Lean construction – Principles and application
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==Background== | ==Background== | ||
− | Lean construction stems from lean production which was developed by Toyota production system during the 1950s. Engineer Ohno in Toyota was committed to minimize waste as a contrast to the craft and mass forms of production. Lean production was developed to save time, money, and materials. In 1992 a seminal report by Lauri Koskela started the adaption of the lean principles to the construction industry, he is recognized as the pioneer of the lean construction method. Still, one could say that the adaption is still ongoing today. | + | Lean construction stems from lean production which was developed by Toyota production system during the 1950s. Engineer Ohno in Toyota was committed to minimize waste as a contrast to the craft and mass forms of production. Lean production was developed to save time, money, and materials. In 1992 a seminal report by Lauri Koskela started the adaption of the lean principles to the construction industry, he is recognized as the pioneer of the lean construction method. Still, one could say that the adaption is still ongoing today. <ref name="AIC"/> Lean construction does accept the same goal as lean production, but it is specified for the construction market. The main difference is the forms of waste involved. Also, lean construction advocates the view of both product and process development at the same time. The main principles that separate the lean management in construction compared to traditional management is a clear set of objectives for the delivery process, that it is aimed to maximize the performance for the costumer, also at the project level. And lean applies production control throughout the life of the project, as a result of the simultaneous consideration of product and process development. <ref name="singapore"/> |
==Theory== | ==Theory== | ||
− | Lean production first developed by Koskela came as a product of an in-depth review of the production paradigms that dominated in the manufacturing industry. There were three competing paradigms: craft, mass, and lean production. By reviewing these paradigms, also including the value management perspective, Koskela came up with the theory which would be the framework of lean construction; the “Transformation-Flow-Value”-theory (TFV). This was a theory implementing the most effective qualities of all three production paradigms transformed into on theory through a perspective of construction. The implementation of the TFV concept into construction management allows for the transformation of raw materials into standing structures while at the same time maximizing the flow of materials and value to the costumer. That is the essence and goal of the TFV-theory. | + | Lean production first developed by Koskela came as a product of an in-depth review of the production paradigms that dominated in the manufacturing industry. There were three competing paradigms: craft, mass, and lean production. By reviewing these paradigms, also including the value management perspective, Koskela came up with the theory which would be the framework of lean construction; the “Transformation-Flow-Value”-theory (TFV). This was a theory implementing the most effective qualities of all three production paradigms transformed into on theory through a perspective of construction. The implementation of the TFV concept into construction management allows for the transformation of raw materials into standing structures while at the same time maximizing the flow of materials and value to the costumer. That is the essence and goal of the TFV-theory. <ref name="AIC"/> |
− | [[File:tfv_wiki.jpg|right|400px|thumb|Visual representation on how TFV is interconnected.]] | + | [[File:tfv_wiki.jpg|right|400px|thumb|Visual representation on how TFV is interconnected.<ref name="tfv"/>]] |
− | In lean construction there is defined 8 forms of waste: transport, inventory, motion, waiting, overprocessing, overproduction, defects, and human potential. Minimizing or even better eliminating these wastes is a key aspect of lean construction. By doing so nothing that adds value to a project will be considered and the result is cut of cost and more efficiency. | + | In lean construction there is defined 8 forms of waste: transport, inventory, motion, waiting, overprocessing, overproduction, defects, and human potential. Minimizing or even better eliminating these wastes is a key aspect of lean construction. By doing so nothing that adds value to a project will be considered and the result is cut of cost and more efficiency. <ref name="AIC"/> |
===The 8 wastes=== | ===The 8 wastes=== | ||
− | #'''Transport:''' Transport is a waste in the sense of | + | #'''Transport:''' Transport is a waste in the sense of expenses and that it does not directly bring value to a project by itself. Therefore should transport be held to a minimum. Transportation is also a contributor to global warming which could be considered as bringing less value to a project.<br /> |
− | #'''Inventory:''' Excess inventory is a waste when it is not processed. This also transfers to all resources surrounding the excess inventory. This | + | #'''Inventory:''' Excess inventory is a waste when it is not processed. This also transfers to all resources surrounding the excess inventory. This would be elements such as storage, capital, transportation etc.<br /> |
− | #'''Motion''': Every motion a worker must do to finish a task that is not necessary. This could be everything from having to re-stack items, going to get something | + | #'''Motion''': Every motion a worker must do to finish a task that is not necessary. This could be everything from having to re-stack items, going to get something and even unnecessary walking.<br /> |
− | #'''Waiting:''' Any reason for a worker to be using time by waiting is a waste. This could be due to waiting for the next step of the process, a tool, an item, etc. All time | + | #'''Waiting:''' Any reason for a worker to be using time by waiting is a waste. This could be due to waiting for the next step of the process, a tool, an item, etc. All time a worker is not working is time that should be used for the advancement of the project.<br /> |
− | #'''Overprocessing:''' Overprocessing is when there is taken unnecessary steps to reaching a goal. It could also be ineffective processing; this could be in the form of using bad tools or | + | #'''Overprocessing:''' Overprocessing is when there is taken unnecessary steps to reaching a goal. It could also be ineffective processing; this could be in the form of using bad tools or making products of a higher quality than what is needed.<br /> |
