First half: Pneumatic Conveying System, Safety and Reliability
February 2, 2021Manufacturing Systems and Quality
February 5, 2021With the technological advancement in every field of life, it needs time to integrate methodological frameworks for improved sustainability and resilience based on modern civil engineering techniques.
Abstract
Several tools have been devised for this purpose over the past many years. This research aims to present a combined methodology by weighing the strengths and weaknesses of two common frameworks used.
Exploring BIM in Design Coordination Along With Integrated Project Delivery
Building Information Modeling (BIM) and Life cycle Assessment (LCA) are two of the most well-established frameworks in built environment management, which are actively utilized in the construction industry and facility management industries. Both of these methods support the built environment to attain sustainability and resilience through a predefined set of methodologies. During this research, effort has been made to find the link between these two tools and how the influence of their implication on construction projects
The research undertaken suggested that BIM is an excellent management framework for achieving sustainability and resilience in developing underdeveloped buildings where whereas LCA requires data to deduce results and is useful in the later phases of the construction process which mainly focus on the lifecycle of the product. Many stakeholders prefer BIM over LCA because BIM aids in management, unlike LCA which requires additional work of gathering authentic data. It was also found that BIM and LCA must be combined to get the best results in the built environment.
The following text comprises the introduction of the study.
Chapter—1; Introduction
The increasing expectations of optimum processing and the ability to meet environmental as well as structural challenges have influenced the construction industry worldwide to rapidly adopt sustainable and resilient methods of construction. Stability between environmental, economic and constructional criteria has to be developed so that a sustainable as well as resilient structure is achieved. Many tools/technologies have been devised in the past many years that are promising enough to achieve this objective. The most important goal is to bring these methodologies to light and find out how they can be incorporated to achieve optimum synergy and help in sustainable construction. Most value can be added to the project if these tools are introduced from the earliest possible stage of the construction process (Fiksel, 2006).
Use of Building Information Modeling (BIM) in Construction Industry
In this research study, two of the most influential methods; Building Information Modelling (BIM) and Life Cycle Assessment (LCA), are critically analyzed. Both of these methods are known to be successfully implemented in various construction projects to gain both sustainability and productivity, as projects executed through these tools/techniques are considered to perform more sustainably and productively (Ortiz et al., 2009). BIM can optimize the whole project with a step-by-step integrated approach from the initial design to the end of the product lifecycle. It improves communication between the team members and stakeholders, whereas LCA emphasizes evaluating environmental performance throughout the development of the project (Eastman, 2011).
However, the challenges in ensuring that resilience and sustainability are accomplished in the current construction scenario are increasing with constant changes in various aspects of the built background situation and at the same time the strain restriction of such scenarios is getting more and more inflexible (Anton and Diaz, 2014). Structures are now expected to utilize lesser spaces, manufactured using supplies coming from eco-friendly sources, are expected to be structurally unhazardous to satisfy the requirements of a large number of stakeholders and at the same time should be functionally optimum. According to research completed by Kibert in the year 2013, this is the future of any construction industry.
Sustainability and resilience are the most significant processes of today’s construction industry, especially in cases which are vulnerable to climatic vicissitudes or natural calamities (A. Audenaert, 2013). Practitioners in the construction business have found technological improvements and advancement to be the answer to resolving sustainability and resilience issues. The introduction of applications such as BIM, and concepts such as LCA and BREAM assessment among others, serve to better the sustainability or resilience of the construction project (Arce and Gullion, 2000). It is important to perceive the importance of the usefulness and efficiency of applications and Information and Communications Technology (ICT) suggested methodologies can play an important part in helping the designers and managers choose the most suitable application during project development (Waterhouse, 2011)
The research undertaken in this study evaluates and investigates the various strategies suggested by both, BIM and LCA from the practitioners’ perspective. Collaboration between LCA and BIM will also be analyzed to find out which of the features is best suited for the industry (Chong and Kumar, 2009). Whether or not the project requirement can be enhanced by a deep and thorough understanding of the integration of the two methodologies and the value of their applications is also outlined in this research.
Specifically, the study addresses the following primary research questions;
- How do technological applications improve resilience and sustainability in construction projects? Is there a connection/link between these two tools? What are the common parameters?
- How important is it to incorporate LCA and/or BIM in the policy-making process during the initial stage, considering that the collective goal of the project is to achieve sustainability/resilience and follow optimum environmental principles? What is the connection between LCA and BIM?
- Which of these applications do you think provides a better chance to increase resilience and sustainability in the building industry? Do you think their integration or redevelopment is required?
Research Aims
This research seeks to outline the influence of each stated tool on the construction techniques in enhancing the resilience/sustainability of construction projects. The primary aim of the research is to find the synergies’ between BIM and LCA.
The following are the details of how this primary aim is to be achieved in this study;
- Develop an understanding of resilience and sustainability in construction projects, and identify the link between these terms from the user's perspective
- Identify and outline the role/effect of the latest progress in enhancing resilience and sustainability
- Thoroughly evaluating both BIM and LCA in construction projects. Outline the influence of these tools on successful completion of projects and throughout their life cycle
- Analyze these applications/tools in terms of; advantages and disadvantages, along with their method of execution and their impact on the resilience and sustainability of construction projects
- Determine the capacity to improve resilience and sustainability for each of the techniques. Compare the findings and recommend the best course of action that can optimize the construction processes
- Analyze, evaluate and process the response of actual practitioners on the above-stated points by obtaining data from the industry
Research Objectives
The following are the primary objectives of this research.
- Outline the role of technology in improving resilience and sustainability in building business by recognizing technological advancements.
- To assess the effectiveness of such technologies, via comparative analyses of techniques under study (primarily BIM and LCA). This will include their method of application and their impact in terms of improving the resilience and sustainability of construction projects
- To analyze the performance of the technological tools from the user’s perception. Assessing responses and reviews given by experts based on their performance in the development industry. Undertake analyses of results and present key findings
- Review the findings of the literature review and the data obtained from the stakeholders, and present analyses of the results
- To determine the future use of BIM and LCA as solutions to modern construction requirements
Motivation of Research
Based on the research completed to date, the use of both LCA and BIM has not been presented by researchers and designers in the past to specifically enhance the sustainability and resilience of construction projects. BIM and LCA have been considered to ease managerial tasks such as reducing material waste, using better resources, increasing sustainability in general and also sometimes improving the environment by doing so.
This research paper aims to take this study a step ahead and evaluate the suitability and effects by analyzing the response of construction managers/stakeholders on the impact of the constantly evolving technologies, in terms of improving the resilience and sustainability of any given project. Since many of the researchers have not given due attention to this field of study in the past, this has offered an opportunity to highlight some of the practical concerns of construction engineering practitioners in terms of the application of state-of-the-art tools
Results obtained from this research will help the stakeholders to decide which applications of LCA and BIM, or its integrated form can be utilized to obtain the given results. In short, it will help in better decision-making when considering the use of technology to improve resilience and sustainability. The information can be used by both, researchers and students to:
- Enhance their knowledge of technological improvement
- Realize the probable result/performance of BIM and LCA while it is used to improve the resilience and sustainability of projects
Chapter—2; Methodology
An organized method that constitutes both primary and secondary research has been undertaken to accomplish the research goals of this study. Questions such as who, when, what, how and where, that are associated with the research are important to be answered (Creswell, 2013) and evocative research has been completed keeping all aspects in mind.
