Building Information Modeling in project management

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==History==
 
==History==
  
Although BIM appears as a totally new tool for management of construction projects, its concept exists for at least 30-40 years.<ref>http://codebim.com/resources/history-of-building-information-modelling/.</ref>  
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Although BIM appears as a totally new tool for management of construction projects, its concept exists for at least 30-40 years.<ref>http://codebim.com/resources/history-of-building-information-modelling/</ref>
  
In 1975, Eastmen introduce in his paper the idea of “''Building description systems (BDS)''” as a “''single integrated database for visual and quantitative analyses''” , where “''Contractors of large projects may find this representation advantageous for scheduling and materials ordering''” . Later, after the development of BDS concept, in 1986, Robert Aish described it as “Building Modelling”, in the sense that BIM is used today. As “Building Information modeling”, first documented in 1992 by G.A. van Nederveen and F. P. Tolman.
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In 1975, Eastmen <ref>Eastman, C. (1975): ‘The use of computers instead of drawings in building design‘, AIA Journal, March, Volume 63, Number 3, pp46-50 </ref> introduce in his paper the idea of “''Building description systems (BDS)''” as a “''single integrated database for visual and quantitative analyses''” , where “''Contractors of large projects may find this representation advantageous for scheduling and materials ordering''” . Later, after the development of BDS concept, in 1986, Robert Aish described it as “Building Modelling”, in the sense that BIM is used today. As “Building Information modeling”, first documented in 1992 by G.A. van Nederveen and F. P. Tolman.
 
However, the concept of “Building Information Modeling” became popular even later when in 2002 Autodesk adopted it as a strategy for “the application of information technology to the building industry”. From then, the amount of BIM users is increasing rapidly due to the benefits are provided.
 
However, the concept of “Building Information Modeling” became popular even later when in 2002 Autodesk adopted it as a strategy for “the application of information technology to the building industry”. From then, the amount of BIM users is increasing rapidly due to the benefits are provided.
  

Revision as of 17:17, 16 September 2016

Building Information Modeling is defined as “a digital representation of physical and functional characteristics of a facility. As such it serves as a shared knowledge resource for information about a facility forming a reliable basis for decisions during its lifecycle from inception onward” according to The National Building Information Model Standard Project Committee. The concept of BIM was developed at Georgia Institute of Technology in the late 1970s and has increased rapidly the last decades due to the significant benefits that provided in construction projects.

In this article, BIM is analyzed for the perspective of project management. Although BIM tool is more associated with the design team, the role of the project management is crucial and continuous in all the stages of the life-cycle of a project. For successful management, the procedures and tasks have to be planned in the early phase of the project. For this reason a BIM Project execution plan should be developed in advance. The components of this execution plan as well the tasks of an experienced project manager as the BIM-coordinator of the project are discussed. Moreover, the advantages and the limitations of the uses of BIM in construction projects are identified.

Contents

History

Although BIM appears as a totally new tool for management of construction projects, its concept exists for at least 30-40 years.[1]

In 1975, Eastmen [2] introduce in his paper the idea of “Building description systems (BDS)” as a “single integrated database for visual and quantitative analyses” , where “Contractors of large projects may find this representation advantageous for scheduling and materials ordering” . Later, after the development of BDS concept, in 1986, Robert Aish described it as “Building Modelling”, in the sense that BIM is used today. As “Building Information modeling”, first documented in 1992 by G.A. van Nederveen and F. P. Tolman. However, the concept of “Building Information Modeling” became popular even later when in 2002 Autodesk adopted it as a strategy for “the application of information technology to the building industry”. From then, the amount of BIM users is increasing rapidly due to the benefits are provided.

BIM aspects regarding Project Management

The main aspect of using BIM regarding Project Management are the following:

  • Integrated Project Delivery System

Integrated project delivery is an integrating approach for project management for delivering projects that integrate the collaboration between the different parties that involved on it. By this way, the efficiency through the phases could be increased as all the parties operate as a coherent team and concentrate on project general outcome and not on individual objectives. For improving the collaboration, BIM-tool enable the communication, visualization and analysis of complex project information between parties, which also improve the productivity and facilitation management. The benefits of an integrated project delivery on BIM based approach during the life cycle, contribute on a successful project execution.

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  • Unique language

The key of success in project management is the usage of the same language, meaning using the vocabulary in the same way that everyone in the project is using it. In a BIM project it is crucial for a project manager to be well-educated and have the skill to understand and be understood by all the parties involved in the project. Moreover, the ‘language’ between the parties is also important as BIM is based on the communication and the exchange of information between the teams of the project. For instance, the use of different softwares languages by different teams involved in the project is one of the main challenges in BIM, which can be solved by the use of a common neutral format language for exchanging information between the parties. For instance, the international organization, buildingSMART, formerly the International Alliance of Interoperability (IAI), has developed a neutral and open specification for BIM, called Industry Foundation Classes (IFCs), for improving the exchange of information between softwares used in the construction industry. Data interoperability is a main factor for obtaining BIM efficiency.