− | #'''Overproduction:''' Producing more items than needed is an obvious waste. Items take up storage and accounts for unnecessary transportation | + | #'''Overproduction:''' Producing more items than needed is an obvious waste. Items take up storage and accounts for unnecessary transportation. Overproduction is also a waste of the cost of the production which could be used somewhere the money is used for creating value to the project.<br /> |
#'''Defects:''' The production of defect items is a waste because it forces the production of a repair item, which again is unnecessary use of time and money.<br /> | #'''Defects:''' The production of defect items is a waste because it forces the production of a repair item, which again is unnecessary use of time and money.<br /> | ||
#'''Human potential:''' By not listening to all employees and working groups a project could be losing time, ideas, skills, improvements and learning opportunities. | #'''Human potential:''' By not listening to all employees and working groups a project could be losing time, ideas, skills, improvements and learning opportunities. | ||
+ | ====Variability reduction==== | ||
− | + | Related to the principle of waste-removal is variability reduction. The reduction of variability grants for the increase of predictability and reduces cycle times. This makes it easier to do project planning and makes room for less expectancies. Koskela stated that the reduction of variability also increases customer satisfaction and decrease the volume of non-value-adding activities. Examples of variability in the context of construction could be late deliveries, defect tools, wrong design of materials, etc. A stunt in the workflow is therefore affected by variability. The methods that can be used to reduce variability are plan buffers, and flexible capacity. These methods are developed to reduce variability without removing it completely. Today the most used method is plan buffers, which is the concept of always having a backlog of work for all working groups involved. Flexible capacity however is the concept of using resources in more than one way, this can be done by having working groups trained to work with the same resources. | |
+ | ===Transformation=== | ||
+ | From a transformation standpoint, production is defined as the transformation of raw materials and parts into finished goods through the use of technology, energy, and labor. In the context of transformation, waste refers to the use of more of these production resources than are required. We can identify the following sorts of waste from a transformation perspective: material waste, unnecessary material use, unnecessary use of resources such as machines, energy, or workers. In the transformation perspective, none of the wastes are exclusive to the construction industry, this view is for example the same for Ohno's lean production. <ref name="bøl"/> | ||
===Flow=== | ===Flow=== | ||
− | The flow view in TFV stems from the paradigms mass and lean production. The viewing of production as a flow of materials and information led to the principle of waste. The principle of minimizing waste should result in a better workflow and optimization of time spent. Through the flow perspective waste is defined as the use of more time than what is necessary. | + | The flow view in TFV stems from the paradigms mass and lean production. The viewing of production as a flow of materials and information led to the principle of waste. The principle of minimizing waste should result in a better workflow and optimization of time spent. Through the flow perspective waste is defined as the use of more time than what is necessary. There are two different forms of flow. One is the the process flow. This flow describes how effective the product flows through the production process. The second flow is the workflow. This is the flow in which the work is carried out by the workers. There can be waste both in the process flow and in the workflow. In the perspective of flow the wastes identified is: Unnecessary movement, unnecessary work, inefficient work, waiting, space not being worked in, materials not being processed and unnecessary transportation. These wastes, both from the flow and transformation-perspective can be categorized into the classic eight types of wastes. <ref name="bøl"/> |
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===Value=== | ===Value=== | ||
− | Value is a special component of | + | Value is a special component of Koskela's TFV-theory. This part of the theory is all about creation and generation of value. The reason why is special is because this is where the TFV-theory stands out the most compared to other production theories. It makes TFV broader and more robust and is the reason why a production theory can be the framework of a management method in the construction industry. This value component is not included in lean production which is not necessarily costumer-value driven, as lean construction is. Value is a term that could be difficult to define, it is also a term that have the possibility of changing with time. According to the Lean Construction Institute is value generated when costumer capabilities are expanded, creating new needs and purposes, and the facility better fulfills the purposes of customers and producers and demands of other stakeholders. The goal of lean construction is to minimize the difference between a client’s desired value and the value that is realized. This is done by the consideration of the product and the process value management at the same time, this approach is called value-based management. Product value is split into market value and utility value. Process value on the other hand is a unit for the ethical value of the provider. Value generation is arguably the area of lean construction that is most open for research and improvement. <ref name="kos"/> |
− | [[File:Substain_pic.jpg|right|350px|thumb|Aspects of lean construction that makes the | + | [[File:Substain_pic.jpg|right|350px|thumb|Aspects of lean construction that makes the management technique sustainable.<ref name="sub"/>]] |
− | === | + | ===Sustainability=== |
− | Sustainability has | + | Sustainability has naturally been tied to the lean way of management. Some aspects of lean construction being a more environment-friendly management strategy is more straight forward, such as eliminating waste in form of material and energy minimalization. But also, that lean construction is a more safety-oriented management technique should be considered. Taking care of the health and safety of everyone involved in a project is beneficial for everyone. Resources through potential hospital visits, replacement of workers and broken equipment is saved. In fact, according to Thomassen (2003) <ref name="mik"/> , crews using lean construction had a 45 percent lower accident rate than crews using traditional construction methods were, this considering that the crews worked for the same company. The advantages of lean construction in terms of sustainability is improved health and safety, waste reduction, and environmental improvement. The advantages are not restricted to the ones listed above. The application of lean yields social and economic benefits as well. Waste reduction, for example, frequently leads to higher productivity and value creation. Improved health and safety will result in a more pleasant working environment, which will benefit society. <ref name="uk"/> |