The research paper initially covers the literature review to extensively describe and evaluate the previously completed work on both research and industrial scale. This has been completed for the utilization of state-of-the-art construction management/engineering tools to enhance resilience and sustainability. The literature review outlines the technology; BIM and LCA that has been involved to achieve the desired results (Hakkinen and Kiviniemi, 2008). This study does not study the causality but the underlying research on which an improved construction system is based. The literature review provided a platform through which this research paper has been structured.
After successful completion of the literature review, primary research has been completed, details of which are given in the following sections. This included the preparation of a comprehensive questionnaire that was distributed amongst the construction engineering stakeholders across the UK but with a specific focus on the locality of Birmingham. The questionnaire was prepared in light of the primary research aim and objectives documented in the previous section so that specific information could be obtained in a logical and engineered manner
The data obtained from the primary as well desk desk-based research was analyzed and key findings were then discussed, before drawing out a conclusion for this study. However, it is important to note that there might be limitations concerning the relevance of the data obtained in this primary research, as this data may present personal opinions, likes and dislikes of the personnel involved. This may also suggest that the data presented in this paper may not be used as recommendations against any of the tools/techniques under study.
The global challenges such as sustainability and life cycle analyses of buildings have increased with the invention of BIM and LCA.
Chapter—3; Literature Review; Desk Based Research
The designers are now required to integrate the basic performance-related data from the very initial phases of the project. Examples of such analyses include quantity/quality/material surveying, energy performance, social impact and environmental performance analyses on the virtual building and virtual space framework (Kam et al, 2004).
The construction industry works on projects and each project has its unique features. Therefore, the aim of the construction must be to utilize most of the available information productively, and both LCA as well BIM are most suited for this purpose. However, there is a definite lack of standardization of both of these techniques. Therefore, it is not possible to evaluate the performance of any of these techniques without undertaking a comprehensive case study analysis, which is not in the scope of this research (Finnveden G., 2009).
This section of the paper aims to highlight the most influential implications of both BIM and LCA while examining how these provide a supporting role in the construction industry. Sustainability, as well as resilience, cover a wide range of the construction industry’s parameters, therefore effort is made to review how the introduction of these technological tools has impacted these norms in the most fundamental aspects of construction projects (Ortiz et al., 2009)
3.1 BIM Building Information Modelling (BIM)
An incorporated BIM system can collaborate and communicate the various processes between different stakeholders and members of the project. This helps in the development of a solid initial design to a well-built structure and effective performance throughout the project (Hungu, 2013). BIM has a huge influence on design practice because it introduces new methods and techniques of bringing forth new designs, techniques and services. Stakeholders want their work to be completed time effectively, with high quality and in low budgeting manner, along with additional services which do not necessarily include planning and construction techniques (Clayton et al, 1999).
Since BIM is grounded on the strong basis of active communication and exchange of information and technology, this trend is utilized to process, generate, store, transform and/or transfer information. The term ‘Building Information Model’ (BIM) appeared in the 1970s and it originated from the designing and data modelling of machines. The technique, from basic machine modelling and designing, was engaged to plan and construct buildings. Building Information Model constitutes of:
A 3D object that may be a part of a building or set of buildings
Data that defines parameters and interconnects various parameters of the object
Provision of data that specifies and defines specifications of materials/components/objects
Ability to integrate costs, time, schedules, simulations and hence preparation of BOQS and other construction management provisions in real-time
Therefore, BIM allows all stakeholders to perform a quick examination of standards and models and their comparisons by engaging in a visualization process, which consequently can be utilized to enhance the sustainability and resilience of the project (McGraw Hill Construction, 2009). Furthermore, errors can be reduced fairly because most of the issues are addressed and resolved in the design phase, hence there will be fewer conceivable errors and models are promptly updated (Eastman, 2008). BIM encourages participation and collaboration of all the working right from the beginning of the project towards a better sustainable and resilient system, which not only reduces time but also the cost of the engineering process (Eastman, 2008).
Since BIM incorporates an integrated system in the designing process, the conformation plan of a building can be examined both quantitatively and qualitatively right from the primary stage (Eastman, 2008). The resilience and stability of a system can be kept in perspective while working under the strategies of BIM. This means encompassing a wide range of environmental as well as economic factors (Azhar, et.al., 2008). At any stage of design, the stakeholders can review and revise the materials being used to enhance sustainability, reduce the cost and/or increase the lifespan of the product. BIM is not just a structurally stable strategy but it also cuts energy costs by letting the stakeholders plan and integrate their design and constructions using proficient energy modelling tools, hence optimizing the sustainability parameters (Hakkinen, 2008).
3.1.1 Influence of BIM
The overall sustainability of the building can be enhanced using environmentally friendly and competent material selection, waste management, better performance of equipment and an efficient error detection/removal system. With the help of optimized design, it is possible to foresee the structure and view the building at any point of construction, and even after the construction is completed. For cases where specific conditional parameters need to be considered, the use of this computer-aided tool can aid the project management in rapidly changing (in real-time) the simulation conditions so that an optimum environment/structure is developed that can have the strength to meet the specific project requirements. The structural calculation can also be integrated into the BIM database, which means only one software can be used for the overall project management. Therefore, the application of these practices through an engineered tool and integration of these efforts can hence enable the construction of resilient structures.
Managers prefer the use of BIM not only because of its excellent approach towards resilience and sustainability, as stated above, but also because it saves time and cash (McGraw Hill Construction, 2009). Problems are identified before their physical existence and henceforth the communication, understanding, chemistry and concern between the different teams such as planners and builders are developed. Locating and eliminating these errors leads to a stronger, more resilient, and sustainable construction procedure that decreases expenses, lowers legal debates and accelerates the construction procedure (Eastman, 2008).
According to McGraw Hill Construction, a study concludes that architects feel more comfortable and add value to the work if there are fewer hindrances and clashes in the project. Even in the case of an honestly overlooked human error, the lapse is quickly identified and swiftly corrected resulting in a near-perfect execution (Eastman, 2008). The components are in the form of 3D visualizations in BIM hence they can be produced using digital technology which means not all of them have to be constructed right on site (Azhar, et.al, 2008). This saves expenses and development time. Moreover, the waste on site is reduced if the components are shipped from off-site which reduces waste management expenses and time (Smith, 2007). Hence this method is considered to be much more sustainable than any other technique.
