What is Building Information Modeling? Check our infographic to know more:
What is BIM?
Building Information Modeling (BIM) can be a valuable tool in the hands of anyone who works in construction. There鈥檚 no doubt that the concept of collaborative working is becoming more and more popular over the years.
That鈥檚 why it鈥檚 critical for all construction agents to be aware of the different BIM maturity levels. Before we go further with that, it would really be useful to try to define what BIM actually means.
What does BIM stand for in construction
As we saw above, BIM stands for Building Information Modeling. To put it simply, BIM refers to a collaborative method of working which is based on the generation and exchange of data and information between the various project parties. Based on this information the full cycle of a building, from conception to completion, can be managed.
In that sense, it鈥檚 an indispensable part of the decision-making process. BIM started gaining attention in the 鈥90s and it has evolved remarkably during the last decades.
Read more: What are BIM objects?
There are different levels of shared collaboration in a construction project. Those are known as BIM maturity levels. As we proceed through the levels, the collaboration between the various sides is increasing. At the time being, there are four distinct BIM maturity levels.
BIM level 0 (low collaboration)
It鈥檚 the simplest step of the information generating process. It doesn鈥檛 practically involve any level of cooperation. In this phase, the production and sharing of the information are taking place with the help of paper and non-interoperable electronic documents.
CAD drawings are used during Level 0, but there is no sharing of the generated information models. and is heading to a more collaborative way of producing and distributing the necessary information.
BIM level 1 (partial collaboration)
A large number of companies are at the moment conducting their work on this level. A is used in this case. A Common Data Environment or CDE is an online shared repository where all the necessary project data are collected and managed.
The contractor is normally the one who manages a CDE. In a few words, BIM Level 1 is focusing on the transition from CAD to 2D and 3D pieces of information. Despite the presence of a Common Data Environment, the generated models are not distributed among the different agents.
BIM level 2 (full collaboration)
The main focus of interest on this level is the way in which the information is shared across the various project members. Two new dimensions, related to project management, are introduced at this level. It鈥檚 the 4D which is related to time management and the 5D which is linked to the calculation of the budget.
The specification is also of imperative importance, as it designates the necessary conditions for a construction project to reach in BIM Level 2.
Collaborative working is at the core of BIM Level 2. Nevertheless, it doesn鈥檛 require every side involved in the project to operate on the same . To the contrary, everyone is free to use a distinct CAD model. What is really important is the existence of a (an IFC file for instance) that contains all the design information.
In other words, we are talking about a model of full collaboration among the numerous project sides. In that way, the parties connected to the project can have an overview of all the available information and modify it accordingly. Thanks to this, they are able to put together a unified BIM model. Last but truly important detail the CAD software, that every party uses, should have the ability to export in common file types (eg. files, files etc.).
Countries like the UK are towards that direction. The UK government mandate for adopting the BIM Level 2 model by 2016 in every public project makes clear that there鈥檚 a strong focus on optimizing the construction process.
BIM level 3 (full integration)
BIM Level 3 is the ultimate goal for the construction industry. Its main point is the attainment of full integration (iBIM) of the information in a cloud-based environment. This will be achieved by the use of a common shared model. The model will be accessible to anyone that has something to do with the project.
On top of that, the various agents that work in the project will be able to edit it and/or add their own piece of information. A new dimension 聽(6D) which is focusing on the management of the building鈥檚 life cycle is expected to be added at this point. Dimensions related to time (4D) and cost (5D) are also available.
At the moment, there are still certain doubts around copyright and responsibility issues. But those are expected to be solved, as the whole process is progressing.
BIM dimensions
A common misconception around BIM has to do with its dimensions. The dimensions are different than BIM maturity levels. BIM dimensions are inextricably connected to the type of data that can become available through the process. They can be found both in BIM Level 2 and Level 3.
In a nutshell, there are four types of BIM dimensions:
- 3D: It refers to 3D generated drawings.
- 4D: It is linked to time management.
- 5D: It concerns data that have to do with the cost of the project.
- 6D: It鈥檚 a dimension dedicated to the life cycle management of a building.
The importance of model checking
is a fundamental element in computer science and by extension in BIM. Model checking could be described as the detailed process of examining a particular system model on whether or not is meeting certain criteria. It鈥檚 understandable that model checking has tremendous importance for BIM.
