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NxtPhase Optical I, V Transducers for High Voltage

NxtPhase Optical I, V Transducers for High Voltage

NxtPhase Corp., Vancouver BC, has developed a family of optical sensors to measure current, voltage, and power in high voltage power systems. These devices appear to be on the verge of becoming a commercial reality, and offer high accuracy, bandwidth and dynamic range. Integrated into the all-digital electronic substation measurement and control system of the future, they will help revolutionize metering, protection, and power quality management.

These optical voltage and current sensing technologies came out of two parallel independent development programs – one in the US and the other in Canada.

Current Sensor–
Honeywell applied fiber-optic gyro technology developed for demanding civil and military navigation applications to the measurement of current, and teamed with Texas A&M to produce a sensor. The first deployment was with Arizona Public Service at the Cholla Generating Station in 1997 where accuracy of 0.03 per cent has been demonstrated. Honeywell entered into a partnership NxtPhase, who has a complementary voltage technology and a similar market vision.

Voltage Sensor–
The other half of the NxtPhase story begins with Carmanah Engineering Ltd. – a successful hi-tech spin-off from the University of British Columbia (UBC). Carmanah, UBC and BC Hydro partnered to develop an integrated optic voltage sensing technology based on a unique electric field sensor called the Integrated Optic Pockels Cell (IOPC). Significant technological breakthroughs led to an extremely accurate optical voltage transducer that avoids the environmental concerns of alternative optical or conventional technologies. The first IOPC sensor was successfully deployed in 1997 at the Ingledow substation of BC Hydro.

Optical Voltage and Current Transducer–
The NXVCT combines both the optical voltage and current transducers in one instrument, over the range of transmission voltages from 69 kV to 765 kV.

Applications include:
– Accurate metering of independent power plants (The dynamic range means accuracy at 1 amp and at 100,000 amps. This can have substantial revenue implications, with the ability to measure power inflow when a plant is not producing power);
– High bandwidth monitoring of power plants, i.e. transients and harmonics; and
– High voltage power quality measurements, to diagnose equipment failures.

Very shortly a technology alliance with BC Hydro will be announced. BC Hydro will conduct field trials to test and demonstrate the devices at one of its high voltage substations to verify performance over time, and at various operating temperatures. The company is looking for customers, partners and investors. They are already in discussions with several UFTO companies and others.

For more information about the company and its products, the website is:
http://www.nxtphase.com/

Contact:
Richard MacKellar, CEO, NxtPhase Corp., Vancouver BC
604-215-9822 x 222, rmackellar@nxtphase.com

Steve Dolling, Director, Marketing
604-215-9822 x233, sdolling@nxtphase.com

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Further details on the technology are available:
http://www.nxtphase.com/nx3.htm

“Design Options Using Optical Current and Voltage Transducers
in a High Voltage Substation”
IEEE PES Substation Committee Annual Meeting May 1, 2000
Powerpoint presentation gives a good overview.

http://www.nxtphase.com/IEEE_substation_meeting_final_version.ppt

Here is the first page of each of two articles, and links for the pdf downloads.

“Optical Voltage Transducers for High-Voltage Applications”
http://www.nxtphase.com/NXVT.pdf

Optical methods for the measurement of current and voltage in high-voltage (HV) environments have been attracting more and more attention in the recent years. This is mostly due to the advantages that they offer over conventional instrument transformers. They provide immunity to electromagnetic interference, are typically non-intrusive, provide excellent galvanic isolation, are much lighter and, therefore, easier to transport and install. Early work on optical current and voltage sensing in the HV environment started in the 1970’s [1-5] leading to more practical and accurate systems developed in the 1980’s and 1990’s [6-13]. Also, at the commercial level, current sensing technology (both for technical and economical reasons) led voltage sensing technology. In this paper, we present results obtained using NxtPhase’s optical voltage transducer, NXVT.

Most practical optical voltage sensors use electric field sensors that operate using the linear electro-optic (or Pockels) effect. It should be noted that the sensors themselves are, strictly speaking, electric field sensors and not voltage sensors. However, various means of getting a one-to-one relationship between the voltage applied and the electric field sensed are used to derive voltage. For example the entire voltage can be applied across the electro-optic crystal, or a capacitive divider can be used to apply a well-known fraction of the voltage to be measured across an optical electric field sensors. There are advantages and disadvantages to each of these methods. Nevertheless, most successful devices in the past have used optical fibers for the transmission of light, bulk electric field sensors as sensing elements, and SF6 gas for insulation.