Implication of BIM in construction projects also helps the site managers by offering a large number of data sources to choose from which can be used to check the order and function as the construction proceeds (Eastman, 2008). This includes the materials quantities, sizes, and costs, along with details such as warranties and insurance of various components, helping the planners in managing the project (Ballesty, 2007). The design and construction tools such as quantitative databases, programme development functions, simulations, dynamic modelling, logic control systems, delivery frameworks and automated creation of BOQs are at the service of all stakeholders as soon as the project planning begins when using BIM (Sahely, 2005).
Hence it be concluded that the implication of BIM has introduced systems that can effectively enhance the sustainability as well as resilience of the construction project in various forms. When utilized properly, this engineered tool can produce many benefits for the stakeholders of this industry
3.2 LCA; Life Cycle Assessment
LCA can be defined as a systematic methodology to assess the influence of the environment that is related to the product’s lifecycle from “cradle to grave”. A complete LCA deals with each phase of a product’s lifecycle and considers the concerned waste streams, withdrawal of raw material, subsequent uses, material handling, product manufacturing, utility, transportation, restoration, conservation, and discards related to the product as well as the recycling and end-of-life disposal service. It is important to note that the practice of construction plays a vital role in regional, global and national environmental impacts. Quite a large amount of research has been done on raw material processing and manufacturing and a few researchers have also looked into the after-use possibilities of commercial buildings (Guggemos and Horvath 2003).
However, the applications of LCA in the construction industry can be referred to as sustainable designing, as it emphasises careful evaluation of the environmental impact of chosen materials and component(s). This is accomplished by using the already available techniques and models. As discussed earlier, LCA can be defined as the collectiveness and evaluation of feedback, outputs, and all the energy contributions to and by the product throughout its lifespan. (Guinee et al, 2011).
The LCA methodology can not only insight into the product’s energy consumption but also into the built environment and the hazard resistance of building structures, which is why this method can be applied at the primary design stage of construction projects. But can this technique provide support in terms of the resilience of civil engineering structures? To answer this question, it is important to review the basic functionality of the complete LCA system when applied to construction projects (Heijungs R., 2010).
Several principles are considered before performing a life cycle assessment (LCA) on a construction project.
- Aim and Scope of Analysis
The aim of LCA depends on the type being performed and the results needed to be catered in a construction process, such as to analyze the most sustainable and resilient solution for the construction design. This purpose or aim of assessment can then be further divided into smaller units within the project to perform a comprehensive study and present results that are based on factual information (Baumann and Tillman, 2004). It is also important to know the scope of assessment to find energy consumption, waste management and economic impacts of each unit under analysis.
- Inventory Analysis
Inventory analysis consists of gathering and demonstrating data for further study. Data is in the form of inflows and outflows of individual units or phases of the design and construction process (Baumann and Tillman, 2004). Availability of data is ensured and quality of data also plays an important role in visualizing a desired output design. Targeting sustainability and resilience, it is made sure that all materials provided in different phases are standardized and reliable. Data and information are cross-checked to avoid any unforeseen circumstances. At the end of inventory analysis, data is in the form of figures representing the energy consumption, emission, waste production and resources utilized throughout the project (Sophia, 2009).
- Impact Analysis
The purpose of impact analysis is to make the results made from inventory analysis easy to comprehend and communicate between stakeholders and development phases. The impact analysis helps choose the right category based on its impacts on an overall developmental project for a certain factor and helps in dealing with it. It therefore smooths the flow of tasks and aids the inventory analysis procedure. The impact can be long-lasting or short-lived, depending on the inventory under consideration. This step plays an important role in attaining a sustainable and resilient system by eliminating the long-term negative impact and including an alternative that has a slightly better or less grave impact (Baumann and Tillman, 2004). Material is chosen based on their long-run results in impact analysis.
3.2.2 Influence of LCA
LCA has also been found to play a significant role in assessing the effect of a construction assembly during its existence and afterwards. The International Organization of Standardization’s 14040 series defines steps for typical LCA assessment based on materials, construction, and demolition of a building, and this information is further computed into energy and carbon footprint equivalents, as well as the demonstration of source utilization and discharged radiations. The data is used by architects, structural engineers, workers, and vendors that have to deal with the prediction of environmental and structural impacts during a structure’s life.
As discussed previously, LCA involves a detailed Inventory analysis which includes the collection and modelling of data and then forming the results in the form of a chronological flow chart that is the collective effect of inflows and outflows of various processes (Baumann and Tillman, 2004). Based on the available data, each process can be examined under the light of their resilience and sustainability attributes. Cross-checking the data makes the source more trustworthy and data quality is enhanced. By the end of inventory analysis, the practitioners can have the figures of overall radiations, waste material, energy consumption and raw material utilized during the whole lifecycle (Baumann and Tillman, 2004). This helps the stakeholders build a more sustainable and resilient structure that is well-researched and more rich in information.
The next step right after the inventory analysis is to assess the impact of the data available. The impact can be environmental, social, economic, ecological and/or structural. This makes the results obtained more easy to understand and communicate the important factors between various levels of stakeholders. This leaves out any unimportant data results that are useful for one stakeholder but unimportant for others. The environmental impacts are divided into some vast categories namely, resource use, human health, and ecological consequences (Ochoa et al., 2002). Further categories of important factors, such as structural resilience, can again be categorized for priority cases by the stakeholders of the project. According to the research completed by Baumann and Tillman in 2004, the specified steps to perform impact assessment that is standardized for many types of LCA studies are;
- Choosing the preferred impact types.
- Organization inventory outcomes in the most suitable impact Type.
- Classification of effects in each type using calculations.
- Optional analysis like the weight of impacts in various categories, to easily relate them with one another, and data can be normalized quickly, making it easy to see how it relates to reference values.
- Impact types can be selected in a way that they portray the overall situation of the conservational or other factors.
An LCA model essentially consists of four phases that are repeatedly used in the process. The steps include objective and aim designation, life-cycle standard LCI evaluation, life-cycle control estimation, and investigation. LCI is a common practice when LCA study is not applicable due to structural compatibility, incomplete development and other such issues in the LCIA stage. Several LCA development strategies are progression-based (Keoleian et al. 2000) or IO methods (Ochoa et al. 2002). A substitute is a mixture of LCA displaying which incorporates the features of both these systems to create a system that is a crossover.
The LCA development model is a complex tool because it is dependent upon numerous sets of data resources. Creating a framework for the project assigning various data resources and integrating data can be puzzling from a large scale as well as a smaller point of view while keeping consistent units and unit conversions in mind (Ortiz, 2009). The whole construction procedure is divided into several smaller units for each construction-specific process, which is unique in one way and very common to each other in many ways. Many of the construction model processes comprise fuel combustion, and related fuel equipment to find out the transportation needs and to estimate the total expenditure of temporary materials in construction. The structure and complexity of the mode are determined through extensive examination tools as an assessment method to find out the significance of a scheme.