There are various BIM viewer tools that could help a lot during this effort. Solibri and Navisworks are two reliable pieces of software聽that can offer a lot toward that direction. In a sentence, they could be used for design coordinating and compliance checking purposes. Similarly, a tool like Revit can be part of this procedure.
BIM adoption is the main driver of change
By now it is clear that Building Information Modeling is a reliable vehicle for submitting and sharing data during a construction project. Data is a core value for Building Information Modeling given that a BIM model is only as precious as the quality and precision of the information submitted to it.
In that sense, user adoption is of paramount importance. That鈥檚 often overlooked in the industry despite the decisive impact that it might have on construction鈥檚 future. BIM should be brought in the hands of field workers in the form of intuitive – yet easy to use – digital solutions.People on the ground need to be able to report progress and update tasks with the click of a button on tools which behind the scenes are linked seamlessly to the BIM model. In that way, workers can focus on their tasks without any unnecessary interruptions.
Simply put, BIM bridges the digital gap between the construction site and the office while preventing people both on the field and the boardroom to work in an isolated way. By linking compliance and quality processes to the BIM model, it becomes easier to improve the projects鈥 as-built documentation and define onsite quality processes across teams.
That being said, Building Information Modeling is a key factor in supporting and improving the flow of data from the project. But here is where a common but very crucial problem emerges.
The lack of a standardised onsite follow up protocol leads companies to have different classifications from one project to another. This generates a lot of confusion between the project agents and results in wasting both time and resources.
Establishing a standardised group of internal classifications, which can also be connected to a company鈥檚 ERP system can eventually boost productivity and improve the way you manage the building process from start to finish.
Like that, all project teams can streamline their tasks and processes in a collaborative digital environment while contributing to the BIM model and by extension to the collection of valuable project data. In the long run, such an approach could play a vital role in bringing trust back in the supply chain and pave the way for fact-based decisions.
Nevertheless, everything goes back to the importance of easy-to-use digital tools which can be effortlessly implemented on site. Digital adoption is an area where many stakeholders in construction make a serious mistake as they tend to fall for the 鈥渟hiny鈥 3D aspects of BIM instead of focusing on data first.
After all, from team to team there are different needs in terms of data and BIM adoption. A 2D representation of a project can work just fine for people on the ground whose first priority is to update the office on the latest progress around their tasks.
At the same time, a 3D representation of the built structure might be more beneficial for a BIM manager whose primary focus is to keep a bird鈥檚 eye view of the entire project.
It鈥檚 evident, then, that there are different levels of transparency depending on an individual鈥檚 role in the project. In any case, though, a common language on how a company maps its classifications to the on-site specifications is necessary.
What the future brings
The transition to BIM Level 2 and hopefully soon enough to Level 3 will have some important benefits for the construction industry. In short, we could sum up some of them below:
Boost in productivity
The ability to share information faster and easier can offer a significant productivity boost. Collaborative working can decrease the required time for incorporating and editing new information. Increased productivity means also lower cost and by extension higher efficiency in terms of project planning.
Big Data
Building Information Modeling will offer remarkable help in handling vast amounts of data. The more effective managing of big data will change the way many of the professionals within construction (eg. contractors, engineers, etc.) are working. It鈥檚 expected that a higher demand for data will emerge, as well.
New possibilities for smaller markets
BIM can play a great role in the optimization of the construction process. This element may very soon lead to the opening and development of new markets which until now did not have the right tools in order to expand. Thanks to a fully or partially integrated collaborative model, 聽they will be able to tackle a big number of difficulties that they face on a daily basis at the moment.
Buildings of better quality
The larger amount of data in conjunction with the ability to manage them with higher precision will eventually lead to a remarkable improvement of the quality of our buildings. To put it simply, more complex buildings that have much more to offer to their residents will be designed and built.
Parameters such as the environment and the modernisation of the designed structures will be easier to be taken into consideration during the building procedure.
Improved clash detection
Thanks to BIM, the clash detection process is drastically ameliorated. The term clash is referring to potential mistakes that emerge during the design and construction of a building. Building Information Modeling can help a lot in clash detection and as a result in increasing the project鈥檚 efficiency. IFC files offer great assistance during this process.
Conclusion
It鈥檚 clear, then, that BIM represents the opening of the construction industry to . There鈥檚 no doubt that it鈥檚 a long and demanding way. But important steps have been made during the last decades and the future of construction looks brighter day by day.