The NXVT introduced here combines the typical benefits of optical sensing technology with some additional features that provide further benefits to the user. For example, it does not use SF6 or oil-paper insulation, making it more environmentally friendly and much safer to use. The NXVT uses multiple miniature electric field sensors inside a high-quality post insulator, in a proprietary manner, to measure voltage with high accuracy.

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“Optical Current Transducers for High Voltage Applications”
http://www.nxtphase.com/NXCT.pdf

Background
Over the past 15 years, optical current sensors have received significant attention by a number of research groups around the world as next generation high voltage measurement devices, with a view to replacing iron-core current transformers in the electric power industry. Optical current sensors bring the significant advantages that they are non-conductive and lightweight, which can allow for much simpler insulation and mounting designs. In addition, optical sensors do not exhibit hysteresis and provide a much larger dynamic range and frequency response than iron-core CTs.

A common theme of many of the optical current sensors is that they work on the principle of the Faraday effect. Current flowing in a conductor induces a magnetic field, which, through the Faraday effect, rotates the plane of polarization of the light traveling in a sensing path encircling the conductor. Ampere’s law guarantees that if the light is uniformly sensitive to magnetic field all along the sensing path, and the sensing path defines a closed loop, then the accumulated rotation of the plane of polarization of the light is directly proportional to the current flowing in the enclosed wire. The sensor is insensitive to all externally generated magnetic fields such as those created by currents flowing in nearby wires. A measurement of the polarization state rotation thus yields a measurement of the desired current.

The optical current transducer being developed by NxtPhase (the NXCT) is an offshoot from the Honeywell fiber optic gyro program. Honeywell has been producing fiber optic gyros for a variety of commercial aviation applications since 1992. Extensive life and reliability testing has been carried out on the product to meet the stringent flight qualification criteria. Early on, Honeywell realized that this technology, with only minor modifications, could be applied to the field of current sensing, and a program to diversify into this area was maintained by Honeywell for several years. In late 1999, Honeywell joined with Carmanah Engineering to launch NxtPhase with the charter of commercializing the technology.

Principle of Operation
The NXCT uses the Faraday effect, but in a different architecture than the more well known polarimetric technique. The NXCT is a fiber optic current sensor and it works on the principle that the magnetic field, rather than rotating a linearly polarized light wave, changes the velocities of circularly polarized light waves within a sensing fiber wound around the current carrying conductor [1]. The effect is the same Faraday effect but differently formulated. We have found in our experience and heritage from the Honeywell fiber-optic gyroscope program that, for a variety of reasons, it is easier to accurately measure changes in light velocity than changes in polarization state. Chief among these reasons is that by using a velocity measurement scheme, we do not need to construct the sensing region from annealed fiber which is brittle and difficult to work with in a production environment.

Elec. Cable Research-Sandia

Electric Cable Life Assessment and Condition Monitoring

John Clauss, 505-844-5449, jmclaus@sandia.gov
Curt Nelson, 505-845-9253, cnelson@sandia.gov

Sandia has an extensive program to study electric cables, primarily in the context of nuclear power plant safety. Cables are everywhere in power plants, transmitting power and information, and can be the origin of common mode failures, e.g. when many cables fail simultaneously during an accident. Generally, cables perform well in U.S. nuclear plants, but life extension and relicensing are leading to increasing needs for techniques to guarantee cable functionality under both normal and accident conditions.

Cable Life Assessment

– Cable Material Aging/Degradation Modeling – accelerated aging tests introduce new questions which must be taken into account, such as whether short exposure to high temperature is equivalent to long times at moderate temperature, and how to treat the combined effects of time, temperature and radiation dose rate. Ironically, low temperature can inhibit self-healing in polymers. A new promising technique involves measuring the oxygen consumption of the insulating material, which could permit very accurate aging measurements in a short time.

– Lab vs Natural Aging – The Sandia Cable Repository of Aged Polymer Samples (SCRAPS) – Sandia maintains a library of thousands of samples of common cable materials that have been aged in the lab, representing over 2000 separate experimental aging environments.

Condition Monitoring Research

– Electric NDE – a new Electric Cable Evaluation Facility (ECEF) is just going into operation, providing cable tray and conduit systems typical of power plants. The cables have fully characterized mechanical defects, hidden for NDE systems to locate as a “blind” test. To keep things interesting, the size, type, distance down the cable, etc. are varied from one cable to the next. Some cables have no defects. Special access ports permit visual observation of the defects following a “blind” NDE test.

