R&D. Tax regulations that may require cap- italization of R&D expenditures increase the demands R&D would make on current cash flows. The natural aversion to risk of many businessmen makes R&D spending that may yield no immediate commercial benefit more difficult to justify even when business is good, and easy to cut when times are bad. Not one of the many nedium and small firms can afford a meaningful research program, and there are few mechanisms to facilitate joint funding of research that will yield distinct benefits to the participating firms. What the optimum level of U.S. construction R&D spending ought to be is a complex question for which the committee found no ready answer. Observation of U.S. performance in introducing technological innovation and an eroding competitive position make it apparent that the level of spending viewed either as an investment for increased productivity or as an indication of openness to new ideas is too low. Direct government involvement in construction research is lim- ited but significant: . The National Science Foundation (NSF) has been a principal source of support for university-based research activities for the U.S. design and construction industries. Through the NSF, National En- gineering Research Centers are being established, such as the Center for Advanced Technology for Large Structural Systems (ATESS) at Lehigh University. In addition to NSF funds of $10.4 million over a five-year period, other state-related institutions and the private sector are providing matching funds. The major goal of the ATESS center is to do research and develop technology benefitting U.S. structures-related industries in design, fabrication, and construction, and inspection and protection of structures in service. The federal government laboratories such as the Army's Con- struction Engineering Research Laboratory (CERL), the Navy's Port Hueneme Civil Engineering Laboratory, the Tyndall Air Force En- gineering and Services Research Center, and the National Bureau of Standards' Centers for Building Technology and Fire Research conduct research on a diverse range of topics with military and civil applications.

58 BUILDING FOR TOMORROW ~ Grants from the Army Corps of Engineers have produced ma- jor new research programs at the Massachusetts Institute of Tech- nology and the University of Illinois. The Construction Industry Institute at the University of Texas at Austin is an outstanding example of research without direct gov- ernment support. More than 65 organizations representing owners, contractors, and 25 academic institutions have combined their re- sources to tackle advanced construction research. The institute then represents an important model for broader public-private partnership in construction research. OTHER EFFORTS NEEDED An exarn~nation of research ideas for addressing societal needs, undertaken by the Technical Council on Research of the American Society of Citric Engineers in 1979, indicates a long list of research suggestions, most oriented toward improving the methodology of engineering. The list includes a large number of projects related to improving methodology, many of which could be valuable in the international arena.* The architectural research community is based almost exclu- sively in universities, so that the potential exists for linking such research to teaching programs. The civil engineering research com- munity is also largely based in universities, but there is some me- chanical, electrical, or electronic research of direct relevance to the construction sectors being done by these other departments. To a limited extent both architectural and civil engineering research in- stitutions do projects related to mechanical and electrical systems. Most research institutions have projects tied to computer-based de- sign and engineering, but more work is needed, particularly to bring new results into practice, through teaching and professional outreach programs. While spending on research often exceeds U.S. rates, the work going on in construction sector research programs in other coun- tries tends to mirror programs in U.S. universities and government laboratories, with three major exceptions: *Addrc`sing Societal Needs of the 1980's Through Civil Engineering Research, The American Society of Civil Engineers, New York, New York, 1979.

RESEARCH AND DEVELOPMENT IN CONSTRUCTION 59 . The work supported by the Swedish government on behalf of the building industry tends to be much more people-oriented, describing user requirements and how these requirements should be accommodated in design. However, there does not appear to be any better match between the research programs and the teaching programs in the universities than in the United States. . The Soviet Union has six major research units within its con- struction agency Gosstroy. Five of these units do traditional science and engineering research of the type done in government building laboratories around the world, but one research unit concentrates on "cybernetics." Not much is known about the work of this unit, but it potentially could represent an interesting area for collaboration. With their government's strong encouragement, the six large, integrated Japanese construction companies all support research by internal units. These programs include hundreds of people, excellent facilities, and a broad spectrum of subjects (see box). This committee has not undertaken to recommend a complete agenda for research in construction and design, and planning of such an agenda by a single centralized body would in any case be unproductive. However, committee members feelthat certain types of research are clearly needed, such as these two examples: 1. The general subject of "diagnostics" is talked about within the architectural research community as an area for methodological improvement. Work on this subject could be greatly enhanced if uni- versity researchers and practicing architects worked in parallel with firms that are in the business of designing and marketing diagnostic instruments. A program that provides special funds to research units (as contrasted with individuals) within universities that had already obtained an agreement for matching funds from instrument compa- nies would encourage vertical integration between the architectural sector and the equipment-producing sector. 2. The development of safety methods for structures during the construction phase could benefit from case studies. For example, the NBS Center for Building Technology has just completed a study of the collapse of L'Ambiance Plaza in Bridgeport, Connecticut, a building which was being constructed using the lift-slab method. This collapse could serve as a case study for a structural engineering faculty to develop a continuing education course for engineers in practice, thus providing a link among a federal laboratory, university research, and professionals. While this subject is unique and timely,

60 BUILDING FOR TOMORRO W

RESEARCH AND DEVELOPMENT IN CONSTRUCTION 61 _ ~--- ~ ~' ~--~ - _ _ the concept is to have this work serve as a model for similar projects on a range of structural safety problems and solutions. As will be discussed further in Chapter 6, the development of advanced concepts for infrastructure poses an international challenge of enormous proportions. The present practice of dealing with urban transportation, water and energy supplies, waste management, and communications is based on inventions developecI nearly a century ago. In the largest cities of the world these old inventions are clearly not well suited to dealing with present problems, and in the small communities of the developing world there has always been a kind of hand-me-down, makeshift quality to the nature of infrastructure investments. New technology for infrastructure could possibly help the United States avoid the endless cutting and patching of our lO~year-old sys- tems, and could also provide whole new market opportunities in the international sphere. There should be special programs to concen- trate on infrastructure development within the university research community. These programs should encourage university units that are skilled in the areas of the "emerging technologies" to explore ways of creating new or higher-performing systems for infrastruc- ture. Technologies such as new ceramics, advanced microelectronics, biotechnology, and genetic engineering should be incorporated into joint programs with the architectural and civil engineering faculties, and especially to provide graduate students from these technological areas the opportunities to work on infrastructure. In such programs universities could associate with trade and professional groups, such as the American Public Works Association, to introduce engineers in practice to new technologies and their capability. The committee recognizes that some engineering schools can best be encouraged to expend research and teaching in construction by

