Multifamily Takes Baby Steps to CHP
And despite their customers efforts to conserve energy, suppliers are still seeing an increased need for power capacity. Electric utilities can choose to invest in creating greater power generation capacity--at a cost and timeline that may prove unrealistic--or to create incentives to encourage the installation of privately owned on-site generation. But it takes a tremendous effort to convince customers to create their own electricity, and to coordinate on-site generation with the existing electric grid.
Combined heat and power (CHP) is the production of electricity and the recovery of thermal energy from a single source, typically a natural gas-driven engine or turbine installed on-site. Benefits could be significant, not only from an energy standpoint--the overall efficiency of CHP (60% and more) is about double the overall efficiency of centralized power plants, which face heat losses at the plant and transmission losses in delivering power from the plant to the customer--but also from an environmental standpoint; the use of CHP could reduce emissions from fossil fuel-burning equipment. CHP sounds like the ideal answer to high energy costs, reliability problems, and the need for increased power production capacity.
Furthermore, CHP is not a new, untested idea; it is widely used in commercial and industrial applications. There have also been several successful attempts, by HUD in particular, to spur the use of CHP in the multifamily market by publicizing case studies. Unfortunately, incentives for the use of CHP to date have targeted large industrial and commercial projects.
Currently, funding entities are starting to investigate the use of CHP in multifamily buildings that offer suitable electric and thermal load patterns for CHP applications (see CHP in the States). These buildings operate 24 hours a day, seven days a week, and do so with predictable load patterns. Although CHP applications in multifamily buildings would be on a smaller scale than CHP applications for large industrial users (30 kW for multifamily compared to 500 kW for multimegawatt industrial applications), the potential exists for many new installations. While investment prices per kW tend to be higher for the installation of these smaller units, prices may decline as companies develop microcogeneration at 1kW of capacity, using a Sterling engine or fuel cell. An efficient technology combined with market volume would then drive prices down. In the meantime, CHP program implementers like the New York State Energy Research and Development Authority (NYSERDA) offer incentives to building owners who want to invest in the technology.
The real challenge at this time is to raise the awareness of, and provide education to, the multifamily buildings sector, explaining the benefits, but also the limitations, of CHP applications. The use of this technology, even with manufacturers efforts to simplify installation by offering package systems, requires multidisciplinary skills. These include mechanical, thermal, and electrical engineering skills for designing custom applications.
As a principle of CHP, thermal energy must be recovered along with the on-site generation of electricity. Studies have shown that electric utility prices would beat the cost of operating a fossil fuel-driven electric generator without recovery equipment. CHP programs typically require the system to achieve a minimum of 60% overall energy efficiency over the year. Consequently, a feasible CHP project requires coincidence between recoverable thermal loads and electric loads. Potential thermal loads are domestic hot water that offers a predictable pattern around the year, central heating, central cooling with the use of an absorption chiller, or a heated pool. The electric baseload generally includes common area lighting and, if the building is master metered for electricity, the total of all apartment electric loads.
In addition, CHP implementation involves a strict development process. This process consists of a series of steps that require coordination among the building manager, the engineers, the electricians, the plumbers, the local electric utility for grid connections, and sometimes the local gas utility, and local permitting entities. Prior to procurement, the client should (1) ensure that the site qualifies for CHP; (2) prescreen to estimate cost-effectiveness; (3) and conduct a feasibility study that involves monitoring, CHP selection, energy savings, and capital costs. While an engineering firm would perform a feasibility study, there are several ways to do the qualification and prescreening. Using guidelines or computer-based tools is one way to qualify and prescreen a building for CHP.
Multicogen Tells You If CHP Is Right
Under contract with NYSERDA, Steven Winter Associates (SWA), my employer, developed Multicogen, a Microsoft Excel-based screening tool specifically designed for multifamily buildings, to assess the potential for CHP. We wanted to develop a screening tool that would lead building owners to pursue CHP feasibility studies as the next logical step. NYSERDA is interested in using this tool to promote CHP to multifamily managers and accelerate the deployment of CHP applications statewide. In its current version, the tool can analyze CHP projects located in New York State.