ECEF will be used to test claims made by various developers for new cable NDE techniques, which historically haven’t faired well. It will also serve as a test bed for the development of new methods. Sandia has a proposal in to DOE and NRC for an evaluation of new Russian method called DIACS.

Sandia developed a new high-voltage fast pulse technique for electrical NDE (100kV, 1 nsec risetime, 10-500 nsec pulse width — low total energy insertion). It combines features of time-domain reflectometry (TDR) and partial discharge techniques, with electrical and acoustic indications of breakdown location. Sandia has done limited proof-of-principle testing that shows potential for use in a highly-constrained geometry.

(** Maybe a new approach for in-situ testing of underground distribution cable?? ** )

– Physical Monitoring – Density Technique
Preliminary research has shown a correlation between density and tensile elongation-at-break in many cable materials. Since density measurements can be made on very small samples of material, this may be a new NDE condition monitoring technique. For some materials, the density change occurs at a fairly constant rate. In others, the rate of density increase is slow, then reach a point at which it increases dramatically. The opposite can also be observed, i.e. fast at first, and then slow. Early results indicate that density measurements could represent a very useful condition monitoring technique.

“Density Measurements as a Condition Monitoring Approach .. ”
draft SAND report 1/21/98, KT Gillen, et. al.

ORNL Utility Survey

Subject: UFTO Note — ORNL Utility Survey
Date: Wed, 09 Jul 1997 11:49:03 -0700
From: Ed Beardsworth

The Engineering Technology Division at Oak Ridge sent out a survey to a list of utilities recently, with a cover letter from Ed Fox, the division director. Some of you have already seen it, and I have the names of who it was sent to in your companies if you want them.

The stated purpose is to increase utility awareness of ORNL R&D, to obtain feedback on the relevance to utilities of that work, and on priorities for additional R&D. Also, they want stronger ties to utilities and potential users of ORNL work…a goal certainly congruent with UFTO!

Ed Fox can be reached at 423-574-0355, ecf@ornl.gov

The survey is being administered by:
Scott R. Penfield, Jr., Technology Insights
P.O. Box 205, Signal Mountain, TN 37377-0205
423-842-8078 Tel 500-346-9500 Alt. Tel
423-886-3225 FAX penfield@ti-sd.com

The text of the survey is attached below, and includes a number of technologies previously reported by UFTO.

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| ** UFTO ** Edward Beardsworth ** Consultant
| 951 Lincoln Ave. tel 415-328-5670
| Palo Alto CA 94301-3041 fax 415-328-5675
| http://www.ufto.com edbeards@ufto.com
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ORNL SURVEY OF UTILITIES

Part I: Current ORNL R&D Programs

The following topics briefly summarize ongoing R&D programs at ORNL. For each, please indicate whether you were previously aware of the work and provide a rating (on a scale of 1-10) as to how relevant the work is to your current needs. (If you were not previously aware of an individual R&D item, please base your rating on the summary.) If you wish further information on any topic, please so indicate.
WWW ADDRESS FOR THE ENGINEERING TECHNOLOGY DIVISION
HOME PAGE: http://www.ornl.gov/etd/etdfctsh.htm

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1.0 PLANT/EQUIPMENT DIAGNOSTICS AND CONDITION MONITORING
The following technologies provide for monitoring the condition of machinery in service, on-line diagnostics for evaluating faults, plus R&D into effects of machinery aging. The objective is to relate appropriate maintenance or replacement actions to the actual condition of the machine.

1.1 Electrical Signature Analysis (ESA)
Data characterizing electrical currents and voltage waveforms to/from motors, generators and similar devices are obtained and recorded, using non-invasive probes. ORNL-developed analysis techniques are applied to the resulting data, leading to powerful insights into the health and performance of the electrical machine and the system and/or facility in which it is installed. A typical utility application involved the evaluation of transient loads in motor operated valves at a Carolina Power & Light nuclear plant. More recent developments include improved data analysis techniques and methods for the integrated monitoring of complete systems.

Status: Early forms of ESA are being used in a range of industrial applications, including utility power plants. Licensees include B&W/Framatome and ITT Movats/Westinghouse and Public Service Electric and Gas of New Jersey. More recent developments are available for licensing and/or joint development.