==Application== | ==Application== | ||
− | A common misunderstanding of lean construction is that is a way to implement lean production to construction projects. This is not the case and projects that do this will not succeed. This because the already used processes are founded on weak principles and practices. | + | A common misunderstanding of lean construction is that it is a way to implement lean production to construction projects. This is not the case and projects that do this will not succeed. This because the already used processes are founded on weak principles and practices. Applicating lean construction the right way is to use tools and developed processes for the purpose of implementing the lean constructions principles to the project. Lean construction can be implemented in small construction projects as well as in large-scale construction projects. For doing this there are some critical elements that has to be considered, according to Howell (1999) these are<ref name="AIC"/>: |
*Clear set of objectives to be established for the delivery process. Customer needs and requirements are well understood. | *Clear set of objectives to be established for the delivery process. Customer needs and requirements are well understood. | ||
Line 74: | Line 74: | ||
*Work structuring of the entire process increases value and reduces waste at the project delivery level. Efforts to improve performance at the planning level increases performance at project level. | *Work structuring of the entire process increases value and reduces waste at the project delivery level. Efforts to improve performance at the planning level increases performance at project level. | ||
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− | There are a variety of systems and tools available for | + | There are a variety of systems and tools available for lean construction projects. These lean delivery solutions are comparable in structure and aims to achieve the TFV aims through improving planning, minimizing waste, and including downstream stakeholders earlier in the project. Examples of such systems are the ''Last Planner System'' and ''Lean Development Project System'' but also tools such as visualization, daily huddle meetings, first run studies and 5S is possible to implement. (Further reading) Usually a mixture of these tools are used in construction projects running on lean construction. In this article the first and most used system, the ''Last Planner System'' will be presented as a general example of how lean construction is applicated. <ref name="Salem"/> |
− | + | ===Last planner system=== | |
− | + | In 1992, the Last Planner production control system was established, emphasizing the link between scheduling and production management. This system was the first system suitable for lean construction purposes. | |
+ | The Last Planner main role is replacing optimistic planning with realistic planning by measuring worker performance based on their ability to consistently meet their obligations. Last Planner's objectives are to remove unnecessary activities by reverse phase scheduling and team planning. The goal is to optimize resources in the long term, as the goal of lean construction. The system have different procedures that uses a pull strategy to create an efficient schedule planning framework that shapes the workflow. It also aligns workflow and capacity, provides work execution methods, and promotes trade communication. <ref name="AIC"/> | ||
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− | The steps of | + | [[File:LPS_pic.jpg|center|500px|thumb|Workflow-map for the processes of the Last Planner System.<ref name="lps"/>]] |
+ | |||
+ | The steps of used and preformed in the ''Last Planner System'' are as follows: | ||
#'''Master schedule:''' The master schedule is a timeline for the entire project, complete with milestones. This master schedule is used to create reverse phase scheduling. | #'''Master schedule:''' The master schedule is a timeline for the entire project, complete with milestones. This master schedule is used to create reverse phase scheduling. | ||
#'''Reverse phase schedules:''' The reverse Phase Schedule is developed by using a pull technique to make a schedule that works backwards from the completion date. The goal of the phase schedule is to establish a plan for the integration and coordination of numerous specialists' operations, and it serves as a link between work structure and production management. | #'''Reverse phase schedules:''' The reverse Phase Schedule is developed by using a pull technique to make a schedule that works backwards from the completion date. The goal of the phase schedule is to establish a plan for the integration and coordination of numerous specialists' operations, and it serves as a link between work structure and production management. | ||
− | #'''Six-week lookahead:''' This is a tool for having control over the workflow. The essence of the six-week lookahead is to show what work that is going to be completed in the weeks to come. The durations of the lookahead and schedule is calculated from the reverse phase schedule. The | + | #'''Six-week lookahead:''' This is a tool for having control over the workflow. The essence of the six-week lookahead is to show what work that is going to be completed in the weeks to come. The durations of the lookahead and schedule is calculated from the reverse phase schedule. The lookahead window does not need to be 6 weeks, it could be anywhere from 3-12 weeks. In short, the six-week lookahead planning is the process of reducing uncertainty in order to achieve constraint-free assignments. A constraint analysis is done in the six-week lookahead meetings, this is done before a task is started. Constraints for the specific task is identified for the purpose of eliminating them before the actual work on the task is started. |
#'''Weekly work plan:''' The weekly schedule, safety issues, quality issues, material needs, manpower, building methods, backlog of ready work, and any difficulties that may arise in the field are all discussed at the weekly work plan meeting. It encourages two-way communication and team planning in order to exchange project information efficiently and accurately. It can help with safety, quality, job flow, material flow, productivity, and team member relationships. | #'''Weekly work plan:''' The weekly schedule, safety issues, quality issues, material needs, manpower, building methods, backlog of ready work, and any difficulties that may arise in the field are all discussed at the weekly work plan meeting. It encourages two-way communication and team planning in order to exchange project information efficiently and accurately. It can help with safety, quality, job flow, material flow, productivity, and team member relationships. | ||