Multicogen first walks the user through a series of multiple-choice questions. Then the software estimates the size and cost-effectiveness of a CHP unit based on building size, local energy pricing, energy metering configuration, domestic hot water use, and heating and cooling system configuration. Based on this information, the tool provides an early indication of CHP feasibility. Multicogen will flag a Showstopper (a stop sign is actually displayed on the computer screen) if a screening criterion is not met.
One feature of the tool is its multistage screening capability. It can provide a screening result even with minimal information. Although a thorough screening, including analysis of monthly energy records, is recommended, Multicogen can use the thermal and electric load patterns that are typical for multifamily buildings to perform the initial assessment. There is also the option of uploading report files from multifamily energy conservation software such as TREAT or EA-Quip. This option not only avoids redundancy in entering data, but also establishes CHP screening based on accurate estimates of thermal and electric loads determined by these energy conservation software tools.
The design of Multicogen combines guidelines developed by the Midwest CHP Application Center in 2003 and an algorithm involving the integration of energy loads and usage calculations that are specific to multifamily buildings. For instance, the tool performs a spark spread analysis, which is defined as the cost difference in $/MMBtu between electricity and natural gas. Energy prices largely determine the effectiveness of CHP applications. A minimum threshold of $12/MMBtu is commonly used for prescreening CHP. This means that a project would not be cost-effective in areas where utilities offer a spark spread below $12/MMBtu. Consequently, a Showstopper could be flagged early in the screening process, avoiding the need for entering further data such as monthly energy records, which are often tedious to collect and enter in the tool. We learned in an early stage of testing that the tool could be used as a guide in the decision-making process. Users can actually learn the reasons why the use of CHP is or is not feasible.
At any time, users can access a report sheet that gives him or her the results of the screening analysis. When it is not practicable to use CHP in the building, Multicogen also provides suggestions. For example, if the tool determines that a building is individually metered for electricity, it will suggest switching to a master meter with submetering, in order to make it more feasible to use CHP. Reports display a screening checklist; a range of possible CHP sizes; and estimates of capital costs, first-year energy savings, simple paybacks, and savings-investment ratios (SIRs).
As part of the NYSERDA project, SWA put Multicogen through a validation process. First the tool was tested on more than 100 low-income multifamily buildings in New York State to verify its capacity to work on buildings of various sizes and configurations. Based on the results of this test, the tool was modified to study CHP production up to 600 kW, up from the original maximum of 400 kW.
Second, the estimates provided by Multicogen were compared to the results of CHP feasibility studies and demonstration projects chosen from among previously funded NYSERDA projects. The average annual savings estimate provided by Multicogen was within 9% of the results of these more complex studies. This is rather effective, considering the early stage of screening. However, with Multicogen, capitol costs for installing CHP systems were found to be 26% lower, on average, than the capitol costs of CHP systems in the previous studies.
As a result of the validation process, cost figures used in the Multicogen database were updated to more closely reflect real costs. Following this initial validation process, and confident that Multicogen is an effective screening tool for building owners who are deciding weather or not to do a CHP feasibility study, SWA developed a beta version of the tool for user testing that started last September. Users were selected from among New York State energy auditors and the owners of several multifamily buildings. If the results of the beta test are satisfactory, we can expect the tool to be available to the public in spring 2007.
Although the current version of Multicogen could be made available as a stand-alone Microsoft Excel tool, we foresee a great opportunity in transferring the tool to a Web-based application and expanding it to other states in the future.
FOR MORE INFORMATION:
To learn more about Multicogen, contact the author.
Steven Winter Associates
50 Washington Street
Norwalk, Connecticut 06854
Tel: (203)857-0200, Ext. 298
Web site: www.swinter.com
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