Usually, the impacts of on-site construction are overlooked, resulting in a gap in understanding of realistic environmental impacts due to the construction process. A recent study on construction projects during the 2008 Beijing Olympics revealed that the air quality is also affected by construction activities. Life-cycle assessment is an efficient ecological administration methodology that comprehensively breaks down and evaluates the natural effects of an item or procedure. It can be used for decision-making to conserve the global, national, and provincial effects on social and biological issues, for example, human well-being, asset exhaustion, and biological community quality. It is specialists are frequently confronted with making difficult selections identified with choosing the fitting degree or limit of the investigation, the wellsprings of information for lifecycle inventories, programming, and effect evaluation practices.
3.3 Comparison and Integration of BIM and LCA
A study completed by Kubba (2012) and Becerik-Gerber and Rice (2010) shows that the evaluation of a proposed scheme and deciding whether or not it fits the criteria set by the owner can be easily assessed by creating a schematic model before the actual detailed building model. This can help decide the important factors like sustainability, resilience and functional requirements and also aid in increasing the project performance and general quality of service.
Therefore, it can be suggested that the utilization as well achievements of technological tools are dependent upon the priorities and objectives of the project stakeholders, and both techniques have definite potential to enhance the sustainability as well as resilience of the construction projects. These techniques can also be integrated to meet the standards set for the projects. A technique suggested by Jrade and Jalaei (2013) focuses on achieving a sustainable design while taking into account environmental impacts by combining BIM, Management Information Systems, and LCA; so that resilience as well as sustainability goals are successfully achieved for a given construction project.
But what is the link or the common parameters of the LCA and BIM? What are the basic parameters that are covered in both techniques?
The basic parameters that are influenced through both BIM and LCA in terms of sustainability and resilience are quantification of resistance to hazard, building design, durability of materials and material analyses. BIM makes it possible for various disciplines to superimpose their information. Hence structural, mechanical, electrical, plumbing lighting etc. information is placed over a single model (Tucker and Newton, 2009). It allows the practitioners to understand the step-by-step processes involved in construction and envisage the 3-dimensional placement of the building (Eastman et al, 2008). Each stage of a construction life-cycle assessment can have an influential impact on the processing of natural resources, production, construction, usage and preservation, repairing and finally demolishing, which can consequently perform a significant role in environmental influence and resilience. Studies propose that the threats related to the environment during the construction stage are not well acknowledged (Hendrickson and Horvath 2000). LCA is the best-known tool to calculate and evaluate the environmental impacts of a product or process.
Of most of the research work completed on these technologies, the comparison between any two is extremely difficult, because each of these tools focuses on a different aspect. Although both LCA and BIM can be a good source to enhance the sustainability as well as resilience of the project, both of these techniques have their specific/unique application models and purpose of utilization. BIM is fundamentally used for overall project management;
- It offers a set of methodologies and courses to enable all the concerned stakeholders to work together in designing, constructing, operating and sustainably managing the existing facility according to their requirements. (Succar, 2013). An information model that is well-informed and has several data sources, data linking and data can be shared among the stakeholders and modified, altered and manipulated at any time from the inception of the building to execution and recycling (Waterhouse, 2013). Data modelling and visualizations are technology-based which means any functional or physical trait and its environment can be foreseen and compared, this results in better decision making (ISO/TC 59/SC 13).
Whereas the LCA technique primarily offers the;
- A systemized environmental assistance framework that thoroughly evaluates and considers the environmental impacts of a product or a process. LCA focuses on matters such as carbon footprint impact, global warming potentials, volatile organic compounds waste that threaten the integrity of nature and environment, fuel consumption and various types of wastes. The construction stage is of the same importance as any other lifecycle stage, the study shows. Research on environmental impacts of buildings essentially concentrated on a) energy consumption during construction projects, b) material manufacturing on-site and off-site and c) waste management upon project completion.
A solution to revolutionize design methods and effectively produce high-performance designs for proposed buildings is possible through a combination of BIM technology and LCA, as synergies exist between both of these techniques in terms of sustainable and resilient design strategies. Since BIM facilitates the complete project through an integrated designing strategy and LCA is considered the method best suited to assess the environmental impact, a broader approach could be adopted to integrate LCA with BIM to achieve a higher level of sustainability, efficiency and resilience for any given project. This integration can also potentially eliminate the limitations of any one tool, such as the lack of data availability for LCA, encouraging ease of decision-making during the early design stages of the project. Alton, 2014 completed a SWOT analysis on this integration suggesting the strengths of the engineered integration as;
- Rapid and efficient methods — the relevant data is more efficiently utilized for environmental, social and economic norms
- Improved efficiency — building suggestions can be extensively examined and designs can be corrected to cut short expenses and times or structurally improve the building to increase resilience.
- Sustainability issues — innovative solutions to every issue during the construction project lead sustainable selection of choices. Moreover, environmental benefits are extended
- Improved quality of product— with the adaptation of modern techniques and technology updates, the quality of the end product increases manifolds.
- Automation — the product data is computerized and can be used in various processing and assembling techniques, making it easier to obtain, analyze and update data, especially during the early stages of the project
- Stakeholder satisfaction — Integration not only helps the managers and planners but also helps the workers and clients collaborate better through an engineered technique.
- Incorporation of planning and execution — data recording, planning and execution happen simultaneously; adding value to time and helping build a communication-friendly environment between various stakeholders.
- Enhanced environmental assessment and making it possible to compare various predicted environmental performances.
Need Help with Academic Writing? Get a Response within 24 Hours!
According to this assessment, integration of these tools can result in exceptionally resilient and sustainable structures. This can revolutionize the way data is manipulated, errors are compensated, and buildings are foreseen at any point in time, specifically concerning environmental performance. This can lead to unmatched prospects of production, storage, enhanced resilience, stability, and sharing/transformation of pivotal information. Data could be exchanged and the best processes can be chosen based on their stability, and resilience keeping the environmental issues in perspective (Garagnani, 2013). This collating of information, incorporating consistency and fostering collaboration and coordination among different actors and professionals can result in structures that are more intelligently managed. This is further discussed in the later sections of this paper.
Chapter—4; Results; Primary Research
As indicated in the literature review section of this paper, utilization of state-of-the-art computer-aided technologies, such as BIM and procedural frameworks, such as LCA, can provide support in improving reliance as well as the sustainability of construction projects. However, during the desk-based research, it was found that since BIM is a more user-friendly and multidimensional tool, it is at an advantage, especially concerning constructional resilience. Whereas LCA, when applied to enhance sustainability, can produce optimum results for any construction project. However, it has been proven difficult to extract comparative-based results on these techniques from the reviewed literature. Therefore, it was important to obtain the views of the construction engineering practitioners; to develop an understanding of these tools that are being utilized to enhance sustainability and resilience, and also to find the user perspective on the connection between the two technologies under investigation.