Previously aware of this research: _ Yes _ No
Request additional information: _
Relevance to current needs (please circle):
(Low) 1 2 3 4 5 6 7 8 9 10 (High)

1.2 Non-Intrusive Voltage and Power Factor Monitoring
ORNL is evaluating a series of new technologies for obtaining high voltage (>480V) waveforms and power factors, without contact and without the need for potential transformers. These technologies have significant potential in power quality monitoring applications.

Status: These technologies are in an early stage of development and evaluation. They are available for licensing and/or joint development.

1.3 Check Valve Monitoring
The function and health of check valves are evaluated, using a combination of magnetic and vibration sensors. Lack of adequate function and deterioration can be detected, without the need for removal or disassembly of the component.

Status: This technology has been licensed to several service vendors, including B&W/Fram- atome and ITT Movats/Westinghouse. Consolidated Edison is also a licensee.

1.4 Improved Eddy-Current Material Defect Detection
ORNL is developing a new technology for improved defect detection and imaging in non-magnetic materials. In laboratory tests, cracks in a perforated aluminum plate, located behind a 60 mil solid aluminum plate, are clearly imaged. In addition to aircraft inspection (the initial target for this innovation), steam generator tube inspection is a potential application of this new eddy-current based technique.

Status: This technology is in the early stages of development.

1.5 Effects of Aging in Machinery
ORNL has developed a vast database and associated reports on the effects of machinery aging. Information and expertise are available on the general principles of machinery aging as well as the specific effects of aging on individual components, machines and systems.

Status: The database was developed in support of NRC investigations into the effects of aging on nuclear power stations. It is available in the form of reports at the present time. Work is ongoing to develop methodologies to support condition based maintenance decisions.

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2.0 PLANT INSTRUMENTATION & CONTROL
ORNL’s capability for conceiving, prototyping and implementing advanced instrumentation and control (I&C) capabilities extends from the I&C support of experimental work throughout the laboratory and from supplying innovative sensor and control technologies to federal agencies, utilities and private industry. The following are examples of related utility applications.

2.1 Plug-in Compatible Instrumentation and Control Upgrades
ORNL has developed and prototyped a concept in which application-specific integrated circuits (ASIC’s) mounted on a motherboard replace corresponding analog modules originally installed in utility power plants. The simplicity of the individual ASIC’s reduces concern with common mode failures, a current issue with complex software driven systems. The resulting plug-in compatible replacement modules simplify installation and operation, because rewiring is not required and because changes to operating procedures are minimized.

Status: ORNL is supporting EPRI and the Westinghouse Owner’s Group in the advancement of this technology. A prototype safety system module has been fabricated and is currently undergoing testing.

2.2 Accurate On-Line Measurement of High Temperatures
ORNL has developed a technique for continuous in-situ calibration of resistance temperature detectors. The goal is to maintain an accuracy of 0.5% (°F) under actual operating conditions and to extend the range of useful measurement from about 900°K (1200°F), at present, to 1300°K (1800°F). A typical application would be measuring steam temperatures for on-line determination of plant efficiency.

Status: The technology has been developed to a pre-commercial form and feasibility has been established through demonstrations at the Diablo Canyon and Connecticut Yankee nuclear stations, as well as tests in the Kingston Steam Plant (EPRI I&C Facility).

2.3 Solid-State Hydrogen Sensor
ORNL and EPRI are developing a small, solid state hydrogen sensor for nuclear plant containment monitoring. Other utility applications might be in conjunction with hydrogen cooled generators, battery banks, etc.

Status: The sensor is patented and available for licensing. Tests have been conducted in air, nitrogen, argon, steam and transformer oil and for H2 concentrations of 0.5% to 30%.

2.4 Automated Measurement of EMI/RFI
ORNL has developed and used an instrument to monitor and record ambient electromagnetic interference/radio frequency interference (EMI/RFI) in power stations. The system is capable of non-obtrusive, unattended operation over several-month periods.

Status: Available now for licensing or use.

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3.0 NON-LINEAR TIME-SERIES ANALYSES
The catchy but misleading name “Chaos” has often been associated with a family of advanced non-linear time-series analysis techniques. In reality, these methods allow a degree of order to be
discerned for what otherwise appear to be a series of highly random events. Examples of practical utility applications are provided below.