62 BUILDING FOR TOMORROW evidence of employment interest for their graduates. Programs may be needed to link employers with graduate programs in construction by having the university offer special graduate programs for mature employees of professional firms. As the Japanese mode! illustrates, university-based activity is not the only way that construction R&D can be accomplished, but in the United States, academic institutions have become the primary centers of research. This pattern is unlikely to change in the fore- seeable future, nor is it clear that it ought to change. What is clear to the committee, however, is that better mechanisms for linking research to construction practice are needed. There is a need as well to increase the speed with which ideas from one field of research are tested for their value in other fields, and with which ideas of value enter practice. The case of the Bell Laboratories (Case Study 4), drawn from an industrial situation very different from construction, is nevertheless instructive because of their great success in linking research to the market. In construc- tion, where the market is distributed among so many suppliers and buyers, projects built with federal government funds can be used to demonstrate new technology. A good example is the introduction to U.S. transit construction of precast concrete segmental tunnel liners (see Chapter 6~. The U.S. Department of Commerce has noted, "Over the next twenty years it is totally reasonable to expect that we will see widespread application of the following technologies: advanced mate- rials, microelectronics, automation, biotechnology, computing, mem- brane technology, superconductivity, and lasers."* Today and in the near future many other new technologies may be added to the list. Mechanisms are needed to expose these new technologies and con- struction to one another, and to produce design and construction professionals competent to make the connections required for inns vation. Besides institutional research, there must be training and education. *Effect of Structural Change in the U.S. Economy on the Uric of Public Works Scr~nccs, U.S. Department of Commerce, Washington, D.C., 1987.

RESEARCH AND DEVELOPMENT IN CONSTRUCTION CASE STUDY 4: THE BELL TELEPHONE LABORATORIES 63 The invention of the telephone is perhaps the single best modern example of how new technology can alter building and infrastructure. The BeR Teieph one Laboratories have for more than 60 years been one of the leading U.S. centers of research and innovations that have changed how to design and build individual structures en c] cities, as weR as the more basic structure of the economy and society. The committee recognizes that the Be]] Labs are a product of a private sector monopoly company that had vertical integration and an ability to make elective decisions about resource allocation and management strategy, with greater ease than is the case in U.S. design and construction. Nevertheless, many characteristics of the Bed Labs can serve as a useful mode] for institutional arrangements needed to strengthen U.S. building research. It is instructive to look at the history and accomp~ishmeIIts of this organization: The invention of the telephone was not inspired by a pre-existent popular demand. Rather, it came about largely through the ingenuity and vision of one man Alexander Graham Bell. His belief that there was a great potential need for two-way voice communication over a distance, a need of which few men had been conscious, was confirmed by its immediate success and spectacular growth in spite of early technical limitations. By the end of the first fifty years a great new industry had been developed. There were nearly seventeen million telephones in the United States, almost twelve million of them in the Bell System. And in perhaps no other field had the force of scientific research in support of engineering development been so effectively demonstrated.* As the AT&T Company Annual report for 1913 said: At the beginning of the telephone industry there was no art of electrical engineering nor was there any school or university conferring the degree of electrical engineer. Notwithstanding this the general engineering staR was soon organized, calling to their aid some of the most distinguished professors of science in our universities. As problems became more formidable and increased in number and complexity, the engineering and scientific staff was increased in size and in its specialization so that we now (1913) have working at headquarters on the problems of the associated companies some 550 engineers and scientists carefully selected with due regard to the practical as well as the scientific nature of the problems encountered. *A History of Engined ring and Scicnec in the Bail System, Bell Laboratories, Murray Hill, New Jersey, 1975.

64 BUILDING FOR TOMORRO W It can be said that this company has created the entire art of telephony and that almost without exception none of the important contributions to the art has been made by any government telephone administration or by any other telephone company either in this country or abroad. By 1924 the technical programs of the Bell System had so grown in range and intensity, and in number of personnel, as to suggest formation of a single new organization to handle most or all of these activities. Such an organization was formed on December 27, 1924, and started operations on January 1, 1925, under the name of Bell Telephone Laboratories, Incorporated. This corporation had a dual responsibility- to the AT&T Company for fundamental researches and to the Western Electric Company for the embodiment of the results of these researches in designs suitable for manufacture. At the date of incorporation, the personnel numbered approximately 3,600, of whom about 2,000 were members of the technical staff, made up of engineers, physicists, chemists, metallurgists and experts in various fields of technical endeavor.... Technological innovation had formed the indispensable core for telephony's growth up to 1925, but was even more significant to the future because so much of it was fundamental: the way was being prepared for more powerful systems yet to come, which would be essential to the enormous expansion felt to be lying ahead. Perhaps more significantly, the application of scientific methods to solving the "system" problems of telephony set a pattern that influenced industrial research and development by demonstrating the power of these methods and developing techniques of management that encouraged their use. Backing up the work on systems, which had laid the groundwork for so much that was yet needed, were the successful management techniques which had been developed for conducting and applying research, the means for closely controlling the quality of manufactured product, and a type of organization providing close integration of the user, technical developer, and manufacturer. The Bell Labs have produced the transistor, the laser, the solar cell, and the first communications satellite, as we]] as sound motion pictures, the science of radio astronomy, en c] crucial evidence for the theory that a Big Bang created the universe. While they are a private laboratory (in the distinction made in the United States between government and private research work), their fin ancia] support was largely generates' from a kind of tax on every telephone in the United States (before the breakup of AT&T in 1984), which in turn was a]]owec! by their rate examiners (a public institution designed to monitor a monopoly utility). The potential for direct emulation by a government/industry research center is limited, therefore, but the operating principle of striving for increased systems performance by