Therefore, a survey questionnaire was developed which included descriptive as well as multiple-choice easy-to-fill questions. This was distributed across several construction companies across the UK as well as within the city of Birmingham. Site managers, assistant site managers, site supervisors, project leads and executive project managers were engaged in taking the survey. The questionnaire was distributed among large and small construction companies, including the designing companies that have been part of the building business for over 5 years. The project managers, project leaders and project directors having relevant experience in the field and construction industry were the target of this survey.
The details of the questionnaire have been included in the appendix section of this paper. Out of the 150 practitioners contacted online (through e-mails and/or online available contact), 57 personnel responded. Some of the respondents were associated with the same organization, however, this data was not filtered since the aim was to obtain views from a maximum number of practitioners. This was also not considered as it was important to explore the approach of various team members at different stages of project completion.
Some of the practitioners did not hold enough accreditation to be made part of the research and their information was not included in the data processing. Moreover, the responders who were not using BIM or LCA tools had to be excluded since they failed to serve the purpose of this study. So out of 57, 46 survey questionnaire forms were considered (Please refer to Appendix for details about the questionnaire)
Following is the pie chart of the designation of people who took part in this survey.
Figure 1; Roles of interviewees (sources: data obtained from questionnaire)
Although most of the questionnaires were mailed to companies, some were delivered by hand to related companies situated inside Birmingham city. It was encouraged that the survey was filled by a senior concerned member of the construction team such as the site manager or assistant site manager.
The main focus of this primary research was to view in terms of; the best solution from LCA and BIM, how to improve resilience and stability in a construction process., the impact of LCA and BIM on resilience and sustainability of a construction project, the connection between LCA and BIM, how can the practitioner describe resilience and sustainability and which technique, and to obtain views on which of the technique can be best utilized to achieve resilience and sustainability. The descriptive questions were not customized so that the practitioners could present their opinions in their own words based on their practical knowledge.
The multiple choice questions were customized for both LCA and BIM techniques, based on performance, importance of resilience and sustainability on construction projects. Furthermore, questions related to prioritizing the factors based on importance in the construction process and overall life cycle and the Importance of environmental impact on the end product were also included in the questionnaire. The connection between LCA and BIM-based on performance in construction projects, the importance of an environment-friendly methodology, which technique is better and which is comparatively difficult to implement were also considered/included while drafting the questionnaire
4.1 Results from Questionnaire:
4.1.1 Descriptive Questions:
The scope of the descriptive questions was to find out the approach of participants towards basic methodologies and how can sustainability and resilience be enhanced by using LCA and BIM according to their point of view. The table below presents the basic questions included in the data collection
Table 1; Descriptive interview questions
Descriptive Question |
How would you describe resilience/sustainability in construction projects? |
What are the connections/links between the LCA and BIM? |
What do you think is the impact of LCA/BIM in terms of resilience and sustainability of projects? |
In your opinion, which of the techniques can more effectively address sustainability and resilience issues, and why? |
In your opinion, what do you think is the best strategy to optimize and/or integrate the project's sustainability and resilience? |
In response to the question related to resilience and sustainability and their connection, the majority of the respondents suggested that although these terms can be expressed as similar from a general perspective, however in a more technical perspective, these terms hold their specific relevance. As one of the respondents quoted;
“Resilience and sustainability cannot be used interchangeably; this is because they present different aspects of the construction system. Projects are managed in such a way that the system presents sustainable practices, however, it may or may not ensure that structure itself is designed with resilient qualities“
(Senior Construction consultant/site manager)
Another respondent to this question in a different way;
”A sustainable system can be defined as a system that can overcome instability, which is the same as resilience. A sustainable building will face minimum outside disturbances and a resilient system will overcome them very quickly. This means that a resilient system points towards sustainability”.
Regarding the question related to the connection between LCA and BIM, the majority of the practitioners agreed that BIM and LCA both play a vital role in achieving resilience and sustainability, one way or another. In many of the forms received, the connection was defined as an ‘engineered approach’ that is adopted in both techniques to enhance the overall productivity of construction, as indicated by the responses below;
“LCA and BIM both work towards sustainability and overall project performance enhancement. BIM is a project management tool whereas LCA increase the lifecycle, and both help in sustainable construction in so many ways”
“Both allow sustainable construction approach and enhance work ethics. Increases productivity”
(Site managers)
Upon asking which tool has so far helped them more in attaining sustainability and resilience, an amazing number (38/46) replied that BIM has been utilized more effectively in their experiences. Many of the respondents suggested BIM is more actively used and addresses many of the constructional activities, hence suggesting that it is the tool that can be best utilized under varying circumstances
“Depends on how one uses it. BIM is being more frequently and effectively used than any other construction tool. LCA is a good approach, however, less utilized on construction sites”
“BIM is an effective system. LCA has its advantages such as energy conservation, waste management and enhanced product lifecycle. BIM, on the other hand, makes the construction process more manageable”
(Site managers)
When enquired about the best strategy to optimize and/or integrate project sustainability and resilience, the majority of the respondents suggested that it is the approach towards construction that matters the most. Many of the personnel who filled out the forms indicated that the optimum strategy is to undertake the best practices and consider all the elements involved. Some of the respondents also added that an integral form of approach can result in the best results. Some of the responses were as follows;
”Neither BIM nor LCA can be taken out of the picture. LCA increases lifecycle which is excellent and BIM eases the processes. Maybe the future is for an integral approach”
“…Construction is a complicated practice, as the complete life cycle of the buildings have to be considered, sustainability and resilience against harsh environments requires the use of both techniques… and “… To meet the diverse set of client requirements, a combinational use of techniques are required…” and “self-sustaining, self-sufficient system requires the use of both BIM and LCA”
From the results obtained/presented, it was observed that for most of the construction managers, the decision of selection between LCA and BIM is dependent upon the project priorities, such as how much importance is given to resilience, sustainability, the ability to cut energy costs, waste management, timely delivery and evenly distributed workload etc. Most of the site representatives were convinced that BIM is important for the successful completion of a construction project and even during the whole product life cycle. On the other hand, it seems that there is a general lack of information on the complete implementation of LCA stages. However, LCA was suggested as an extremely important practice when addressing the environmental concerns of materials used in the construction process
4.1.2 Multiple Choice Questions:
The multiple-choice questions were targeted to obtain practitioner’s views on specific elements of the construction requirements. When asked about how important they think is sustainability for their projects, the following response was received;
Figure 2; Fundamental research questions (sustainability importance) results
This response showed that more than 65% of practitioners believe that sustainability is the most important attribute of a construction project. 32% thought it to be important and only 2% thought it to be fairly important.
Similarly, upon asking the importance of resilience for their construction project, the response received looked like this:
Figure 3; Fundamental research questions (resilience importance) results
In this case, 56% of the managers beings asked about resilience replied it to be most important. 39% of the practitioners declared resilience to be important for their construction projects. Only 5% considered resilience for their buildings fairly important. These results show that sustainability is slightly more important from the perspective of site managers. Since none of the practitioners that were being surveyed think that sustainability and/or resilience is not important, confirms the fact that all personnel involved had utilized BIM and/or LCA in their previous 5 years of practice to enhance sustainable practices at their respective construction sites.