3.1 Improved Combustion Control
Non-linear analysis can be used to analyze and optimize fossil power plant burners, fluidized bed combustion systems and, potentially, gas turbines for higher efficiency and improved NOx control.
Status: An early application was the characterization of fluid bed combustion systems, where an objective was to avoid unstable operating regimes (e.g., chugging). More recently, the potential of this technology for improving fossil burner control is being developed through a project involving EPRI, ORNL and B&W.

3.2 Failure Prediction
There is a further potential for applying non-linear analysis to advanced machinery diagnostics/ failure prediction (e.g., in turbine-generators). Bearings, in particular, appear to exhibit chaotic behavior in advance of certain failure modes.

Status: Non-linear analysis is being evaluated in conjunction with diagnostics and condition monitoring techniques, such as electrical signature analysis (see above). Westinghouse has expressed an interest in bearing diagnostics.

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4.0 TRANSMISSION AND DISTRIBUTION

ORNL is developing technologies for automating the control of transmission systems, increasing system capacity and providing an improved understanding of the underlying costs of ancillary services.

4.1 Real-Time System Control
ORNL, DOE and EPRI are developing the technology for real-time monitoring and control of widely distributed transmission systems. This compares with current practice in which responses to disturbances are predetermined on the basis of previously completed analyses. The real-time system will employ an array of monitors, with outputs time-synchronized by satellite clocks. Artificial intelligence techniques will be used to recognize and appropriately respond to disturbances.

Status: This work is in the early stages of development.

4.2 High Capacity Transmission
ORNL has participated in R&D for increasing the capacity of high-voltage transmission lines. Included was testing of a high phase order line, which has the potential for transmitting up to three times the power of a standard single circuit AC line.

Status: The potential of this technology has been confirmed through the operation of a 1.5 mile test section, sponsored by EPRI, DOE, NYSERDA, NYSEG and ESEERCO. Given the current transition to independent operation of transmission capacity, no follow-on work has yet been identified.

4.3 Cost of Ancillary Services
One challenge in establishing the pricing basis for open access to electrical transmission systems is placing a value on ancillary services (scheduling and dispatch, load following, system protection, VARs, energy imbalance, and real power losses). Initial estimates developed by ORNL range from $1.5-$6.8/MWh, with an average of $4.1/MWh. By contrast, the FERC pro-forma schedule includes an allocation of $1/MWh for ancillary services.

Status: An initial report, based on an analysis of 12 utilities is now available. Follow-on work is recommended to establish a consistent framework for estimates.

5.0 POWER ELECTRONICS
This area includes research in power electronics, which is finding broad applicability in power quality, energy conversion and storage, adjustable speed drives, transmission, links, etc.

5.1 Resonant Snubber Inverter
The Resonant Snubber Inverter (RSI) is a power electronics innovation that employs a special resonant circuit to reduce losses during switching. Tests at ORNL have shown efficiency to be improved by 15 percentage points at half speed and 5 percentage points at rated speed. Elimination of associated voltage spikes reduces voltage stresses (leading to higher reliability), and essentially eliminates electromagnetic interference. Potential uses include power conversion for energy storage devices (e.g., flywheels, ultracapacitors, etc.) and adjustable speed drives.

Status: The RSI is currently being developed at ORNL for a number of specific applications.. The technology is available for joint development and/or licensing.

5.2 Multilevel Converter
The Multilevel Converter is another power electronics innovation that allows synthesis of high voltage waveforms, using capacitors as voltage dividers. Potential applications include DC links, static VAR generators and high voltage variable speed drives, as well as power conversion from renewable energy sources (such as photovoltaic arrays) or battery-fed systems. The ORNL technology eliminates the need for transformers, which are a significant source of cost and energy losses in conventional systems. A problem with capacitor based systems is the tendency to develop an imbalance between voltage levels when real power is being transferred (this is not a problem in static VAR generator applications). The unique contribution of ORNL is a new approach for maintaining the desired voltage balance across the capacitors, when real power is being transferred.

Status: An 11-level (21-level phase to phase) multilevel converter, employing insulated gate bipolar transistors (IGBTs) is working in the laboratory at ORNL. This system is prototypical of a 60kV multilevel converter using gate turn-off thyristors (GTOs).

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6.0 INFORMATION MANAGEMENT AND OPERATIONS ANALYSIS
This area comprises R&D on information management and operations analysis methodologies which support the management decision process.