  • Technical Aspects

Some specific characteristic of BIM, that are increasingly developed, can be used in project management effectively. These characteristics are:

  • Clash Detection
    One of the main problem during the design construction project, is when the differences disciplines’ plans are overlapped and design inconsistencies are created. By using BIM techniques, the plans are gathered together and clashes are detected and solved. Not only construction clashes but also aesthetic problems can be avoided, due to the visualization that offered by BIM.
  • Constructability
    Using BIM, constructability issues can be reviewed and handled by the teams. Moreover, the visual information that is provided can facilitate the detection of constructability problems and mitigate the risk, allowing investigation for finding solutions.
  • Analysis
    BIM methods allow better analysis of all phases, enabling for project managers, designers and engineers to make decisions about the project. For instance, using BIM tools, it is possible to calculate the energy consumption of a construction project and find solutions by changing the materials and orientation, improve indoor air quality . Moreover, BIM enables light acoustic and mechanical analysis.
  • Time and Cost estimation (4D and 5D analysis)
    The visualization of a construction project achieved by 3D models result in a better understanding of the construction. But BIM also enables time and cost estimation which represented by 4D and 5D analysis, which can be utilized at the first stages of a project and facilitate the decision making process by minimum time and cost. Additionally, the implementation of alternatives scenarios could be utilized and near-instant analysis of the situation to be used by project manager in order to predict the consequences of their decisions.
  • Integration
    The collaboration of the parties that use BIM as well as the composition of a unified model, enable the coordination of analysis, design and construction activities resulting in integrity of projects.
  • Quantity take-off
    Quantity takeoffs in a BIM model contribute to better decision analysis by the project team regarding different alternative solution during the project life-cycle. Faster estimation are allowed due to the integration and 3D 4D and 5D analysis offered by BIM models. Takeoffs quantities can be also used in the procurement procedure.
  • Element based Model
    BIM models consist of elements/objects and not just geometrical shapes and lines. This enable the division of the project in smaller objects for better analysis, better management design, estimation and construction by having a defined and clear scope of the project.
  • Collaboration and team building
    Collaboration and Team building is another key of successful construction projects. Using the BIM concept, all parties are working on the same unified model and they don’t focus on individual outcomes but the whole project progress.
  • Communication
    Collaboration and the communication between the different parties involved in the construction project is increased due to the unified project model . The distribution of information between project managers, engineers, designers and contractors and the direct constant communication facilitate the reduction of risk.

Limitations/Challenges

  • Cost of software
    Currently, organizations utilize 2D and 3D softwares having the cost against purchasing, maintaining and upgrading software licenses. The cost of BIM software packages are more expensive than CAD software packages.Moreover, due to the increasing hardware requirements, BIM softwares dedicate high-specification workstation to be operated, in contrast with CAD softwares that can be operated in the majority of professional laptops.
  • Cost of Training
    When an organization is investing in BIM software, it is crucial to train its employees for using it and gain the benefits of the investment quickly. A specialized training is appropriate even if the staff have the knowledge of CAD methods and it is a requirement for all professional involved in BIM projects. Without the appropriate training the BIM may be proved more costly and time-consuming.
  • Transition from Drafting to Modeling
    The transition from CAD softwares to BIM softwares is not only about the increased drafting capabilities but a change in the workflow. Except from the design skills, the ability of understanding the whole project and the material used is a requirement for BIM users. Moreover the responsibilities of the staff are increased in order to ensure that all system components are coordinated with the other design professionals such as architectures and engineering services. Additionally, the cost associated with the training and maintaining of current designers in order to undertake their work into a design environment and up-skilling the drafting staff to a higher technical level is high.
  • Compatibility Between Software Platforms
    One of the biggest challenges of new BIM users is the inter-product compatibility due to the high amount of different software packages that existing in the market and used by different teams. However the interoperability issue it is not only about the different softwares but also about the different versions of programs within the same platform. This problem can be eliminate by using an agreed neutral-file format such as IFC (Industry Foundation Classes) which captures both geometry and properties of intelligent building objects.

BIM execution planning

For gaining the benefits of using BIM in a project, the parties should be aware of detailed-planning and scheduling of tasks and procedures.

PAS 1192-2013 proposes the implementation of a BIM execution plan, which will ensure that all parties have knowledge of the opportunities and responsibilities by using Building Information modelling. In the BIM execution plan should be included all the uses of BIM as well as detailed design and documentation of the processes for executing BIM through the project life-cycle. After the implementation of this plan, the parties take the advantage of following and monitoring their progress against the plan and gaining all the benefits of BIM usage.

The Guide

BIM Execution Planning Guide, a product of the BIM Project Execution Planning buildingSMART alliance™ (bSa) Project, includes the decision matrix and guidelines for creation and implementation of a BIM execution plan.

The main objectives of the BIM Project Execution Planning Guide are:

  • The identification of high value BIM uses during project planning, design, construction and operational phases
  • The creation of process maps for designing the BIM execution process
  • The definition of the BIM deliverables in the form of information exchanges
  • The development of the infrastructure in the form of contracts, communication procedures, technology and quality control to support implementation.
BIM execution plan.jpg

Goals

The main goals for developing this structured planning procedure are:

  • communication
  • collaboration
  • Saving time
  • sharing data
  • stringer execution

References


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