To gain an opinion of the technology that is best suited for the subject matter, various questions were drafted for the practitioners. The following graph demonstrates the performance and applicability of BIM by the participants in terms of resilience and sustainability
Table 2; BIM Rating (sources: data obtained from questionnaire)
As shown in the graph above, the majority of the responses are divided into either excellent or good ratings. 45% of the participants who took part in the survey pointed out that the application and its performance are excellent. On the other hand, 48% rated the performance and application of BIM to be good. To another question most of the participants also suggested that BIM is a relatively better technique in terms of impact. From these results, it was observed that the overall rating of BIM based on their practical application and advantages is excellent. Users of this tool are hugely satisfied with their choice. BIM was the number one choice for achieving better results in a construction project.
The following graph demonstrates the performance and applicability of the LCA rating by the participants in terms of resilience and sustainability.
Table 3; LCA Rating (sources: data obtained from questionnaire)
The graph based on the answers given by the responders demonstrates that LCA is not as favoured a tool as BIM when it comes to performance and practicality. Many companies do not use it altogether and some of those that do utilize it at a very later stage of construction (once the construction resumes or procurement practices are initiated). The majority of the participants further suggested (to another question) that LCA is a relatively more difficult technique to implement, especially concerning resilience. Based on this survey, it is safe to state that LCA needs to be brought more into light and research must be done for stakeholders so that they can fully benefit from it.
The link/connection between the two tools under study was suggested as follows;
Table 4; Link between BIM and LCA (sources: data obtained from questionnaire and interview)
As can be seen from table 4 above, almost all the participants agreed that both tools (BIM as well as LCA) can enhance sustainability and project productivity; as it was suggested as the strongest links (. Environmental performance enhancement was also considered to be a strong link by 33 participants, however, a lesser number (27) believed that resilience is a strong link between the two tools. A similar pattern was observed in another question in which the participants suggested that sustainability and productivity are the prime concern of the practitioners
Another set of questions which were tailored to gain views on how the systems can be improved and which strategies can be utilized to obtain the optimum results. The implications of these results are outlined in the Chapter below.
The following chapter is related to the discussion of the study.
Chapter—5; Discussion
It was observed from the primary research completed that the stakeholders prefer to use BIM and highly recommend it.
5.1 Key Observations of Results
The most common logic that can be drawn from practical research and literature review suggests that since BIM allows one to foresee the various phases and helps in resolving conflicts of interest, undertakes comprehensive designing/simulations, and increases cost efficiency, BIM has been preferred by practitioners. BIM is considered to have an equally influential impact on both resilience as well as sustainability, as observed from the research completed.
Another interesting observation that was made during the survey was the fact that many stakeholders may not consider the product life cycle and environmental impact as their primary concern, probably because this impacts years after the completion of the projects, as indicated from the summarized results presented below. Site engineers are less keen on environment conservation and the impact their built project brings to it, as compared to other factors. Also, the product’s lifecycle, which comes once the building is ready to be used, is observed to be relatively underestimated by stakeholders when, in fact, it is the extremely important stage when sustainability and resilience are being tested and judged. This factor could have resulted in the lack of optimism received concerning the utilization of LCA in the construction industry
Figure 4; Results Comparison (questionnaire), 2015
Note: The results above present processed data in a summarized form, obtained from various questions included in the questionnaire
Figure 4 above shows how the participants responded to questions related to the importance of various attributes for optimum project management. For example, according to a large number of respondents, sustainability was considered the most important factor/attribute. However, It was obvious from the above bar graph that a large number of construction managers consider resilience, sustainability, the ability to cut energy costs, waste management, timely delivery and evenly distributed workload as important factors and use them as a decision-making tool for choosing BIM or LCA. This goes on to show that since the stakeholders prefer most of the attributes as important, they are keen to work with a system that can cater to all these attributes with minimal effort.
Although some of the site representatives were convinced that both of these techniques (BIM and LCA) are equally important for the successful completion of a construction project and even during the whole product life cycle, however, overall results indicated that LCA was not rated as highly as BIM, especially concerning the initial stages of projects. In the case of most of the projects, there is an overall absence of data in the primary stages so BIM comes in handy when several options and implications of each tool are placed in front of the manager to choose from. It gives a degree of freedom to all the stakeholders as the project proceeds. Each stakeholder is involved and hence demands are well catered to at any stage of construction. This was also indicated from the results where most of the respondents stated that a step-by-step understanding of the design-related parameters is extremely important, and hence probably BIM was preferred.
A large number of participants agreed with the statement that “A devised methodology must focus on sustainability/resilience along with product’s energy consumption”. They further agreed that “Defined procedures (through a central agency/frameworks) requiring specific use of tools can enhance the sustainability as well as the resilience of construction projects”. These statements highlight the fact that there is a need to develop a standardized form of tools which can be managed and implemented through a central governing agency. However, in the current industrial scenarios, sharing critical information is quite difficult.
5.2 Discussions and Recommendations
Summing down the previous discussion, it was concluded that sustainable and resilient are the tools to judge a construction’s performance based on environmental, social and economic criteria. This helps in fair and informed comparison between various alternatives while the design framework is kept in perspective and this makes the handling of a huge amount of data fairly easy. According to primary research, sustainability and resilience can be achieved by both the techniques under study; BIM and LCA. This not only helps the environment but also keeps important factors such as life cycle, energy conservation and waste management processes stress-free. In short, the techniques, in one way or the other, help all the stakeholders directly or indirectly related to the project.
Sustainable design should be comprehensive, having more ventures made in the initial stages, but at the same time regarding the life-cycle of the building as an entire piece. Sustainable construction is not a complex or luxurious trend that does not pay off, it is an implementation of integrated design which considers all aspects of a project within a complete model instead of being analyzed as an individual component. Design plays the most important role. One must try to restrict the use of energy, excessive resources and end up creating an environment that is low in cost, functional, practical, and comfortable and environment friendly. These are elements where BIM plays a highly influential role, and hence much utilized in the current construction industry of the UK.
LCA also offers resilience and sustainability attributes but it has yet to find its proper implication to fully benefit from this tool. Dealing with environmental impact and insinuations caused to it by the construction project. Working on LCA also increases social awareness and hence conserves the environment while the project proceeds. The final budget of the project does not include environmental effects; hence this can help in lowering costs immensely. Moreover, conserving the environment means conserving nature and the ecosystem which contributes to sustainability and resilience against some of the most challenging and extreme natural conditions. The need of the time is to realize the importance and impacts of the environment in human’s daily lives. Stakeholders need to realize that the most significant part of sustainability is environmental and both others: economic and social hugely depend on it.
