Energy Management 101: Controlling Costs Campus-wide with EEM

08/15/2005


It’s becoming more challenging for educational institutions to find the funds for facility upgrades and expansion, but in many cases, an untapped source of revenue exists in improved energy-management practices. Across North America, innovative colleges and universities are deploying energy management technology to help reduce electricity bills and avoid costly power-quality related interruptions.

By their very nature, large educational institutions have a lot to gain from managing their energy wisely. Characterized by a sprawling campus, multiple buildings, thousands of residents and a diverse range of power requirements, a typical university campus is like any progressive community—a large energy consumer. And with more than its share of high-tech labs, medical facilities and specialized computer equipment, this is one community that can benefit considerably by controlling the cost, quality and reliability of its power.

Fortunately, today’s technology offers many ways to do just that. Instead of waiting for the monthly electricity bill to determine power usage, facility managers can now use enterprise energy management (EEM) technology to manage campus-wide energy use, improve problem response and increase reliability.

An EEM system can help managers predict energy usage for the month, allocate costs by department and identify waste or potential trouble spots. A detailed understanding of the facility’s energy requirements over time can also help simulate alternative rate structures, negotiate better power-supply contracts and evaluate future options such as installing on-campus generation.

EEM System Components

A typical EEM system consists of a network of intelligent energy meters linked to a centrally located server running the enterprise energy management software. Each meter monitors a specific location or activity, while the head-end software continuously retrieves, aggregates, and processes the information.

The system logs the information in an historical database, responds to any alarm conditions by relaying notifications to operations personnel, and displays the real-time status of each monitored area on the screens of one or more networked workstations. In short, the software aggregates and analyses data from multiple sources and acts as the central intelligence for the entire system.

Figure 1: A typical EEM system includes web-enabled software and intelligent meters, connected over a communications network

The type and location of each meter is determined by the electrical system itself. For example, an advanced, utility-grade meter can be installed at the main substation to verify the quantity and quality of power delivered to the campus. Simpler sub-metering devices can then be installed at key points around the campus to monitor individual buildings or departments.


Typically, the distributed meters communicate with the head-end software across the campus’ existing Ethernet-based local area network; however, if the campus is geographically dispersed over great distances, then telephone, wireless and even the Internet can be used. In some cases, the meters can use e-mail to send system updates or alarm notifications directly to the facility manager, or even host a built-in web page accessible over any standard web browser.

Using an EEM system to better understand how a facility currently uses energy is the first step in controlling the cost, quality and reliability of its power.

Controlling Energy Costs

Although the cost of electricity is a considerable line item on most income statements, it often goes unchallenged and unmanaged. Like any large business, universities need to take active charge of their energy management and procurement; however, to do so requires a full understanding of ongoing energy needs, and the ability to manage its use.

Relatively few institutions have the ability to verify the billing statements from their energy suppliers, or to allocate the appropriate amounts to specific cost centers or activities within their operations. An EEM system delivers the information needed to accurately represent the true cost of doing business and helps to identify procedures or departments that exhibit energy inefficiencies or waste.

With a high-accuracy meter located at the utility service entrance, an EEM system can “shadow bill” campus energy consumption. Automated reports can then help to verify utility bills, and identify any over-billing errors.

Figure 2: Typical EEM intelligent energy metering and control devices

By allocating energy costs by department, and using automated reports and alarm options to keep staff aware, an EEM system can help everyone actively reduce energy consumption, increase efficiency, and minimize costs within their individual departments. For campus-based commercial outlets such as restaurants or shops, an EEM system can help to accurately sub-bill each tenant for the energy used.



With a network of meters reporting to one or more energy-management workstations, facility managers have the tools to identify and monitor energy requirements across the entire campus. This information can then be presented as a load profile —basically a snapshot of energy consumption at all monitored locations throughout a typical day, week or month.

A load profile can help to illustrate how energy is used throughout the facility, providing a valuable baseline that can help identify inefficiencies and evaluate improvement efforts. With an accurate understanding of energy consumption, facility managers can normalize usage patterns in conjunction with variables such as occupancy, temperature and weather to accurately benchmark and project energy requirements.

An EEM system also helps managers analyze historical energy trends to accurately predict needs. With this information, “what if” scenarios can be developed to help facility managers optimize loads or processes and even negotiate better energy contracts. Accurate information on usage trends can also help discover unused capacity, which in turn can defer capital investment decisions such as building additional onsite generation.

Depending on the campus location, there may also be an opportunity to take advantage of demand response or load curtailment programs offered by energy suppliers. These programs offer price concessions to the consumer, in return for the consumer agreeing to reduce its load anytime energy consumption across the power grid is at a critical peak. In this way, the consumer can also avoid incurring penalties from the utility for exceeding a maximum power demand level during peak times.

All of these opportunities are dynamic in nature. When energy prices are high, or demand is rising too quickly, an EEM system can start a generator or dynamically shed non-essential loads (such as heating or air-conditioning) to reduce the energy drawn from the utility.

