To enhance minimally invasive surgeries for patients, Penrose Hospital constructed a new interventional hybrid operating room on the second floor. This facility features advanced medical imaging devices that allow surgeons to visualize and access smaller areas of the body, making procedures less traumatic than traditional surgical methods. As the mechanical and electrical engineer on the project, RMH designed the HVAC, plumbing, normal and emergency power, and lighting systems to support the new operating room, control room, and various supporting devices, including new diagnostic equipment, medical equipment booms, and surgical systems integration equipment.
This project advances high-power electric vehicle (EV) charging by developing a megawatt-scale battery emulation framework at the Flatirons Campus. The system enables real-time testing of EV charging scenarios, focusing on integration with renewable energy and grid infrastructure.
At its core is a custom-designed MWh-scale lithium-ion battery emulator that replicates the dynamic behavior of various battery chemistries used in heavy-duty vehicles and stationary storage. Using Digital Real-Time Simulators, hardware-in-the-loop techniques, and grid simulators, the team built a robust platform for evaluating charge/discharge cycles and system-level interactions.
This infrastructure supports research in Vehicle Grid Integration, Behind-the-Meter assets, and Distributed Energy Resource applications, paving the way for more innovative and resilient EV-grid ecosystems.
The Lockheed Martin Space Systems Gateway Center at the Waterton Canyon campus marks a significant leap in satellite production capabilities. This $350 million, 266,000-square-foot facility focuses on designing, manufacturing, and testing satellites. Within its expansive layout, 175,000 square feet of SCIF support secure operations for national security missions.
The Gateway Center features a high bay Class 100k clean room, enabling the simultaneous construction and testing of large and small satellites. It also houses a large thermal vacuum chamber that replicates the harsh conditions of space, allowing for rigorous satellite testing prior to launch. Complementing these facilities is a sizable anechoic chamber for safely testing satellite antennas, sensors, and communication systems, as well as a large volume airlock that streams the departure of completed spacecraft in a controlled, clean environment.
The project includes redundant power systems, uninterruptible power supplies, generators, and a central utility plant, achieved through meticulously coordinating highly technical equipment.