The reason why LCA is not favoured by many is that there are no methods or tools designed entirely for measuring the impacts of the life cycle assessment process. It is so far underrated because the extent of resilience and sustainability offered by the LCA process depends on the databases available and the inclusion of factors. During the project, many factors keep changing and it is impossible to predict the results completely based on incomplete data, hence LCA cannot be evaluated based on all the factors. Thus the results are vague and not very reliable. Furthermore, there is a lack of input during the designing stage of the project in this technique, especially in terms of the design of the structure, therefore it has not been widely appreciated concerning structural resilience.
5.2.1 Future Research Opportunities
LCA focuses more on environmental stability whereas BIM promises socio-economic betterment from a project. Both are two different but equally important approaches. It is the need of the hour to incorporate or integrate both these techniques to achieve a long-term, sustainable and resilient solution for the construction projects. This will help stakeholders belonging to various domains to achieve their specific goals without compromising on their dynamics and elements. LCA helps in the overall product’s lifecycle whereas BIM is the systematic approach during product creation to achieve the best form of a building. BIM brings all the investors close and benefits them all without damaging anyone’s interests. LCA comes into play once the product is out and about the market. It smartly considers several data sources to form a flow chart and identifies the strengths and weaknesses at a given time. Many onsite engineers and managers fail to provide the constantly changing data at the time of project execution. Hence most of the practitioners rated LCA as a more difficult technique to implement with limited resources of data at earlier stages
Therefore, a more integrated approach to research and practice is required especially for the incorporation of various disciplines, sections and phases of the project. This approach can offer a solution that is based on extensive communication between various levels and stakeholders as well as based on life cycle analyses of the structures. This approach can allow all shareholders to execute a quick inspection of criteria and quality by comprehensive evaluation and this can be used to enhance the sustainability and resilience of construction during and after project execution.
Furthermore, this approach can avoid complexities in dealing with the environment and lifecycle of the product fairly easily. The integrated systems can have the potential to cater to all the stakeholders and their conflicting interests without straining the cost and product’s usage/life cycle. This approach was also preferred/recommended by practitioners who took part in this research
Since energy conservation helps in cost control which is the ultimate goal of any stakeholder, this data can be integrated into computer-aided tools such as BIM to attain the best possible results, as cost and energy reduction are the two main factors considered while deciding the tool to be used in project management. Moreover, a resilient system must also be cost-effective and vice versa. This simply implies that a resilient system will return or try to return to its stable state without an outside effort i.e. budget for maintenance is reduced to its minimum. Therefore this recommended approach can prove to be a viable solution for the construction industry.
Therefore, future research is recommended to work on the procedures or a computer-aided tool/application to be developed which can meet the attributes of both BIM and LCA and in which data can be easily shared/transferred across different formats. Moreover, research can also be completed on aspects of LCA so that can be more extensively and effectively utilized in the current UK construction industry
Chapter—6; Ker Leanings / Conclusions
According to the literature reviewed and the research conducted in preceding chapters, it has been observed that BIM is a more commonly used technique and is preferred over LCA when considering the resilience and sustainability of a construction project. As indicated by the data obtained, most of the site workers/engineers rated the performance and applicability of Building Information Modeling (BIM) better than that of Life-Cycle Assessment (LCA). This is supported by our literature review in secondary research which says that since BIM is a more systematic and orderly process which involves communication between various stakeholders, it is mostly preferred over LCA which plays a role in later stages of development.
More than 80% of our survey participants felt more comfortable in using BIM for effective project management. This trend was also explained by the literature review: BIM allows the stakeholders to visualize the construction at any stage of the construction phase. This helps in foreseeing any errors or potential threats to the design and a strategy can be devised accordingly. This hugely cuts down the effort and finances required to bring a change in the structure of an under-construction building. LCA on the other hand does not necessarily support the stakeholders but rather is used for the product itself. It can determine the environmental impacts of a building and its performance analysis once it becomes a practical part of the environment and helps in energy consumption analysis and conservation. However, its attributes specific to the resilience of structures are yet to be addressed as it is normally not a part of the designing processes.
Our survey suggested that more than 65% of clients and stakeholders are interested in a cost-efficient solution for their construction projects. Both BIM and LCA can save money when used in construction during and after the manufacturing of a product or building. BIM helps in the timely identification and removal of errors that result in a resilient, sustainable, cost-effective and sound construction procedure that is not only cost-effective but also long-lasting.
Architects are more at ease while working with BIM techniques and this trend is indicated by our survey. This is because BIM adds value to work, and resolves conflicts of interest between different stakeholders and different levels. It also helps identify structural or design errors way before they occur and impacts the sustainability of the building. This reduces on-site management tasks and the burden can be divided into various levels, hence BIM makes the process manageable for all the stakeholders. BIM plays a great role in improving both sustainability and resilience by using technology that has been more recently optimized. The stakeholders communicate for the best possible solution for construction issues which fosters effective understanding, consideration and interest among them. LCA is a systematic process that is environment friendly with minimum waste material disposed to the environment.
High quality, cost-effectiveness and time conservation are among the main concerns of stakeholders when they choose a framework for the construction project. LCA offers high-quality end products provided all the data resources are already known and calculated. LCA offers a systematic solution which is based on collecting and modelling data. In most of the cases, estimating the data at the beginning of a project is realistically impossible. Many stakeholders do not have enough resources to collect and foresee data which is why LCA cannot be effectively implemented on a large scale.
However, LCA still requires additional work and effort so that it can be effectively implemented. Better-researched plans can include inventory analysis and inflows-outflows of processes, this increases data quality and in turn, helps stakeholders build sustainable and resilient buildings that will be able to withstand unfavourable conditions. LCA underscores the influences of various types of data on the overall integrity of the building before, during and after the development process. LCA is an environmental, social, economic, ecological and/or structural friendly technique. All the stakeholders, in one way or another, can make use of this technique to achieve the desired output from the project.
There is a strong link between LCA and BIM. The connection was suggested as; productivity, sustainability, environment and resilience (sustainability being the most relevant). Since both these techniques are highly useful, an integrated approach in the prospective future is recommended to enhance the overall performance of construction in today’s demanding era. This reveals an opportunity for the researchers, IT specialists and other stakeholders to work towards integrating the benefits offered by systems such as LCA into more comprehensive computer-aided tools.
During this research, it was also observed that there is no legal framework or any other form of system that details the necessity of using state-of-the-art technological tools. Even BIM on its own does not have a standardized format and is unable to integrate import information from other sources/software/tools into its database. LCA on the other hand can be utilized through so many different methods and techniques. Therefore, a lot of work is required to standardize all the technologies have to offer so that a wider range of teams can benefit from such resources.
6.1 Key Conclusions
- Sustainability, resilience, high quality, cost-effectiveness and time conservation are among the main concerns of stakeholders when they choose a framework for the construction project.