RESEARCH AND DEVELOPMENT IN CONSTRUCTION 65 teams of scientists, engineers, manufacturers, en c] systems operators is a good one. Today's telephone caller uses components Bell never dreamed of, today's driver depends on systems Daimler and Benz never thought of, and today's homeowner switches on a power and light system that Edison never envisioned. These discoveries have long since been em- bedded in mammoth networks of technology that no single individual invented. Technological systems evolve through relatively small steps mark- ed by the occasional stubborn obstacle and by countless break- throughs. Often the breakthroughs are labeled inventions and patent- ed, but more often they are social innovations made by persons soon forgotten. In the early days of a system such as electric light and power, inventors played the prominent role. Then as the system ma- tured and expanded to urban and regional networks, others came to the fore. Electric light and power systems today are not just scaled-up versions of the Pearl Street station that Edison introduced in New York City in 1882. By the turn of the century, for example, it was the utility manager, not the inventor or engineer, who played the major role in extending round-the-clock service to many different kinds of customers to the night shift chemical plant as well as the rush-hour electric streetcars.* *Thomas P. Hughes, The inventive continuum, Science 84, November 1984.

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Research Trends in the Construction Industry

February 29, 2024

(Data visualized in the chart captures buying and research signals for the past 365 days)

Executive Summary: Construction Research Trends in the Construction Industry

The data highlights the top trends and insights within the construction industry, focusing on how businesses are researching “Construction” and related topics. Here’s a summary of the top trends from the data:

1. Construction: This topic stands at the forefront of the industry’s research, with an average of 2,615.62 businesses spiking in their research weekly, and a total of 135,587 research spikes observed.

2. Construction Camera: Following closely, this technology is also a hot topic with 2,469.04 weekly average business research spikes, accumulating to 130,095 spikes. This indicates a high interest in surveillance and monitoring technologies within construction sites.

3. Architectural Design: With 2,250.02 businesses on average researching this weekly, totaling 118,361 spikes, architectural design is a significant area of focus. This suggests a strong demand for innovative and sustainable design practices in the industry.

4. Commercial Worksite: This topic, which garnered 2,187.23 weekly average business research spikes and a total of 113,988 spikes, indicates a keen interest in commercial construction projects and their management.

5. Home Decor: Though slightly tangential, the interest in home decor, with 2,081.23 businesses researching it weekly (totaling 107,251 spikes), suggests a broader interest within the construction industry towards interior design and aesthetics, possibly driven by end-consumer demand.

These insights reveal that the construction industry is not only focused on traditional construction topics but is also keenly interested in technology (such as construction cameras), design (architectural and interior), and commercial project management. This reflects a dynamic industry that is adapting to modern technologies and consumer demands while maintaining a strong foundation in its core activities.

Technological Integration

– Construction Cameras: With 2,469 weekly research spikes on average, the data underscores a significant trend towards the integration of technology in construction projects. This interest points towards an industry-wide push for enhancing security, monitoring progress, and improving documentation through advanced surveillance technologies. The close gap between general construction and construction camera research spikes (135,587 vs. 130,095) highlights the critical role of tech solutions in modern construction practices.

Design and Aesthetics

– Architectural Design: The focus on architectural design, with an average of 2,250 businesses researching this topic weekly, signifies an evolving industry perspective that places a premium on innovative design and sustainability. The substantial number of research spikes (118,361) reflects a strong demand for architectural excellence, blending aesthetics with functionality in construction projects.

Commercial Projects Focus

– Commercial Worksite: The data reveals a concentrated interest in commercial construction, with 2,187 average weekly research spikes. This interest (113,988 total spikes) indicates a robust market activity in the commercial sector, emphasizing the importance of efficient worksite management, project delivery, and scalability in commercial construction endeavors.

Expanding Industry Scope

– Home Decor: An intriguing aspect of the dataset is the substantial interest in home decor, with 2,081 weekly research spikes on average. While not directly related to construction, this trend (107,251 total spikes) suggests an expanding scope of the construction industry into interior design and decoration, possibly driven by market demand for comprehensive construction-to-interior solutions.

Implications for the Construction Industry

The data not only illustrates the primary areas of interest and research within the construction industry but also highlights the sector’s dynamic response to technological advancements, market demands, and sustainability considerations. The emphasis on construction cameras and architectural design points towards a future where technology and innovation play pivotal roles in shaping construction practices. Additionally, the focus on commercial worksites and the extended interest in home decor indicate a broadening of the industry’s scope, catering to a wider range of client needs from foundational construction to the final touches of interior aesthetics.

This comprehensive analysis reveals a construction industry at the cusp of significant transformation, driven by technology, innovation, and a deepening understanding of consumer expectations. These trends not only reflect current industry priorities but also suggest areas of potential growth and development in the future.

Company Sample Data

This contains data on companies within the construction industry, focusing on their size and corresponding research activity related to the industry. Here’s a brief overview of its structure and the information it conveys:

– Company Size: This column categorizes companies based on the number of employees. The categories range from “Micro (1 – 9 Employees)” to “Medium-Large (500 – 999 Employees)”, providing a spectrum of company sizes within the construction industry.

– Spiking Businesses (weekly avg.): This column shows the average weekly number of businesses within each size category that have shown a spike in research activity related to construction. This metric offers insights into the level of active interest and research engagement among companies of different sizes.

