BIM Automation: Where Efficiency and Optimization Converge

HENDERSON HEADLINES BIM AUTOMATION: WHERE EFFICIENCY AND OPTIMIZATION CONVERGE Authored by: Adam Roth | July 8, 2021 Implementing dynamic methods to innovate with design is standard practice at Henderson Engineers. One of the tools we rely on to help us determine the best system design for a space is Building Information Modeling (BIM). BIM is a process that uses data to generate digital representations of a facility’s physical and functional characteristics, including the building systems we engineer. This digital representation of the facility, often with 3D modeled systems, serves as a shared knowledge resource for anyone needing to make informed decisions during a facility’s lifecycle – from design, to construction, to operations, and beyond. Efficiency and optimization are key components of innovation, and as Director of BIM/VDC, I focus on how we can use BIM to its maximum potential. Because using BIM is a key approach for Henderson designers and many of our clients, automating the process adds incredible value to a project. Simply put, BIM automation uses pre-calculated design conditions to automate the placement of system components with different variables. While a simple idea, automating these design conditions and variables is a foundation of many of Henderson’s design initiatives. This process allows us to quickly react to project changes and focus more thoroughly on the engineering itself, while still producing quality models. The efficiency we achieve through BIM automation directly translates to time and cost savings for our clients without impacting the quality of our work. Below are three recent examples of how we utilized BIM automation to create efficient, optimized designs. MAINTENANCE ACCESS One way we implement BIM automation at Henderson is by using already modeled data to help guide our designs and collaborate with other disciplines and project partners. For example, we use a Dynamo script to identify equipment above Acoustic Ceiling Tile (ACT) ceilings based on data from linked architectural models, and then store that information in the individual ceiling elements for reference during design. Having this data allows us to automate the placement of an access tile family for ceiling height, grid placement, and grid rotation. This access tile reserves space for equipment maintenance (not typically shown on ceiling plans) and is a crucial design component that can be easily overlooked. While the initial layout may be automated, a designer always confirms final placement to ensure it makes sense for the designed equipment. We also use Revit to make sure there are no elements placed in the ceiling tile, and then run a QC script to verify the final design layout is still within range of the equipment and complies with equipment access requirements.