#'''Percent plan complete (PPC):''' Is the relationship between completed tasks and all the task. It's computed by dividing the total number of scheduled activities by the number of activities that are executed as planned. When the slope between two PPC values is positive, it indicates that production planning was accurate. PPC levels are highly variable, ranging from 30% to 70% in the absence of lean implementation. Additional lean building tools, such as first run studies, must be employed to obtain higher values. | #'''Percent plan complete (PPC):''' Is the relationship between completed tasks and all the task. It's computed by dividing the total number of scheduled activities by the number of activities that are executed as planned. When the slope between two PPC values is positive, it indicates that production planning was accurate. PPC levels are highly variable, ranging from 30% to 70% in the absence of lean implementation. Additional lean building tools, such as first run studies, must be employed to obtain higher values. | ||
− | #''' | + | #'''Variance analysis:''' This analysis is done after period of work is finished. Variance in this sense is the work that was not completed is reference to the weekly work plan. It is discussed in the variance analysis the reasoning for why these task were not preformed, and how to prevent these flaws from happening again. <ref name="Salem"/> |
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+ | ===Barriers of implementing lean construction=== | ||
+ | |||
+ | There are some barriers related to lean construction. They can be generalized into seven categories: managerial, technical, human attitude, the process of lean construction, educational, government and financial barriers. | ||
+ | |||
+ | One of the main barriers is managerial barriers when implementing lean construction. Lean construction is dependent on carefully executed logistics which must go through the top management of the company. Also, the communication between the stakeholders and the different groups in the company must be present and effective. Without these criteria’s a project will suffer from disruption and ineffectiveness. | ||
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+ | When it comes to the technical barriers is the architectural designs buildability and the certainty of the production process the biggest obstacles. When a design is not buildable the plans need to be revised, which requires a lot of time and money. Therefore, it is recommended that all stakeholders should be involved form the beginning to make sure that the project is buildable and that the process is feasible. | ||
+ | |||
+ | Human attitude is one, if not the biggest barrier of lean construction, mainly in the physical implementation stage. What is meant by attitude in this setting is the tendency regarding intent, commitment and co-operation that needs to be presented within the stakeholders if lean construction management is going to run successfully. If this drive of wanting the project to be successful by lean principles is not there, the project will not succeed. | ||
+ | |||
+ | The process of implementing lean construction is regarded as a barrier in itself. This is because some projects tend to take a long time implementing the management system. There are examples of sites that have needed many meetings and discussions in the initial stage of their project. When these meetings also are poorly managed time flies by. This was found to be a problem in the pre-construction phase. But if a project managed to implement lean construction successfully, no matter of when, the project did generate profit and helped the company’s reputation. | ||
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+ | Education is regarded as a barrier when the stakeholders involved in a project does not have enough knowledge about the execution of lean construction. The training to be able to understand the principles of the lean way of thinking as well as how to implement it in construction is of course vital. The responsibility of having this training is the top managements. | ||
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+ | The last main barrier of lean construction is government and financial barriers. This due to inflation, additional construction cost and poor salaries. Also, the lack of incentives or reward systems and sufficient sources of funding is a barrier for lean construction in particular and construction in general. There are some solutions to these kinds of problems, provision of contingency cost is preventing construction projects from inflation or additional cost due to instability of the construction market. <ref name="singapore"/> | ||
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+ | ==Annotated bibliography== | ||
+ | |||
+ | *Tariq Abdelhamid, 2008, '''LEAN CONSTRUCTION: FUNDAMENTALS AND PRINCIPLES''': This article explains the major principles of lean construction and also how to implement the management technique. | ||
+ | |||
+ | *Trond Bølviken, 2018, '''THE WASTES OF PRODUCTION IN CONSTRUCTION – A TFV BASED TAXONOMY''': This article elaborates the 7 wastes of Ohno and how they relate to Koskela's TFV-theory. | ||
− | + | *Mohd Arif Marhani, 2013, '''Sustainability Through Lean Construction Approach: A Literature Review''': This study goes through the fundamental concepts of lean construction and also its barriers, it is then discussed what makes the management technique sustainable. | |
− | == | + | ==References== |
− | + | <references> | |
− | + | ||
− | + | <ref name="AIC"> Abdelhamid, T.S., 2008. Lean Construction: Fundamentals and principles [online] Available at: <https://www.researchgate.net/publication/289380759_Lean_construction_Fundamentals_and_principles> [Accessed 4 March 2022]. </ref> | |
− | + | <ref name="Salem"> Salem, O., 2005. Site Implementation and Assessment of Lean | |
+ | Construction Techniques [online] Available at: <https://leanconstruction.org.uk/wp-content/uploads/2018/09/Salem-e-al.-2005-Site-implementation-and-assessment-of-lean-construction-techniques.pdf> [Accessed 10 March 2022]. </ref> | ||
− | + | <ref name="bøl"> Bølviken, T., 2018. THE WASTES OF PRODUCTION IN | |
+ | CONSTRUCTION – A TFV BASED TAXONOMY [online] Available at: <https://leanconstruction.org.uk/wp-content/uploads/2018/09/Bolviken-et-al.-The-waste-of-production-in-construction-a-TFV-based-taxonomy.pdf> [Accessed 8 March 2022]. </ref> | ||