– Percent of Total: Represents the percentage of total research activity attributable to companies within each size category. This gives an idea of how much each segment contributes to the overall research activity in the construction industry.

Key Observations

– Small companies (10 – 49 Employees) and medium-small companies (50 – 199 Employees) are the most active in research related to construction, with significant weekly spikes (7,073.19 and 6,425.17 on average, respectively). – These two categories also contribute the most to the total percentage of research activity, with small companies accounting for approximately 34.74% and medium-small companies for about 31.56%. – Micro companies, despite being the smallest, still show considerable activity, indicating a vibrant interest in construction research across all levels of business sizes.

This data suggests a diverse engagement across different company sizes in the construction sector, with a notably higher level of activity among small to medium-sized businesses. This could reflect the dynamic nature of the construction industry, where businesses of various sizes actively seek out new information, technologies, and methodologies.

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11 Construction Industry Trends for 2022

• Topics & Resources

Construction needs skilled workers as the industry adopts AI, IoT, robots and more.

Date Published:

Oct 19, 2021

Mark Crawford

New construction materials

Finding and retaining workers.

3D printing

Digitalization.

Artificial intelligence

AI can be integrated with other technologies on the job such as building information management, sensors, wearables, and other monitoring tools to make better-informed decisions in real time, reducing construction costs through improved forecasting and construction management. AI can also promote safety by analyzing photos of the jobsite and identifying hazardous situations or high-risk trends in worker behavior.

Building Information Modeling

Digital twins

A digital twin in the construction industry is an exact virtual model of a building or a construction site that is built using Internet of Things technologies that capture hundreds of thousands of data points. This data is processed using AI and can be viewed, monitored, or changed in real time to test new ideas or make changes, which can improve building design, project scheduling, and building operation systems.

Robots can perform an increasing number of tasks on the construction site, including painting, loading, brick-laying, tying rebar, and installing drywall. This helps protect workers from dangerous or repetitive tasks, which reduces injuries and allows workers to take on other tasks. Robots can be also used to complete work during labor shortages.

Wireless sensors and trackers are embedded in apparel or personal protective equipment such as gloves, vests, and hard hats and monitor a worker’s vital signs, movements, repetitive motions, and slips or falls. Such real-time health data helps keep workers safe and immediately lets safety managers know if a worker is exhausted or at risk for injury. Editor’s Pick: Construction Robots that Read Your Mind Technology and material trends in construction will continue to advance. By combining IoT-enabled digital technologies, construction companies will be more efficient, productive, and safe than ever before, increasing their bottom line and winning market share. Project delivery methods must also evolve to meet customer demands. For example, Gray has expanded its services to better meet the specialized needs of its food and beverage customers. “We have adapted the traditional design-build model to include a robust scope of services that extends well beyond traditional design and construction, such as process and packaging engineering, controls integration, automation, and even equipment prefabrication,” said McCowan.  As with all growth, he added, challenges exist in construction, but so do opportunities. “In this type of evolving industry, project management teams must pioneer new methods to push the industry forward in creative and productive ways.” Mark Crawford is an engineering and technology writer in Corrales, N.M.

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Seizing opportunity in today’s construction technology ecosystem

After decades of under-digitization, the engineering and construction (E&C) sector is making bold moves in a new era. Last year, we mapped the industry’s technology ecosystem with a focus on the solutions that are proliferating in the construction phase of the project life cycle. The research shed light on the emergence of technology clusters, industry-wide technology investment of more than $10 billion in less than a decade, and the lack of integrated solutions that span three identified use case clusters: on-site execution (“field”), digital collaboration (“team”), and back-office and adjacencies (“office”).

Stay current on your favorite topics

This year, we expanded the study to include the entire asset life cycle—concept and feasibility, design and engineering, preconstruction, construction, and operations and maintenance—across more than 2,400 technology solutions companies, creating the most comprehensive database of the construction ecosystem worldwide. In this article, we explore three key topics based on our latest research:

• What are the emerging trends from this year’s research? We explore how the landscape has changed over the past year in terms of constellations of technology, accelerated investment, and an expansion in the number of use cases.
• How will the market evolve in the coming years? We discuss the changes we expect over the next few years, including continued fragmentation of the industry, which will lead to consolidation, as well as an intensifying fight for talent.
• How can the industry accelerate its transition to a digital future? We outline recommendations for AEC firms, technology providers, and owners to accelerate the impact of technology.

1. What are the emerging trends from this year’s research?

Three key trends are shaping the industry: emerging constellations of solutions around established use cases, accelerating technology investment, and an expanding set of promising use cases.

‘Constellations’ of solutions emerging around established use cases

In our continuous mapping of the construction technology landscape, we see the concept of different “constellations” of connected solutions emerging around established use cases, which serve as indicators of what technologies are gaining the most traction and where their impact can be expected to rapidly increase in the near future. Today, the most prominent constellations include 3-D printing, modularization, and robotics; digital twin technology; artificial intelligence (AI) and analytics; and supply chain optimization and marketplaces (Exhibit 1).

Within each constellation are three or more use cases that span the three use case clusters we identified last year: on-site execution (“field”), digital collaboration (“team”), and back-office and adjacencies (“office”). For example, the digital twin technology constellation includes drone-enabled yard inspection, which is an on-site execution use case, as well as several digital collaboration use cases: laser scanning, virtual learning, and design simulation. In Exhibit 1, the thickness of the lines connecting various use cases indicates use cases that are often addressed together; in the digital twin technologies constellation, design simulation and virtual learning are strongly linked given the increasing amount of solutions offering these two uses cases in combination.

In particular, three of the constellations—3-D printing, modularization, and robotics; twin models; and artificial intelligence and analytics—are poised to be transformational for the industry. A fourth constellation, supply chain optimization and marketplaces, is notable due to its quick rise as dozens of smaller players have entered into this market over the past year.

