The Real BIM: What You Need To Know About Clash Detection

Introdution

In the dynamic world of construction and engineering, Building Information Modeling (BIM) has emerged as a revolutionary technology that promises to transform the way we design and construct buildings and infrastructure. One of the key functionalities of BIM that has gained significant attention is “clash detection.” This article explores what clash detection is, its importance in construction projects, how it works, and best practices for achieving seamless clash detection results.

What is Clash Detection?

Clash detection is a critical process within the BIM framework that involves identifying and resolving conflicts or clashes between different building elements in a 3D model. These conflicts can be anything from structural components intersecting with plumbing systems to electrical conduits obstructing HVAC ducts. Clash detection helps prevent costly and time-consuming errors during construction by identifying and rectifying issues before they become on-site challenges.

Figure shows the clashes between disciplines

The Significance of Clash Detection

The clash detection as a main step in the BIM work flow has a great impact on the project positively if it was done correctly and negative if it wasn’t. The Significance of the clash detection is but not limited to:

1. Error Prevention

Clash detection is like a virtual safety net for construction projects that it allows engineers, architects, and construction professionals to identify potential issues in the design phase, thereby reducing the likelihood of costly errors during construction.

2. Time and Cost Savings

By catching clashes early in the project, construction teams can avo id rework and costly delays. This leads to significant cost savings and ensures the completion of the projects are on time or even ahead of schedule.

3. Enhanced Collaboration

Clash detection fosters better collaboration among project stakeholders, as it encourages interdisciplinary teams to work together to resolve issues. This results in a smoother construction process.

How Clash Detection Takes Place?

Clash detection in BIM involves several key steps and technologies. Understanding the process is essential for effectively implementing it into construction projects.

1. Building the 3D Model

The foundation of clash detection is a comprehensive 3D model of the entire project. This model includes all architectural, structural, mechanical, electrical, and plumbing components, each in their respective layers.

2. Clash Detection Software

Specialized clash detection software, such as Autodesk Navisworks or Solibri Model Checker, is used to analyze the 3D model for clashes. These tools enable users to define clash detection rules and criteria.

3. Running Clash Tests

The software runs clash tests based on predefined rules stated in the BEP (BIM Execution Plan). The clash test codes or names are being set as per a clash test matrix which specify the two elements which each test is conducted for. It scans the 3D model for any instances where building elements intersect or clash with each other. Detected clashes are typically highlighted in the model.

4. Clash Reports

Clash detection software generates detailed clash reports, listing the clashes, their locations, and the disciplines involved. These reports are essential for collaboration and issue resolution.

5. Resolution and Collaboration

Once clashes are identified, interdisciplinary teams collaborate to find solutions. This may involve repositioning elements, resizing ducts, or modifying structural components. The 3D model is updated accordingly.

6. Continuous Monitoring

Clash detection is not a one-time process; the BIM team should be performe it regularly throughout the project’s lifecycle to account for design changes and evolving requirements.

Best Practices for Effective Clash Detection

To harness the full potential of clash detection, construction professionals should adhere to best practices. Here are some key guidelines:

1. Early and Continuous Clash Detection

Start clash detection as early as possible in the project and continue throughout all phases. Early detection and resolution prevent issues from cascading downstream.

2. Clear Communication

Effective communication is paramount. Ensure that all team members understand the clash detection process, the used software, and their responsibilities in resolving clashes.

3. Define Clash Detection Criteria

Clearly define clash detection criteria and rules based on project-specific requirements. This includes setting tolerances and priorities for resolving clashes.

4. Regularly Update the 3D Model

As the design evolves, the BIM team updates the 3D model to reflect changes. This ensures that clash detection remains accurate and relevant.

5. Collaborative Workflows

Encourage collaboration among disciplines and stakeholders to resolve clashes efficiently. Use clash reports as a basis for discussions and decisions.

6. Document and Track Resolutions

Maintain records of resolved clashes and their solutions. This documentation is invaluable for future reference and quality assurance.

Conclusion

Clash detection is a cornerstone of efficient and error-free construction within the BIM framework. By identifying and resolving conflicts in the digital realm, construction projects can avoid costly delays and rework. Implementing clash detection best practices and using specialized software can significantly enhance the overall quality and efficiency of construction projects. Embracing clash detection is not just an option; it’s a necessity for modern construction professionals to achieve delivering excellence in their projects.

The AEC industry: The Important information to know

What AEC stands for?

The AEC industry is one of the most modern terms that appeared in the last decades in the field of the construction industry and all related fields. AEC stands for “Architectural, Engineering and Construction.”

The AEC industry

Architecture: Architects provide the conceptual and final designs.

Engineering: Engineers supervise the construction and maintenance of the project.

Construction: Construction project personnel and their skilled labourers take the responsibility of executing the project on time and within budget as per quality standards.

What is the AEC industry?

The expression describes the collaboration of architects, engineers, and construction professionals on various construction projects to achieve successful completion. The three disciplines are integrated together from design to execution.

How large is the AEC industry?

“AEC global market is growing and is reaching $10.5 trillion by 2023 as experts expect. Experts also expect it to grow at a compound annual growth rate of 4.2% between now and 2026. Additionally, the global AEC industry has experienced 40% annual revenue growth for 16 years straight. Historically, jobs in the industry have grown at 3.2% but were projected to grow by 5% in 2022 and then exponentially over the next few years.” www.oriontalent.com

What are the new methods within the AEC industry?

There are many trends shaping the AEC industry, including:

Green Processes: This is a major trend that sees AEC professionals transforming their processes to be more cost-effective and energy-efficient, as well as having a lower carbon footprint.