− | + | <ref name="singapore"> Mohd, A.M., 2013. Sustainability through Lean Construction Approach: A | |
+ | literature review [online] Available at: <https://www.sciencedirect.com/science/article/pii/S1877042813020776> [Accessed 15 March 2022]. </ref> | ||
− | + | <ref name="kos"> Koskela, L.J., 2013. The foundations of lean construction [online] Available at <https://www.researchgate.net/publication/28578914_The_foundations_of_lean_construction> [Accessed 8 March 2022]. </ref> | |
− | + | <ref name="mik"> Thommasen, M., 2003. EXPERIENCE AND RESULTS FROM IMPLEMENTING LEAN CONSTRUCTION IN A LARGE DANISH CONTRACTING FIRM | |
+ | [online] Available at: <https://www.researchgate.net/publication/265110860_Experience_and_results_form_implementing_lean_construction_in_a_large_danish_contracting_firm> [Accessed 11 March 2022]. </ref> | ||
− | == | + | <ref name="uk"> Ogunbiyi, O., 2014. An empirical study of the impact of lean construction techniques on sustainable construction in the UK |
+ | [online] Available at: <https://www.emerald.com/insight/content/doi/10.1108/CI-08-2012-0045/full/pdf?casa_token=2Hty8KvKgoAAAAAA:Cz63pY_oLlQNTA4kWes8XK55Vlwt9wR9wR22lvtFVggRnTgZfuN8ZspnHstwx0nn5mrIIYXBouDHN_mcu0eldhDctJ58feo6zQAbPJkH4o-WBBdH8Dcmgw> [Accessed 11 March 2022]. </ref> | ||
− | + | <ref name="tfv"> Figure illustrating how the TFV-theory is interconnected, | |
− | + | [online] Available at: <https://www.arcom.ac.uk/-docs/proceedings/ar2005-0331-0340_Sard%E9%96%9A_and_Stehn.pdf>. </ref> | |
− | + | ||
− | = | + | <ref name="sub"> Figure illustrating the components making lean construction sustainable, |
+ | [online] Available at: <https://www.semanticscholar.org/paper/Area-of-linkage-between-lean-construction-and-in-Dixit-Mandal/bb7f20675bd2cd18a71878a486c10481bb049cd6>. </ref> | ||
− | + | <ref name="lps"> Figure illustrating the workflow of the Last Planner System, | |
− | + | [online] Available at: <https://leanconstruction.org.uk/wp-content/uploads/2018/09/Salem-e-al.-2005-Site-implementation-and-assessment-of-lean-construction-techniques.pdf>. </ref> | |
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Latest revision as of 23:49, 22 March 2022
Developed by Niklas Kjenstadbakk Brede
Lean project management's goal is to maximize value and minimize waste, preferably eliminate waste. The goal is to achieve as much value to the costumer as possible with as little waste as possible. The lean technique is especially suitable for complex projects and has therefore proven to be effective for construction project since it was first used in the industry in the mid-1990s.
It is designed to reduce the time, effort and materials required for the project; this is done by reducing waste. Lean construction has 8 different forms of waste: transport, inventory, motion, waiting, overprocessing, overproduction, defects, and human potential. By minimizing these forms of waste, the benefits of lean production will become apparent. Optimally the timeframe of the project will be shortened because of more effective and flexible work. Total cost and increased profit should also be achieved. The lean method is also great for environmental benefits since the method is formed to minimize excess materials.
To implement lean construction the principles of lean must be considered. These are the basics of lean thinking and are considered in all industries where lean can be utilized. There are 5 principles: defining value, mapping the value stream, creating a flow, establishing a pull, and to pursue perfection.
In lean construction all the parties of a project are considered, from the constructors to the owner. This is to ensure that the right tools and method is being used for all the parts of the project. To optimize productivity and save work hours everybody involved in the project is put at specific task of their specification. This causes companies to stick to project that they are especially suited for and gives them a comparative advantage. The lean construction method will then, if preformed correctly, allow projects to avoid mistakes rather than having to fix mistakes.
Contents |
[edit] Background
Lean construction stems from lean production which was developed by Toyota production system during the 1950s. Engineer Ohno in Toyota was committed to minimize waste as a contrast to the craft and mass forms of production. Lean production was developed to save time, money, and materials. In 1992 a seminal report by Lauri Koskela started the adaption of the lean principles to the construction industry, he is recognized as the pioneer of the lean construction method. Still, one could say that the adaption is still ongoing today. [1] Lean construction does accept the same goal as lean production, but it is specified for the construction market. The main difference is the forms of waste involved. Also, lean construction advocates the view of both product and process development at the same time. The main principles that separate the lean management in construction compared to traditional management is a clear set of objectives for the delivery process, that it is aimed to maximize the performance for the costumer, also at the project level. And lean applies production control throughout the life of the project, as a result of the simultaneous consideration of product and process development. [2]
[edit] Theory
Lean production first developed by Koskela came as a product of an in-depth review of the production paradigms that dominated in the manufacturing industry. There were three competing paradigms: craft, mass, and lean production. By reviewing these paradigms, also including the value management perspective, Koskela came up with the theory which would be the framework of lean construction; the “Transformation-Flow-Value”-theory (TFV). This was a theory implementing the most effective qualities of all three production paradigms transformed into on theory through a perspective of construction. The implementation of the TFV concept into construction management allows for the transformation of raw materials into standing structures while at the same time maximizing the flow of materials and value to the costumer. That is the essence and goal of the TFV-theory. [1]
In lean construction there is defined 8 forms of waste: transport, inventory, motion, waiting, overprocessing, overproduction, defects, and human potential. Minimizing or even better eliminating these wastes is a key aspect of lean construction. By doing so nothing that adds value to a project will be considered and the result is cut of cost and more efficiency. [1]
[edit] The 8 wastes
- Transport: Transport is a waste in the sense of expenses and that it does not directly bring value to a project by itself. Therefore should transport be held to a minimum. Transportation is also a contributor to global warming which could be considered as bringing less value to a project.