Artificial intelligence and analytics. In the long-term, AI and analytics have boundless potential use cases in E&C. Machine learning is gaining some momentum as an overarching use case (that is, one applicable to the entire construction life cycle, from preconstruction through O&M), particularly in reality capture (for example, in conjunction with computer vision) as well as for comparison of in situ field conditions with plans (for example, supporting twin models). Indeed, by applying machine learning to an ongoing project, schedules could be optimized to sequence tasks and hit target deadlines, and divergences from blueprints could be caught closer to real time and corrected using a variety of predetermined potential scenarios.

In the immediate future, we expect AI’s proliferation in the E&C sector to be modest. Few leaders have the processes, resources, and existing data strategies in place to power the necessary algorithms and meaningfully implement this technology. However, the potential impact is so large that the industry can no longer afford to ignore it. AI methods are increasingly able to work across industries, elevating the threat of competition from nontraditional market entrants. And a narrow set of start-ups are already gaining market traction using AI-focused approaches. 1 For more insights on specific use cases of AI in E&C, see Artificial intelligence: Construction technology’s next frontier .

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3-D printing, modularization, and robotics. Parts of the construction industry are moving toward a manufacturing-like system of mass production, relying on prefabricated, standardized components that are produced off-site. Our research finds that consistent use of these techniques, on projects where they are economically feasible, could boost the sector’s productivity by five- to tenfold. Such a system would include applications such as fully automated prefabrication processes that turn a 2-D drawing or 3-D model into a prefabricated building component, or fabrication directly off a 3-D model or shop drawings; construction robotics such as bricklaying or welding robots; self-driving heavy machinery to make construction safer, faster, and more affordable; exoskeletons and wearable robotics to improve the mobility of workers with injuries or to harness the strength of robotic arms; and metal 3-D printing of long-lead components such as joints, enabling the production of high-performing components and, ultimately, more efficient, cost-effective parts.

On the robotics side, the E&C industry is at the beginning of its journey to embrace the hardware innovations that enable field augmentation with exoskeletons and drone-enabled yard inspection. These advances are particularly important given a labor shortage in many geographies as well as the natural ceiling of human physical productivity. Pairing humans with robots can assist in tasks that would take a human worker more effort (for example, lifting heavy objects and placing them in exact coordinates).

Digital twin technology. In E&C, productivity gains are directly driven by transparency and proactive problem resolution. Digital twin platforms and reality-capture solutions enable stakeholders to minimize rework in the field by allowing a dynamic view of the project and real-time comparison of progress to design blueprints—and the ability to adapt those blueprints as the work progresses and inevitably results in changes. Drones and satellite imagery, as well as LiDAR and photosphere based-solutions, are key components of many reality-capture efforts.

The most exciting applications of twin models can be found in the seamless integration of 3-D models generated by drone imagery, turbocharged by live key performance indicators that are monitored using Internet of Things sensors. This approach creates an exact digital replica of a project’s physical reality, allowing us to rapidly advance data accuracy and incorporate as-built data into 3-D models for automated, real-time progress updates. It also enables users to virtually interact with “mixed reality” models that combine 3-D design and as-built configurations. What is truly exciting about these applications is the ability to reduce decision-making cycles in a construction project from a monthly basis to a daily basis through full automation of the project’s scheduling and budgeting updates.

Supply chain optimization and marketplaces: Currently, procurement of materials, equipment, and labor is a largely manual and cumbersome process. However, start-ups that offer marketplace platforms for the buying and selling of goods as well as hiring have begun to gain traction in certain regions. Some of these start-ups have been acquired by large suppliers, which have quickly deployed these platforms at scale. By enabling players to match supply with demand, these marketplaces have huge potential to optimize the supply chain—much the way such marketplaces have revolutionized industries such as retail—improving productivity and profitability. In construction, these marketplaces can also enhance competitive bidding by improving transparency on costs and availability of materials, labor, and equipment for both future and ongoing projects. They will also become increasingly important given the rising use of prefabricated components that are manufactured off-site. Despite the progress, this constellation is nascent and limited to North America.

Increasing and evolving technology investment

Through the mapping of the investment flows we found two critical insights:

Investment has doubled in the past decade: Last year, we found that construction technology companies had garnered $10 billion in investment between 2011 and early 2017. Our updated research has pointed not only to a greater volume of outside investment but also an acceleration in investment. Between 2008 and 2012, construction technology received $9 billion in cumulative investment. Between 2013 and February 2018, that number doubled to $18 billion, largely driven by mergers and acquisitions (Exhibit 2).

Early technologies are delivering on their promise: Our research reveals that by count of transactions, early-stage venture capital (VC) is on the rise. Of the 908 transactions from 2013 through February 2018, three in four were early-stage VC. Indeed, since 2015—a peak year for VC investments—the construction technology space has sustained a relatively high level of investment from VCs, suggesting that more solutions will be ready for scaling and that high levels of merger and acquisition (M&A) activity will continue unabated. M&A activity tends to occur one to two years after late-stage VC.

Furthermore, late-stage VC has been trending upward in the market (Exhibit 3). From 2010 onward, late-stage VC has almost steadily increased (except a small dip in 2016). Such a steady rise indicates that certain use cases are market-backed and ready for growth financing, 2 The caveat here is that a rise in late-stage VC can also be driven by price inflation or because companies have chosen to stay private for a longer period (requiring more financing before an exit). delivering on the promised impact.

An expanding set of use cases

Last year, our research focused on technology in one phase of the asset life cycle: construction and commissioning. As we expanded our taxonomy to look at the entire asset life cycle, we found that two phases are attracting the most growth: construction and commissioning and operations and maintenance (Exhibit 4). Other phases tend to be already established—for instance, preconstruction and back-office—while others are small or still maturing.