Data Management: Building off of an interest in green processes, the collection of data on a building and its users helps the AEC team improve building performance, save energy, and optimize the space.

Remote Work enabled by AI: The recent shift to remote work has made it less painful for a traditionally on-site industry with the utilization of Building Information Modeling (BIM) with AI, which allows teams to collaborate in real-time within one 3d model.

Prefabricated Buildings: Modular buildings streamline the construction process by saving time and month. They also reduce activity on construction sites in accordance with social distancing trends.

Automation and Robotics: Remote operation of robots that can perform manual tasks and self-driving trucks, as well as materials handling equipment are making worksites safer.

Conclusion

AEC stands for “Architectural, Engineering and Construction.”

AEC global market is growing and is reaching $10.5 trillion by 2023 as experts expect.

Green Processes, Data Management, Remote Work enabled by AI, Prefabricated Buildings, Automation and Robotics are the most trendings in the AEC industry.

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The Real BIM: The history you need to know.

Briefly, What is BIM?

To know the History of BIM, we must first know what is BIM.

“Building Information Modeling (BIM) is the holistic process of creating and managing information for a built asset. Based on an intelligent model and enabled by a cloud platform, BIM integrates structured, multi-disciplinary data to produce a digital representation of an asset across its lifecycle, from planning and design to construction and operations.” Autodesk.com

Is BIM really a new system?

We knew BIM as a concept in the early 70s until the early 2000s when the world started using it widely as an application of a system started to be used widely. BIM tools as we know them as computerized method of work was a result of long exerted efforts started by the hand-drawn drawings to have the engineering information in a holdable form.

How BIM evolved from random practices to an integrated system?

The Drawings

The engineers used the cyanotype printing process to produce copies of
drawings.

In 1842, Sir John Frederick Herschel invented blueprint.

The blueprint was the first kind of modern drawing.

Sir John Frederick William Herschel (1792-1871)

BY 1890, thanks to Alphonse Louis Poitevin, a civil engineer, and a photographer, blueprint reached 10% of its cost with less time after discovering the light-sensitivity properties of bichromated gelatin.

Alphonse-Louis Poitevin (1819-1892)

After using diazo printing (blue-line process), the world started printing on white paper.

The Computer Era

The drawings lasted as the only way to share information in engineering until the computer era in 1961 when Dr. Patrick J. Hanratty (the cad father) developed DAC (Design Automated By Computer) in general motors laboratories, Which Was The First CAD System.

Unlike expected and although DAC system was useful, GM discarded this system when it upgraded its hardware.

Dr. Hanratty had this quote: “Never Generate Anything Closely Coupled To A Specific Architecture And Make Sure You Keep Things Open To Communicate With Other Systems Even Your Competitors”.

In 1971, Dr. Hanratty developed “Adam” for running on any computer. “Adam” became the model for many cad/cam programmers.

Dr. Patrick J. Hanratty aka (the Cad father) (1931-2019)

1963, Ivan Sutherland developed “Sketchpad” software. It became the first (Computer Aided Design) With A Graphical User Interface.

SketchPad represented a big leap in the computer graphics developement that it changed the Human-Computer interaction.

SketchPad allowed the ability to display and record shape information.

Ivan Sutherland (1938)

The concept of BIM and evolution of its applications

In 1975, Charles M. Eastman (The BIM Father) developed The BDS (Building Description system).

Charles M. Eastman (The BIM Father) (1940-2020)

BDS Was One Of The First Developments To Successfully Utilize A Building Database.

BDS didn’t have the expected popularity then, and few companies used it.

In 1977, Eastman created GLID (Graphical Language For Interactive Design). GLID Was One Of The First Programs To Incorporate Most Of The Major Features Present In Today’s BIM Software.

In 1979, Autodesk released Autocad under the name Interact CAD.

1982, the first version of Autocad and in the same year Gabor Bajor started graphisoft archicad..

1986, AutoCAD became the most used cad software worldwide.

1993, Cas Berlin developed NURBS (Non-Uniform Rational Basis Spline) which was able to show simple and complex spline 3D surfaces by control points and In the same year, The Lawrence Berkeley National Lab developed BDA (Building Design Advisor) which provided the new analysis and visualization tools.

1997, Charles River Software the company which issued “Pro/ENGINEER” For Mechanical Design With The Intent Of Bringing The Power Of Parametric Modeling To The Building Industry.

1998, McNeel Created (Rhinoceros) Which is a Commercial 3D Computer Graphics Software.

2000, Leonid Raiz and Irwin Jungreis the founders of Charles River Software renamed it to Revit Technology Corporation then Autodesk purchased it 2002 for 133.00 Million USD, Since then Autodesk became a significant Key player in BIM technology platforms.

And the BIM applications continued the upgrade journey to fulfill the AEC industry needs till moment.

The BIM Authoroties.

1994, Autodesk and another 11 companies (AT&TArchibusCarrier CorporationHellmuth, Obata & Kassabaum (HOK); HoneywellJaros, Baum & Bolles (JB&B)Lawrence Berkeley LaboratoryPrimavera Systems; SoftdeskTimberline Software Corp; and Tishman) established IAI (international Alliance For Interoperability).

1996, IAI (Industry Alliance For Interoperability) issued the first version of IFC (Industry Foundation Classes) files to support open bim.

2005, IAI name became Building Smart which became the issuer of IFC standards.

Building Smart has many chapters in many regions: Europe, Australia, Asia, and the Middle East.

Conclusion

BIM is the natural result of long prompt efforts and innovation of people and each one of those reached the farthest extent of his potential.

As we knew from the post, BIM is not new. The story started in the early 1840s and continued to these days.

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