One of our tasks was not to create a completed design, but more of a 80-90% complete design, complete with flaws and design issues that might occur during a project. So there are some conflicts, a few ducts that need to be sized, and some fairly complicated duct and pipe routing. We also include electrical system components that help demonstrate 120/208 and 277/480 voltage systems, and how to create a distribution system. Schedules include lighting, panel, and space/zone design schedules.
While primarily using out-of-the-box families, we also brought in examples of manufacturer content from Mitsubishi Electric.The HVAC system is designed as a variable refrigerant flow system. This system utilizes traditional supply and return ductwork systems, and room specific units that utilize makeup air from an energy recovery unit. The zoned systems also include demonstrating how a make-up supply air system can now be connected to a return air system. This is an improved feature in 2014 - in previous releases, the systems that are connected together all had to be the same type. You can now connect ductwork between these systems, but the sizing tools become disabled. We added a system connector family as an example, to demonstrate how you could maintain system separation and maintain the integrity of the system for sizing tools, and still connect the ductwork.
The architectural model includes a variety of finish materials, and allows the user to experiment with different design conditions easily. We also worked with Autodesk consultants on the design to create an asymmetrical design, including small variations in levels. The structure combines both concrete and steel components, to help Autodesk demonstrate the different design tools in Revit Structure.
All in all, it was a great learning experience for us as well. It helped drive home how important having a single, coordinate shared parameter file was on a project, which is something we put into place a few years ago. We included an example parameter text file based on the shared parameters exported from the Mitsubishi families to give us common voltage, number of poles, and other shared electrical connection parameters. This helps us avoid the issue of having duplicate name parameters in a project, which can make defining schedules a real pain.
One of the biggest improvements for us came with the graphics systems. I've been running Revit 2014 on a three year old Dell Inspiron 14R, with an i5 processor, 8gb of RAM and Intel HD onboard graphics. I didn't have to wait for views to regenerate themselves, even in more complex views such as a transparent 3D model. File opens and saves were also faster. For someone who hasn't had the money to upgrade their systems, this release doens't mean the end of the world - as long as you keep your models compact. I haven't tried it yet on some of our larger, more complex projects, but I expect similar improvements on performance.
Rendering is also greatly improved, whether you are working on your own workstation or in the cloud. A simple medium quality rendering using exterior only lights took about 5 minutes to produce the image above, even on my old workhorse.
So when you get a chance to watch one of the Autodesk demos, check out the model (and promise not to laugh too much - remember, I'm not an engineer, I just play one on TV). Hopefully it will give you an idea of just how far Autodesk has come with Revit for all areas of design - and that you get as much out of it as we do.
Think you can guess how much time it took to create the model? If you can, you win - well, nothing of real value other than a pat on the back...I'll post the actual time up later as a comment - you'll be surprised!
thanks - David B.