Construction remains the highest invested phase of the asset life cycle. Construction leads the ecosystem in garnering the most overall capital from 2013 to February 2018, with both the highest number of use cases and the highest number of transactions. It is also relatively mature; only one-third of companies in this phase are newcomers. Over time, we expect to see M&A investments related to consolidation as well as incremental late-stage VC investments (for example, for scaling sales operations).

Preconstruction and construction back-office phases are both garnering large investments. Investment in the preconstruction phase is primarily driven by labor and equipment marketplaces, a relatively fragmented solution space where regionally focused players will eventually face consolidation. Construction back-office, on the other hand, is a very mature solution space. Investment in this phase is driven primarily by mature companies through M&A or private equity transactions with high average values.

Cross-cutting technologies are gaining the most momentum. We classified 3-D printing, virtual learning, design simulation, machine learning, and deep learning as “overarching,” given their applicability across different stages of the life cycle. While we found relatively few transactions in this category compared with construction and commissioning, the number of companies founded in this space over the past five years exceeds any other category, and the dollar value of transactions is quickly catching up with the rest of the categories. The average transaction amount is particularly high in capital-intensive use cases in this category such as 3-D printing.

There are two untapped markets: design/engineering and concept/feasibility. This may be because entrepreneurs have focused on life cycle stages that hold the majority of project value. Alternatively, the office-based nature of these phases also means their relevant solutions (such as CAD or BIM) may already be relatively mature and sophisticated. We foresee less disruption in these stages and more continuous improvement (for example, new features for existing software).

2. How will the market evolve in the next 2–3 years?

Mapping the number of transactions in each of the 38 use cases against the number of new companies in the past five years in that space reveals a detailed picture of the current construction market (Exhibit 5). Four archetypes emerge:

• Talent acquisition. In the upper right quadrant, we find both a high concentration of new companies and a high number of transactions in machine learning, among several other use cases. This quadrant can be described as “talent grab,” which means that companies are using acquisitions to onboard new talent and skills.
• Emerging. In the lower right quadrant, we find use cases, such as deep learning, where there are a lot of new companies but not a lot of transactions, suggesting these use cases are primed to emerge into the tech investment space in the next few years.
• Maturing. In the upper left quadrant, we find use cases, such as document management, with a lot of transactions but relatively fewer new companies, suggesting that these use cases are dominated by relatively established companies operating in a fragmented market. These areas may thus be facing consolidation in the near future.
• Established or unproven. Finally, in the lower left quadrant we find established or unproven use cases, such as enterprise resource planning, where few new companies and few transactions are underway. These markets may be saturated—but for the exception of some use cases, such as laser scanning, that have simply not yet realized momentum.

Increasing consolidation against a backdrop of continued fragmentation

The fragmentation of technology offerings will continue to be an issue. In last year’s analysis, just 13 percent of the companies we studied had engaged a technology solution that addressed more than one of the three clusters (on-site execution, digital collaboration, and back-office and adjacencies)—meaning that most companies are engaging solutions that address a very specific, narrow application rather than more integrated solutions.

Our new research confirms that more than half of companies are still engaging a solution that addresses just 1 or 2 use cases out of the 38 (Exhibit 6).

This fragmentation is one of the biggest challenges we’ve heard from companies that want to engage with technology solutions. Many are older, venerable companies using legacy systems and various information-collection methods. For these companies, integration may sound more like it’s yet another solution to layer in on the top of all the other processes and solutions on hand—when in fact, technology can be used to cut down on the number of solutions and methods being used.

Integration plays

We see three types of integration that can materialize over time:

Large software players acquiring point solution start-ups. We see existing software companies acquiring more targeted start-ups in order to offer an integrated software solution, usually across multiple asset classes. Examples of this archetype can be seen in Oracle’s 2017 acquisition of Aconex, or Trimble’s acquisition of e-Builder and Viewpoint in 2018. These players claim to be a “one-stop shop” for core needs in construction technology.

Platform plays. Companies can become agnostic platforms on which to integrate multiple point solutions, similar to an application programming interface (API). These providers model themselves as a “best-of-breed” solution—analogous to the way Apple markets their iOS ecosystem or platform—upon which various construction needs or applications can sit. This also allows companies to play across multiple asset classes. However, data ownership and related risk (for example, assuming responsibility for negative project outcomes when multiple solutions are deployed) can make end users wary of this type of integration.

Hybrid integrations. While the former two archetypes are asset class–agnostic—that is, their solutions are applicable across asset classes—we also see the potential for integrations of asset class–specific solutions. For example, compared with residential construction, industrial construction requires greater accuracy in reality capture and digital twin models. As such, we have begun to see solutions in this category geared toward specific asset classes (for instance, digital twins for complex oil and gas projects) as well as those geared toward building suites or packages of such solutions. We are also already seeing the rise of vertically integrated contractors who incorporate (by developing, acquiring, or partnering with) the full set of hardware and software solutions for a given asset class—for example, Katerra in residential construction.

The lack of use case integration is one of the drags on technology adoption at scale. As such, more companies are exploring the potential to consolidate solutions that address multiple use cases. While integration won’t “grease the wheels” of every aspect of technology adoption, it certainly represents a viable path forward to bring more layers up to speed. (See sidebar, “Integration plays.”)

The struggle to find talent

Finding digital talent is a prominent concern for executives across the industry, and it will be critical to digitization: according to research by McKinsey’s Digital Academy, investing in talent increases the odds of digitization success by 2.5 times. Investing in talent requires balancing the entrepreneurship DNA, industry knowledge, and business acumen to build business unit from scratch—but the talent pool is small when it comes to balancing these three skill sets.

3. How can the industry accelerate its transition to a digital future?

While technology has dramatically advanced in the E&C sector, there is much room for improvement. There are several actions that AEC firms, technology providers, and project owners can take to accelerate construction technology in the coming years.