- Inventory: Excess inventory is a waste when it is not processed. This also transfers to all resources surrounding the excess inventory. This would be elements such as storage, capital, transportation etc.
- Motion: Every motion a worker must do to finish a task that is not necessary. This could be everything from having to re-stack items, going to get something and even unnecessary walking.
- Waiting: Any reason for a worker to be using time by waiting is a waste. This could be due to waiting for the next step of the process, a tool, an item, etc. All time a worker is not working is time that should be used for the advancement of the project.
- Overprocessing: Overprocessing is when there is taken unnecessary steps to reaching a goal. It could also be ineffective processing; this could be in the form of using bad tools or making products of a higher quality than what is needed.
- Overproduction: Producing more items than needed is an obvious waste. Items take up storage and accounts for unnecessary transportation. Overproduction is also a waste of the cost of the production which could be used somewhere the money is used for creating value to the project.
- Defects: The production of defect items is a waste because it forces the production of a repair item, which again is unnecessary use of time and money.
- Human potential: By not listening to all employees and working groups a project could be losing time, ideas, skills, improvements and learning opportunities.
[edit] Variability reduction
Related to the principle of waste-removal is variability reduction. The reduction of variability grants for the increase of predictability and reduces cycle times. This makes it easier to do project planning and makes room for less expectancies. Koskela stated that the reduction of variability also increases customer satisfaction and decrease the volume of non-value-adding activities. Examples of variability in the context of construction could be late deliveries, defect tools, wrong design of materials, etc. A stunt in the workflow is therefore affected by variability. The methods that can be used to reduce variability are plan buffers, and flexible capacity. These methods are developed to reduce variability without removing it completely. Today the most used method is plan buffers, which is the concept of always having a backlog of work for all working groups involved. Flexible capacity however is the concept of using resources in more than one way, this can be done by having working groups trained to work with the same resources.
[edit] Transformation
From a transformation standpoint, production is defined as the transformation of raw materials and parts into finished goods through the use of technology, energy, and labor. In the context of transformation, waste refers to the use of more of these production resources than are required. We can identify the following sorts of waste from a transformation perspective: material waste, unnecessary material use, unnecessary use of resources such as machines, energy, or workers. In the transformation perspective, none of the wastes are exclusive to the construction industry, this view is for example the same for Ohno's lean production. [4]
[edit] Flow
The flow view in TFV stems from the paradigms mass and lean production. The viewing of production as a flow of materials and information led to the principle of waste. The principle of minimizing waste should result in a better workflow and optimization of time spent. Through the flow perspective waste is defined as the use of more time than what is necessary. There are two different forms of flow. One is the the process flow. This flow describes how effective the product flows through the production process. The second flow is the workflow. This is the flow in which the work is carried out by the workers. There can be waste both in the process flow and in the workflow. In the perspective of flow the wastes identified is: Unnecessary movement, unnecessary work, inefficient work, waiting, space not being worked in, materials not being processed and unnecessary transportation. These wastes, both from the flow and transformation-perspective can be categorized into the classic eight types of wastes. [4]
[edit] Value
Value is a special component of Koskela's TFV-theory. This part of the theory is all about creation and generation of value. The reason why is special is because this is where the TFV-theory stands out the most compared to other production theories. It makes TFV broader and more robust and is the reason why a production theory can be the framework of a management method in the construction industry. This value component is not included in lean production which is not necessarily costumer-value driven, as lean construction is. Value is a term that could be difficult to define, it is also a term that have the possibility of changing with time. According to the Lean Construction Institute is value generated when costumer capabilities are expanded, creating new needs and purposes, and the facility better fulfills the purposes of customers and producers and demands of other stakeholders. The goal of lean construction is to minimize the difference between a client’s desired value and the value that is realized. This is done by the consideration of the product and the process value management at the same time, this approach is called value-based management. Product value is split into market value and utility value. Process value on the other hand is a unit for the ethical value of the provider. Value generation is arguably the area of lean construction that is most open for research and improvement. [5]
[edit] Sustainability
Sustainability has naturally been tied to the lean way of management. Some aspects of lean construction being a more environment-friendly management strategy is more straight forward, such as eliminating waste in form of material and energy minimalization. But also, that lean construction is a more safety-oriented management technique should be considered. Taking care of the health and safety of everyone involved in a project is beneficial for everyone. Resources through potential hospital visits, replacement of workers and broken equipment is saved. In fact, according to Thomassen (2003) [7] , crews using lean construction had a 45 percent lower accident rate than crews using traditional construction methods were, this considering that the crews worked for the same company. The advantages of lean construction in terms of sustainability is improved health and safety, waste reduction, and environmental improvement. The advantages are not restricted to the ones listed above. The application of lean yields social and economic benefits as well. Waste reduction, for example, frequently leads to higher productivity and value creation. Improved health and safety will result in a more pleasant working environment, which will benefit society. [8]
[edit] Application
A common misunderstanding of lean construction is that it is a way to implement lean production to construction projects. This is not the case and projects that do this will not succeed. This because the already used processes are founded on weak principles and practices. Applicating lean construction the right way is to use tools and developed processes for the purpose of implementing the lean constructions principles to the project. Lean construction can be implemented in small construction projects as well as in large-scale construction projects. For doing this there are some critical elements that has to be considered, according to Howell (1999) these are[1]:
- Clear set of objectives to be established for the delivery process. Customer needs and requirements are well understood.