- BIM is a more common method among the stakeholders and is preferred over LCA, however, both tools can be utilized to enhance resilience as well as sustainability
- The connection between the two techniques is more or less suggested as the ‘project productivity’ by the participants
- 80% of the participants of our survey used BIM because it is management management-friendly and cost-effective strategy and can cover aspects of construction projects. BIM not only foresees errors but also helps in finding a solution to them even before the design process. This helps in achieving long-lasting results.
- LCA demands knowledge and data sources from the beginning of a construction process to fully prospect the outcomes of a product. The complete knowledge is not possible at the initial stage. LCA is comprehensive while BIM is a systematic procedure.
- Integration of BIM and LCA is considered as the way forward by a large number of practitioners
Chapter—7; References
Álvarez Antón L., and Díaz J., (2014). “Integration of Life Cycle Assessment in a BIM environment,” Creative Construction Conference 2014, submitted for publication.
Arce and Gullon (2000) The application of Strategic Environmental Assessment to sustainability assessment of infrastructure development, Environmental Impact Assessment Review, 20(3), pp. 393-402
Azhar, S et al. (2008) ‘Building information modeling (BIM): now and beyond’, Australasian Journal of Construction Economics and Building, 12 (4) 15-28
Ballesty, S. (2007) Building Information Modelling for Facilities Management. Queensland, Australia: Project report by Co-operative Research Centre (CRC)
Baumann, Heike, and Anne-Marie Tillman, (2004). The Hitch Hiker’s Guide to LCA. Lund: Student literature AB, 2004. Print.
Becerik Gerber B. and Rice S. (2010). The perceived value of building information modeling in the U.S building industry, Journal of Information Technology in Construction, Volume 15, p. 185.
Buyle M., Braet J., and Audenaert A., (2013). “LCA in the construction industry: a review,” Renewable and Sustainable Energy Reviews, vol. 26, Oct. 2013, pp. 379 – 388
Chong W., Kumar S., Haas C., Beheiry S., Coplen L., and Oey M., (2009). “Understanding and Interpreting Baseline Perceptions of Sustainability in Construction among Civil Engineers in the United States,” Journal of management in engineering, vol. 25 (3), July 2009, pp. 143-154.
Clayton M., Johnson R. and Song Y. (1999). Operations documents; addressing the information need for facility managers. Durability of Building Materials and Components, Volume 8, pp. 2441-2451.
Eastman C., Teicholz P., Sacks R., Liston K. (2008). BIM handbook: a guide to building information modeling for owner, managers, designers, engineers, and contractors, New York: John Wiley& Sons
Eastman C., Teicholz P., Sacks R., Liston K. (2011). “BIM Handbook. AGuide to Building Information Modeling for Owners, Managers, Designers, Engineers, and Contractors,” 2nd ed., New Jersey: John Wiley & Sons, Inc.
Fiksel, J. (2006) Sustainability and resilience: toward a systems approach. Sustainability: Science, Practice, & Policy 2(2):14–21
Finnveden, G.; Hauschild, M. Z.; Ekvall, T.; Guinée, J. B.; Heijungs, R.; Hellweg, S.; Koehler, A.; Pennington, D.; Suh, S. (2009). Recent developments in life cycle assessment. J. Environ. Manage.
Garagnani, S. (2013) Building Information Modeling and real world knowledge – A methodological approach to accurate semantic documentation of the built environment. Digital Heritage 2013 Proceedings.
Guggemos, A., and Horvath, A. (2003) “Strategies of extended producer responsibility for buildings.” J. Infrastruct. Syst., 9(2), 65–74.
Guinée J. B. , Heijungs R. , Huppes G. , Zamagni A., Masoni P., Buonamci R., Ekvall T. and Rydberg T. (2011). Life Cycle Assessment: past, present, and future, Journal of Environmental Science and Technology, Vol. 45. No.1. pp: 90 – 96.
Hakkinen T., Kiviniemi A. (2008). Sustainable building and BIM, proceedings of world sustainable building conference (SB08), Melbourne. Australia
Heijungs, R.; Huppes, G.; Guinee, J. (2010). Life cycle assessment and sustainability analysis of products, materials and technologies: Toward a scientific framework for sustainability life cycle analysis. Polym. Degrad. Stabil, 95, 422-428.
Hendrickson, C., and Horvath, A. (2000) “Resource use and environmental emissions of U.S. construction sectors.” J. Constr. Eng. Manage.,126(1), 38–44.
Hungu C.F. (2013). Utilization of BIM from early design stage to facilitate efficient FM operations, available at: http://publications.lib.chalmers.se/records/fulltext/183268/183268.pdf, accessed time: 24 June 2014
ISO/TC 59/SC:13. Organization of information about construction works
Jrade A. and Jalaei F. (2013). Integrating building information modelling with sustainability to design building projects at the conceptual stage, Journal of Building Simulation, Springer, DOI10.1007/s12273-013- 0120-0.
Kam C. and Fischer M. (2004). Capitalizing on early project decision-Making opportunities to improve facility design, construction, and life-cycle performance-POP, PM4D, and decision dashboard approaches, Automation in Construction, Volume 13, pp. 53-65.
Keoleian, G., Blanchard, S., and Reppe, S. (2000) “Life-cycle energy, costs, and strategies for improving a single-family house.” J. Ind. Ecol., 4(2), 135–156.
Kibert, C. (2013) Sustainable Construction: Green Building Design and Delivery (3rd ed.), New Jersey: John Wiley and Sons, Inc.
Kubba S. (2012). Handbook of Green Building Design and Construction: LEED, BREEAM, and Green Globes. UK: Butterworth Heinemann.
McGraw-Hill, Construction. (2009). Understanding Perceptions and Usage Patterns of BIM Software Among Key Player Segments: Detail Findings –Non-Users of BIM.
Ochoa, L., Hendrickson, C., and Matthews, H. S. (2002) “Economic input-output life-cycle assessment of U.S. residential buildings.” J. Infrastruct. Syst., 8(4), 132–138.
Ortiz, O., Castellsa, F. and Sonnemann, G. (2009) Sustainability in the construction industry: A review of recent developments based on LCA, Construction and Building Materials, 23(1), pp. 28-39.
Sahely, H., Kennedy, C. and Adams, B. (2005) Developing sustainability criteria for urban infrastructure systems, Canadian Journal of Civil Engineering, 32(1), 72-85.
Smith, D. (2007). An Introduction to Building Information Modeling (BIM), Journal of Building Information Modeling, pp. 12–4.
Sophia Lisbeth Hsu (2009). Life Cycle Assessment of Materials and Construction in Commercial Structures: Variability and Limitations, pp. 13-14
Succar, B. (2013). The BIM Competencies of Industry Practitioners, Powerpoint presentation, Sócio-diretorda Change Agents, Australia, 24 de outro.
Tucker P. and Newton W. (2009). Carbon emissions from domestic built-in appliances, environment design guide, DES 74.
Waterhouse, R. (2011). Putting the ”I” into BIM, Building Information Modeling report, NBS, UK, March.
Get 3+ Free Dissertation Topics within 24 hours?