Invest in talent and skill building: AEC leaders must begin to expand skill sets among existing employees as well as hire new candidates with technical expertise. To start, AEC firms can explore talent pools in digital native companies, even those outside the E&C industry; a particular focus should be given to candidates in other industries that have undergone a digital transition. These individuals can be paired with the right industry leaders and reach in the organization to integrate new and existing expertise. To upskill current employees, firms should bring in training programs in new technologies—for instance, to train employees in 3-D printing—or set aside funds for capability building.

Capital projects: Creating digital-first organizations

Actively engage with the start-up ecosystem: This action can take a variety of forms, one of which is investing directly in start-ups through a corporate VC arm. Here, AEC firms may be challenged by entrepreneurs who are hesitant to accept capital from large players, as it compromises their ability to work with a funder’s competitor. AEC firms can manage this caution by exploring other, less risky forms of engaging with start-ups: for instance, investing indirectly through a VC fund or partnering selectively for piloting or codeveloping solutions.

Establish conditions of success for piloting and scaling: AEC firms can prime themselves to be early adopters of promising technology by setting aside funding for the purpose of experimentation. As pilot solutions prove their value, AEC firms can use a helpful acid test for evaluating the longer-term use of a technology: whether a project manager is willing to accommodate its cost in their project budget. AEC firms can also bring in outside start-up expertise as needed, as building an in-house development team is often labor intensive and time consuming. Partnering with start-ups that can bring specific capabilities (for example, product development through rapid iteration) can be particularly valuable.

Tech providers:

Listen to the end user and adapt: Solutions in the ecosystem are often developed by looking for a problem. Indeed, we find passionate start-up founders looking for an application of their novel solution in the industry, instead of truly understanding the industry’s needs. To that end, start-ups—especially if teams are from outside the AEC industry—must listen closely to the needs of AEC firms and adapt product offerings. This effort will consist of focusing on validated customer needs; in this fragmented landscape, it is imperative to validate the real need (versus a “nice-to-have” application).

Plan for the journey to integration and consolidation: As described above, unlocking real value from the technology ecosystem will require integration across multiple use cases and clusters. As the industry evolves, start-ups must therefore forge a “co-opetition” strategy—that is, how to simultaneously collaborate and compete. This is especially true given the multiple pivots that start-ups undergo (for example, starting with one use case and shifting to a new one). Start-ups in the early stage will need to plan on an evolving go-to-market strategy.

Enforce a strong and sharable data foundation: All project participants need to work with one shared data backbone in one system, known as a common data environment (CDE) . This data will need to be made available to all project participants, with up-front agreement from all.

Align on supportive contract strategies: Digital participation needs to be part of the bidding contracts for all project participants. Indeed, a digital project should emulate an integrated project delivery (IPD) setup, which can not only improve outcomes and accountability but also circumvent the hostility of an adversarial contractual environment.

Identify and focus on critical use cases: Owners need to focus on understanding their organization's unique economic case for technology. While it may be appealing to pursue the most cutting-edge tools and applications, owners must identify and prioritize the use cases that will have both a long-term impact and a medium- to short-term impact to generate momentum. Only by developing a concrete and customized understanding of the return on investment, as well as the risk and disruption to existing functions, can they ensure that new technology adoption is optimized and sequenced according to pressing needs and their distinct circumstances.

Gone are the days when the construction industry can ignore the burgeoning set of technology solutions across the asset life cycle. We expect investment, competition, and consolidation to continue to accelerate as use cases and start-ups serving the industry proliferate. As predictions come to life and new capabilities infiltrate the field, team, and office, the winners will be the ones that adapt—sooner rather than later.

Jose Luis Blanco is a partner in McKinsey’s Philadelphia office, where Matthew Parsons is a senior partner. Andrew Mullin is a partner in the Toronto office; Kaustubh Pandya is an alumnus of the San Francisco office; and Maria Joao Ribeirinho is a partner in the Lisbon and Madrid offices. The authors would like to acknowledge the contributions of Yoav Cosiol , Tushita Garg , Csilla Ilkei , and TG Jayanth to the development of this research.

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Construction equipment market is expected to grow at a compound annual growth rate (cagr) of 4.48 percent until fy30.

According to the analysis by Maximize Market Research, the Construction Equipment Industry growth is supported by sustained demand for advanced machinery and technological innovations. This growth is boosted by strong infrastructure development, increased urbanization and rising investments in construction projects.

PUNE, India , Sept. 3, 2024 /PRNewswire/ -- The global construction equipment industry is set to grow intensely, with a projected growth of USD 263.80 billion over the next decade, reaching USD 194.10 billion by 2030. According to the MMR analysis, China , India , the US, and Indonesia are expected to contribute to 60% of the market's growth over the forecast period. This surge in construction activity is anticipated to drive substantial growth in the construction equipment market.

Massive government investments in large public infrastructure projects, such as roads, highways, schools, and hospitals across North America , Europe , and Asia Pacific , are significantly boosting the Construction Equipment Market. Also, ongoing and planned smart city initiatives are driving spending on construction activities, increasing demand for advanced machinery and equipment to support these expansive projects.

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"Emerging Trends in the Global Construction Equipment Market: Growing Demand for Technologically Advanced Equipment"

The global Construction Equipment Market is experiencing strong demand for technologically advanced machinery, driven by digitization, automation, safety, and sustainability. Digitization, through innovations such as telematics, provides actionable insights that enhance equipment efficiency and reduce energy consumption. Automation and operator assistance are paving the way toward fully autonomous machinery, improving productivity, and addressing complex tasks. Safety advancements, such as remote operation and advanced vision systems, are mitigating job site risks. Also, the surge in market demand for sustainable power solutions, including battery-electric, hydrogen, and alternative fuels, is supporting the industry's transition to greener practices. This growing focus on sustainable technology, coupled with increased government investments and a booming construction industry projected to grow by USD 263.80 billion by 2030 is influencing market supply dynamics. These trends are driving the construction equipment market towards smarter, safer, and more sustainable solutions.