- Process concurrently, to give more value to the customer needs - this process of parallel design helps positive iteration within the process and negative iteration is reduced.
- Shifting design work along the supply chain to reduce the variation and match the work content.
- Work structuring of the entire process increases value and reduces waste at the project delivery level. Efforts to improve performance at the planning level increases performance at project level.
There are a variety of systems and tools available for lean construction projects. These lean delivery solutions are comparable in structure and aims to achieve the TFV aims through improving planning, minimizing waste, and including downstream stakeholders earlier in the project. Examples of such systems are the Last Planner System and Lean Development Project System but also tools such as visualization, daily huddle meetings, first run studies and 5S is possible to implement. (Further reading) Usually a mixture of these tools are used in construction projects running on lean construction. In this article the first and most used system, the Last Planner System will be presented as a general example of how lean construction is applicated. [9]
[edit] Last planner system
In 1992, the Last Planner production control system was established, emphasizing the link between scheduling and production management. This system was the first system suitable for lean construction purposes.
The Last Planner main role is replacing optimistic planning with realistic planning by measuring worker performance based on their ability to consistently meet their obligations. Last Planner's objectives are to remove unnecessary activities by reverse phase scheduling and team planning. The goal is to optimize resources in the long term, as the goal of lean construction. The system have different procedures that uses a pull strategy to create an efficient schedule planning framework that shapes the workflow. It also aligns workflow and capacity, provides work execution methods, and promotes trade communication. [1]
The steps of used and preformed in the Last Planner System are as follows:
- Master schedule: The master schedule is a timeline for the entire project, complete with milestones. This master schedule is used to create reverse phase scheduling.
- Reverse phase schedules: The reverse Phase Schedule is developed by using a pull technique to make a schedule that works backwards from the completion date. The goal of the phase schedule is to establish a plan for the integration and coordination of numerous specialists' operations, and it serves as a link between work structure and production management.
- Six-week lookahead: This is a tool for having control over the workflow. The essence of the six-week lookahead is to show what work that is going to be completed in the weeks to come. The durations of the lookahead and schedule is calculated from the reverse phase schedule. The lookahead window does not need to be 6 weeks, it could be anywhere from 3-12 weeks. In short, the six-week lookahead planning is the process of reducing uncertainty in order to achieve constraint-free assignments. A constraint analysis is done in the six-week lookahead meetings, this is done before a task is started. Constraints for the specific task is identified for the purpose of eliminating them before the actual work on the task is started.
- Weekly work plan: The weekly schedule, safety issues, quality issues, material needs, manpower, building methods, backlog of ready work, and any difficulties that may arise in the field are all discussed at the weekly work plan meeting. It encourages two-way communication and team planning in order to exchange project information efficiently and accurately. It can help with safety, quality, job flow, material flow, productivity, and team member relationships.
- Percent plan complete (PPC): Is the relationship between completed tasks and all the task. It's computed by dividing the total number of scheduled activities by the number of activities that are executed as planned. When the slope between two PPC values is positive, it indicates that production planning was accurate. PPC levels are highly variable, ranging from 30% to 70% in the absence of lean implementation. Additional lean building tools, such as first run studies, must be employed to obtain higher values.
- Variance analysis: This analysis is done after period of work is finished. Variance in this sense is the work that was not completed is reference to the weekly work plan. It is discussed in the variance analysis the reasoning for why these task were not preformed, and how to prevent these flaws from happening again. [9]
[edit] Barriers of implementing lean construction
There are some barriers related to lean construction. They can be generalized into seven categories: managerial, technical, human attitude, the process of lean construction, educational, government and financial barriers.
One of the main barriers is managerial barriers when implementing lean construction. Lean construction is dependent on carefully executed logistics which must go through the top management of the company. Also, the communication between the stakeholders and the different groups in the company must be present and effective. Without these criteria’s a project will suffer from disruption and ineffectiveness.
When it comes to the technical barriers is the architectural designs buildability and the certainty of the production process the biggest obstacles. When a design is not buildable the plans need to be revised, which requires a lot of time and money. Therefore, it is recommended that all stakeholders should be involved form the beginning to make sure that the project is buildable and that the process is feasible.