And because utilities may also bill an additional surcharge for consuming energy inefficiently below a minimum power factor level (typically caused by large motor loads), an EEM system can intelligently control capacitor banks to correct low power factor and again avoid penalties.

Figure 3: Typical EEM web-enabled software, with custom energy and power quality reports

Maintaining Power Quality and Reliability

When it comes to power quality, the cost of harmonics, sags, transients and outages can quickly become very expensive, not to mention disruptive. Data may be lost, equipment damaged and procedures interrupted. Power quality is especially critical for the types of sensitive applications found in data centers, science labs and medical facilities. With sensitive equipment requiring “clean” power, these operations require near 100% uptime.

The power grid was designed to deliver “three nines” of clean, reliable power; that is, it provides a constant flow of energy 99.9% of the time. Although this is sufficient for lighting and motor loads, new digital assets and processes may require power reliability as high as “six nines” (99.9999%) or higher.

To achieve this, a university may have one or more feeds from the utility, or some form of stand-by generation with a transfer switch that selects between the utility and the generator feed. However, because generators typically cannot start up instantly when needed, other forms of mitigation equipment, such as UPS/battery systems and flywheels are used to “fill the gap.” These are connected by electrical distribution equipment such as transformers and circuit breakers. An EEM system can carefully monitor all this equipment to ensure it operates properly when needed.

When power quality problems are suspected, portable power-monitoring equipment can sometimes help to pinpoint problem areas. But for a large campus, an EEM system with its network of permanent-mount meters installed at key locations can verify power quality around the clock. This solution combines fast desktop access to status information for the entire electrical system, with the ability to receive early warning alarms anywhere by e-mail, pager or cell phone.

And like the “black box” used by the airline industry, the EEM system provides valuable forensic data after an event, to help personnel identify the source of a disturbance, and take corrective action to help prevent a reoccurrence. Detailed power quality reports can also help personnel correlate poor power quality with negative impacts on operations and processes.

In labs and research facilities across campus, a single interruption can easily result in the loss of months of costly work. To help offset this risk, onsite generators are becoming a popular addition, but the opportunities they provide can also raise many questions. As a source of standby power, generators can not only support improved reliability, but can cut costs by “peak shaving” peaks in demand, and can convert waste heat to electricity through co-generation. A clear understanding of generator processes is crucial to the efficient and economical operation of the facility. For this reason, an enterprise energy management system can provide a simple and efficient way to manage onsite generation assets, by profiling energy requirements and managing generators or loads based on power reliability or economic conditions.

Sound energy management

When considering ways to control costs on campus, sound energy management practices should be a priority. By monitoring consumption on an ongoing basis, managers can predict electricity costs for the month, avoid penalties, and verify each bill. Threats to reliability can be identified and corrected proactively, and poor power quality or disturbances can be dealt with promptly and efficiently.

A network of meters installed campus-wide can help to allocate costs by department or function, and verify the impact of any new energy initiatives. Automated reports can keep staff informed, so they can actively participate in programs to reduce energy consumption, increase efficiency, and minimize costs within their individual departments. In the long run, a detailed picture of overall energy requirements can help to identify opportunities for better supply contracts, alternative rate structures, or new construction such as on-campus generation.

The place to start is a clear understanding of energy usage across campus over a given period of time. From there, assessments can be made based on fact, corrective measures can be identified, and the relative success of improvements can be verified. By supporting a continuous cycle of research, optimization and verification, an investment in energy management strategies can open the door to a more efficient and cost-effective future.





No comments
Consulting-Specifying Engineer's Product of the Year (POY) contest is the premier award for new products in the HVAC, fire, electrical, and...
Consulting-Specifying Engineer magazine is dedicated to encouraging and recognizing the most talented young individuals...
The MEP Giants program lists the top mechanical, electrical, plumbing, and fire protection engineering firms in the United States.
Water use efficiency: Diminishing water quality, escalating costs; Lowering building energy use; Power for fire pumps
Building envelope and integration; Manufacturing industrial Q&A; NFPA 99; Testing fire systems
Labs and research facilities: Q&A with the experts; Water heating systems; Smart building integration; 40 Under 40 winners
Maintaining low data center PUE; Using eco mode in UPS systems; Commissioning electrical and power systems; Exploring dc power distribution alternatives
Protecting standby generators for mission critical facilities; Selecting energy-efficient transformers; Integrating power monitoring systems; Mitigating harmonics in electrical systems
Commissioning electrical systems in mission critical facilities; Anticipating the Smart Grid; Mitigating arc flash hazards in medium-voltage switchgear; Comparing generator sizing software
As brand protection manager for Eaton’s Electrical Sector, Tom Grace oversees counterfeit awareness...
Amara Rozgus is chief editor and content manager of Consulting-Specifier Engineer magazine.
IEEE power industry experts bring their combined experience in the electrical power industry...
Michael Heinsdorf, P.E., LEED AP, CDT is an Engineering Specification Writer at ARCOM MasterSpec.