6.1 Integrated Operational and Economic Models
ORNL has developed an extensive capability for operations and economic modeling techniques that support the management decision process. Alternative courses of action can be evaluated on a probabilistic basis, taking into account both the likelihood of various outcomes and their technical and economic consequences. Typical examples in which utilities might apply such techniques include evaluating the business potential of a new energy storage device, or determining the likelihood that a nuclear facility would be profitable over its remaining lifetime.

Status: These modeling techniques have been extensively applied. A recent example is a probabilistic assessment (for DOE) of the economic viability of each of the nuclear plants currently operating in the U.S.

6.2 Real-Time Power Scheduling
ORNL developed a “Power Advisor” to guide the operations of the Paducah, KY uranium enrichment plant in response to real-time electric power pricing inputs. The model provides a basis for deciding whether blocks of power at a given price should be accepted or whether it is more cost effective to curtail plant operations. The model includes consideration of the technical limitations of the facility, as well as the economic impact on the product bottom line.

Status: In place and operating at Paducah, KY.

6.3 Performance Indicators
The performance indicator methodology developed by ORNL is an operations management process for filtering and organizing the vast amounts of data generated in a complex management environment. The key objective is to focus management attention on activities that have the most influence on organizational goals, such as economic return, operational efficiency, safety, etc. The process starts with the selection of key performance indicators. These individual measures of performance are subjected to additional analysis and weighting, resulting in composite indices representative of overall performance, analogous to a stock market index. Feedback mechanisms are included to optimize information flow and to respond to organizational changes over time.

Status: Currently employed by DOE for managing the DOE occupational safety and health program.

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7.0 UTILITY/CUSTOMER TECHNICAL SUPPORT
The following research areas would potentially support both utility and utility customer technology support needs.

7.1 Electric Machinery Analysis
ORNL has developed an improved motor equivalent circuit model to more accurately estimate the operating characteristics of electric motors. Input to this computer-based tool can start from name plate data and increased accuracy can be obtained with supplemental calibration measurements (e.g, speed and current). Once calibrated for a given machine, the method can be used to accurately predict loads, currents, efficiency, etc. As a result, the need for additional monitoring instrumentation may be reduced in some cases.

Status: The model is complete and available through the DOE Motor Challenge Program

7.2 High Temperature Thermography
Techniques developed by ORNL offer improved capability for accurately measuring high temperatures. Using emissions from thermographic phosphors, temperatures can be measured over a wide range (cryogenic to 1600°C [2900°F]) and without the need for physical contact.

Status: This technology has been applied to several industrial processes. Initial applications have included the first stage vanes of turbine engine gas generators and the surface of steel exiting a molten zinc bath in a galvanizing process.

7.3 Electric Machinery Test Facility
ORNL has developed a flexible and well instrumented Electric Machinery Test Facility. The current capacity is 100 hp, but is now being expanded to 700 hp. During testing, loads can be varied over a wide range. Input voltage and currents can also be varied to simulate various operating demands, as well as a range of power quality situations (e.g., voltage imbalances, harmonics, etc.)

Status: The Electric Machinery Test Facility is a National User Facility available for use by private sector entities for testing and qualification of motors, generators and related components at nominal cost.

7.4 Pump Test Facility
ORNL recently commissioned a Pump Test Facility, with a design capacity of 100 hp. The configuration of the facility is highly flexible in terms of flow configuration, installed components and provisions for instrumentation and monitoring.

Status: The Pump Test Facility is a National User Facility available for use by private sector entities for testing and qualification of pumps and related components at nominal cost.

7.5 Buildings Technology Center
ORNL is actively involved in developing technologies to improve the efficiency of buildings and installed equipment. The Buildings Technology Center (BTC), established at ORNL in 1994, includes a large scale climate simulator and a hot box for testing components (walls, windows, etc.), as well as facilities for testing equipment (e.g., heating and air conditioning).

Status: The BTC is a National User Facility available for use by private sector entities for testing and qualification of building components at nominal cost.

Part II: Priorities for Additional R&D
Please indicate below up to three areas of R&D that would most help your organization to meet its objectives.
1.
2.
3.

Part III: Contact for Liaison with ORNL

Please identify one or two individuals that could serve as a liaison with ORNL managers. We will keep them informed of new innovations at ORNL and request their input regarding utility R&D priorities in the future.
1. Name Title Organization
Address
Tel FAX E-Mail

2. Name Title Organization
Address
Tel FAX E-Mail