Campus-Wide Power Control

A pioneering microgrid project at Quinnipiac University

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A unique power control system for Quinnipiac University’s York Hill Campus, located in Hamden, CT, ties together a range of green energy power generation sources with utility and emergency power sources. The powerful supervisory control and data acquisition (SCADA) system gives campus facilities personnel complete information on every aspect of the complex system. Initially constructed when the term microgrid had barely entered our consciousness, the system continues to grow as the master plan’s vision of sustainability comes to fruition.

Hilltop Campus Focuses On Energy Efficiency and Sustainability
In 2006, Quinnipiac University began construction on its New York Hill campus, perched high on a hilltop with stunning views of Long Island Sound. The campus master plan incorporated innovative electrical and thermal distribution systems designed to make the new campus energy efficient, easy to maintain, and sustainable. Electrical distribution requirements, including primary electrical distribution, emergency power distribution, campus-wide load shedding, and cogeneration, were considered, along with the thermal energy components of heating, hot water, and chilled water.

The final design includes a central high-efficiency boiler plant, a high-efficiency chiller plant, and a campus-wide primary electric distribution system with automatic load shed and backup power. The design also incorporates a microturbine trigeneration system to provide electrical power while recovering waste heat to help heat and cool the campus. Solar and wind power sources are integrated into the design.

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Implementation Challenges for the Complex System
The ambitious project includes numerous energy components and systems. Startup and implementation was a complex process. The power structure system infrastructure, including the underground utilities, had been installed before all the energy system components had been fully developed. This made the development of an effective control system more challenging. Some of the challenges arose from utility integration with existing onsite equipment, in particular the utility entrance medium voltage (MV) equipment that had been installed with the first buildings. Because it was motor-operated, rather than breaker-operated, paralleling of generator sets with the utility (upon return of the utility source after power interruption) was not possible in one direction. They could parallel the natural gas generator to the utility, but the generator was also used for emergency power, so they could not parallel from the utility back to the microgrid.

Unique System Controls All Power Distribution Throughout the Campus
In response to the unique challenges, Russelectric designed, delivered, and provided startup for a unique power control system, and has continued to service the system since startup. The system controls all power distribution throughout the campus, including all source breakers—utility (15 kV and CHP), wind, solar, generators, MV loop bus substations, automatic transfer switches (ATSs), and load controls.

As might be expected, this complex system requires a very complex load control system.

Here is the complete power control system lineup:

  • 15-kV utility source that feeds a ring bus with eight medium voltage/low voltage (MV/LV) loop switching substations for each building. Russelectric controls the open and close of the utility main switch and monitors the utility main’s health and protection of the utility main.
  • 15-kV natural gas, 2-MW Caterpillar CAT generator with switchgear for continuous parallel to the 15-kV loop bus. Russelectric supplied the switchgear, providing full engine control and breaker operations to parallel with the utility as well as for emergency island operations.
  • One natural gas 750-kW Caterpillar generator used for emergency backup only.
  • One gas-fired FlexEnergy microturbine (Ingersoll Rand MT250 microturbine) for CHP distributed energy and utility tie to the LV substations.
  • Control and distribution switchgear that controls the emergency, CHP, and utility.
  • 12 ATSs for emergency power of four natural gas engines in each building.
  • 25 vertical-axis wind turbines that generate 32,000 kilowatt-hours of renewable electricity annually. The wind turbines are connected to each of the LV substations. Russelectric controls the breaker output of the wind turbines and instructs the wind turbines when to come on or go off.
  • 721 rooftop photovoltaic panels gathering power from the sun, saving another 235,000 kilowatt-hours (kWh) per year. These are connected to each of the three dormitory LV substations. Russelectric controls the solar arrays’ breaker output and instructs the solar arrays when to come on or go off.

The system officially only parallels the onsite green energy generation components (solar, wind, and microturbine) with the utility, although they have run the natural gas engines in parallel with the solar in island mode for limited periods.

Since the initial installation, the system has been expanded to include additional equipment, including another natural gas generator, additional load controls, and several more ATSs.

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SCADA Displays Complexity and Detail of All The Systems
Another feature of the Russelectric system for the project was the development of the Russelectric SCADA system. This SCADA system takes the complexity and detail of all of the systems and displays it for customer use. Other standard SCADA systems would not have been able to tie everything together—with one-line diagrams and front views of equipment, which provide the ability to visually see the entire system.

While the Russelectric products used are known for their quality and superior construction, what really made this project stand out is Russelectric’s ability to handle such an incredibly wide variety of equipment and sources without standardizing on the type of generator or power source used. Rather than requiring use of specific players in the market, the company supports any equipment the customer wishes to use—signing on to working through the challenges to make the microgrid work. This is critical to success when the task is controlling multiple traditional and renewable sources.

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