Construction Equipment Market: Segment Analysis

The Construction Equipment Market is segmented by Type, Power Output, Industries and Application. The Industry segment includes Oil & Gas Infrastructure, Forestry & Agricultural, Manufacturing, Military and Mining. The Infrastructure segment dominated the Industries segment of the Construction Equipment Market in the year 2023 due to increased investments in public works, urban development, and transportation projects. These large-scale projects drive high demand for heavy machinery and advanced equipment, surpassing other sectors in terms of expenditure and growth, reflecting the sector's critical role in economic development.

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Asia Pacific Construction Boom Drives Growth in the Equipment Market

The Asia Pacific construction industry is driving the growth in the region's construction equipment market, with an estimated USD 263.80 billion of output in 2030, accounting for 45% of the global sector. This trend is expected to continue, with the region projected to contribute nearly half of the global construction industry by the end of the decade.

Major infrastructure projects across the Asia Pacific are key contributors to this growth. Landmark developments such as Singapore's Gaia Timber Building, China's Suzhou Zhongnan Centre, and India's Navi Mumbai International Airport are leading the charge. These projects, along with sustainable initiatives such as Vietnam's Hanoi Pilot Metro Line and China's UHV Transmission Channel, demonstrate the region's commitment to advanced and eco-friendly construction practices. The emphasis on renewable energy, highlighted by Kazakhstan's 1GW wind energy project, and expansive urban developments including Tokyo's Azabudai Hills, bolster the demand for construction equipment. As urbanization and infrastructure investment intensify, the Asia Pacific region continues a crucial market for construction equipment, reinforcing its position as a global leader in the industry.

Construction Equipment Market: Segmentation

By Power Output

By Industries

Oil & Gas

Infrastructure

Forestry & Agricultural

Manufacturing

By Application

Transportation

Excavation & Demolition

Heavy Lifting

Material Handling

Recycling & Waste Management

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Construction Equipment Market: Top key players

Caterpillar Inc. ( USA )

Komatsu Ltd. ( Japan )

Volvo Construction Equipment ( Sweden )

Hitachi Construction Machinery Co., Ltd. ( Japan )

Deere & Company (John Deere) ( USA )

Sany Heavy Industry Co., Ltd ( China )

Liebherr Group ( Switzerland )

CNH Industrial N.V. ( United Kingdom )

XCMG Group ( China )

Doosan Infracore Co., Ltd. ( South Korea )

Terex Corporation ( USA )

JCB (J.C. Bamford Excavators Ltd.) ( United Kingdom )

Hyundai Construction Equipment Co., Ltd. ( South Korea )

Zoomlion Heavy Industry Science & Technology Co., Ltd. ( China )

Manitou Group ( France )

Maximize Market Research is leading Engineering Equipment, has also published the following reports:

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Precast Construction Market:  Precast Construction Market size was valued at USD 156.81 Bn . in 2023 and the total Precast Construction revenue is expected to grow by 5.6% from 2024 to 2030, reaching nearly USD 229.63 Bn . the Need for Reducing Construction and Cost-effective Products Boost the Market.

Global Vertical Garden Construction Market :  Vertical Garden Construction Market was valued at USD 0.74 Billion in 2023, and it is expected to reach USD 1.30 Billion by 2030, exhibiting a CAGR of 8.2% during the forecast period (2024-2030). There is an increasing emphasis on sustainable design and construction practices boost the market growth.

Global Smart Building Market :  Smart Building Market was valued at USD 89.73 Bn . in 2023. Global Smart Building Market size is estimated to grow at a CAGR of 10.89 %. The growing use of Internet of Things (IoT) devices, sensors, artificial intelligence (AI), and machine learning in smart buildings enables data collection, real-time adjustments, and automation for improved building operations. This is a major driver for market growth.

Excavator Attachments Market : The Excavator Attachments Market size was valued at US $ 6.96 Billion in 2023 and is expected to grow at a CAGR of 5.37% from 2024 to 2030, reaching nearly US $ 10.04 Billion . The Excavator Attachments Market is driven, increasing infrastructure development activities, growing urbanization, and rising construction activities worldwide.

Ceramic Tiles Market  size was valued at USD 326.8 Bn . in 2022 and the total Ceramic Tiles revenue is expected to grow by 7.6 % from 2023 to 2029, reaching nearly USD 545.72 Bn .

Precast Construction Market  size was valued at USD 156.81 Bn . in 2023 and the total Precast Construction revenue is expected to grow by 5.6% from 2024 to 2030, reaching nearly USD 229.63 Bn .

Key Benefits for Stakeholders:

This report offers a comprehensive analysis of the Construction Equipment market, combining both quantitative and qualitative insights. It covers segment analysis, current trends, market dynamics, challenges, and forecasts for the industry from 2024 to 2030.

Utilizing Porter's Five Forces framework, the report examines the power of buyers and suppliers, supporting stakeholders in making informed decisions and strengthening supplier-buyer relationships.

A detailed look at market segmentation covers key opportunities within the Construction Equipment sector.

Major countries within each region are mapped according to their revenue contributions, highlighting their impact on the global market.

Market player positioning facilitates benchmarking and provides a clear understanding of the present position of the market players.

About Maximize Market Research:

Maximize Market Research is a multifaceted Market Research and consulting company with professionals from several industries. Some industries we cover include medical devices, pharmaceutical manufacturers, science and engineering, electronic components, industrial equipment, technology and communication, cars and automobiles, chemical products and substances, general merchandise, beverages, personal care, and automated systems. To mention a few, we provide market-verified industry estimations, technical trend analysis, crucial market research, strategic advice, competition analysis, production and demand analysis, and client impact studies.

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