Human attitude is one, if not the biggest barrier of lean construction, mainly in the physical implementation stage. What is meant by attitude in this setting is the tendency regarding intent, commitment and co-operation that needs to be presented within the stakeholders if lean construction management is going to run successfully. If this drive of wanting the project to be successful by lean principles is not there, the project will not succeed.
The process of implementing lean construction is regarded as a barrier in itself. This is because some projects tend to take a long time implementing the management system. There are examples of sites that have needed many meetings and discussions in the initial stage of their project. When these meetings also are poorly managed time flies by. This was found to be a problem in the pre-construction phase. But if a project managed to implement lean construction successfully, no matter of when, the project did generate profit and helped the company’s reputation.
Education is regarded as a barrier when the stakeholders involved in a project does not have enough knowledge about the execution of lean construction. The training to be able to understand the principles of the lean way of thinking as well as how to implement it in construction is of course vital. The responsibility of having this training is the top managements.
The last main barrier of lean construction is government and financial barriers. This due to inflation, additional construction cost and poor salaries. Also, the lack of incentives or reward systems and sufficient sources of funding is a barrier for lean construction in particular and construction in general. There are some solutions to these kinds of problems, provision of contingency cost is preventing construction projects from inflation or additional cost due to instability of the construction market. [2]
[edit] Annotated bibliography
- Tariq Abdelhamid, 2008, LEAN CONSTRUCTION: FUNDAMENTALS AND PRINCIPLES: This article explains the major principles of lean construction and also how to implement the management technique.
- Trond Bølviken, 2018, THE WASTES OF PRODUCTION IN CONSTRUCTION – A TFV BASED TAXONOMY: This article elaborates the 7 wastes of Ohno and how they relate to Koskela's TFV-theory.
- Mohd Arif Marhani, 2013, Sustainability Through Lean Construction Approach: A Literature Review: This study goes through the fundamental concepts of lean construction and also its barriers, it is then discussed what makes the management technique sustainable.
[edit] References
- ↑ 1.0 1.1 1.2 1.3 1.4 Abdelhamid, T.S., 2008. Lean Construction: Fundamentals and principles [online] Available at: <https://www.researchgate.net/publication/289380759_Lean_construction_Fundamentals_and_principles> [Accessed 4 March 2022].
- ↑ 2.0 2.1 Mohd, A.M., 2013. Sustainability through Lean Construction Approach: A literature review [online] Available at: <https://www.sciencedirect.com/science/article/pii/S1877042813020776> [Accessed 15 March 2022].
- ↑ Figure illustrating how the TFV-theory is interconnected, [online] Available at: <https://www.arcom.ac.uk/-docs/proceedings/ar2005-0331-0340_Sard%E9%96%9A_and_Stehn.pdf>.
- ↑ 4.0 4.1 Bølviken, T., 2018. THE WASTES OF PRODUCTION IN CONSTRUCTION – A TFV BASED TAXONOMY [online] Available at: <https://leanconstruction.org.uk/wp-content/uploads/2018/09/Bolviken-et-al.-The-waste-of-production-in-construction-a-TFV-based-taxonomy.pdf> [Accessed 8 March 2022].
- ↑ Koskela, L.J., 2013. The foundations of lean construction [online] Available at <https://www.researchgate.net/publication/28578914_The_foundations_of_lean_construction> [Accessed 8 March 2022].
- ↑ Figure illustrating the components making lean construction sustainable, [online] Available at: <https://www.semanticscholar.org/paper/Area-of-linkage-between-lean-construction-and-in-Dixit-Mandal/bb7f20675bd2cd18a71878a486c10481bb049cd6>.
- ↑ Thommasen, M., 2003. EXPERIENCE AND RESULTS FROM IMPLEMENTING LEAN CONSTRUCTION IN A LARGE DANISH CONTRACTING FIRM [online] Available at: <https://www.researchgate.net/publication/265110860_Experience_and_results_form_implementing_lean_construction_in_a_large_danish_contracting_firm> [Accessed 11 March 2022].
- ↑ Ogunbiyi, O., 2014. An empirical study of the impact of lean construction techniques on sustainable construction in the UK [online] Available at: <https://www.emerald.com/insight/content/doi/10.1108/CI-08-2012-0045/full/pdf?casa_token=2Hty8KvKgoAAAAAA:Cz63pY_oLlQNTA4kWes8XK55Vlwt9wR9wR22lvtFVggRnTgZfuN8ZspnHstwx0nn5mrIIYXBouDHN_mcu0eldhDctJ58feo6zQAbPJkH4o-WBBdH8Dcmgw> [Accessed 11 March 2022].
- ↑ 9.0 9.1 Salem, O., 2005. Site Implementation and Assessment of Lean Construction Techniques [online] Available at: <https://leanconstruction.org.uk/wp-content/uploads/2018/09/Salem-e-al.-2005-Site-implementation-and-assessment-of-lean-construction-techniques.pdf> [Accessed 10 March 2022].
- ↑ Figure illustrating the workflow of the Last Planner System, [online] Available at: <https://leanconstruction.org.uk/wp-content/uploads/2018/09/Salem-e-al.-2005-Site-implementation-and-assessment-of-lean-construction-techniques.pdf>.