FINAL CADER Report Available

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Forwarding note just received a few minutes ago.

Subject: FINAL CADER Report Available
Date: Fri, 17 Apr 1998 15:05:04 -0700
From: ERIC WONG
To: edbeards@ufto.com

FINAL CADER REPORT Now Available! High Quality, perfect bound edition. The 400 page report, a documentation of the work of the California Alliance for Distributed Energy Resources (CADER) and a compilation of the papers presented at the September 1997 CADER Conference is available. Please send a $10 check or money order (per copy) along with your return address to CADER, 770 L Street, Suite 810, Sacramento, CA, 95814. Make the check or money order out to CADER. Charge Card numbers will not be accepted. Upon receipt of payment, your report will be mailed via first class. Orders are being handled by Vanessa; she can be reached at 916-329-9180. The Energy Commission is not handling any orders.

Active members of CADER, that is those who served on committees, and the co-chairs, will receive one copy free. These will be mailed during the week of April 20.

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Here’s a portion of an UFTO note from July 15, 1997:
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** CADER – California Alliance for Distributed Energy Resources

CADER is an alliance of public and private organizations formed in 1996 to identify and develop specific solutions to the deployment of Distributed Resources. Initially set up with the help of the California Energy Commission, it is a self-managed organization.

Mission Statement: A consortium of manufacturers, users, energy service companies, engineering firms, utilities, power providers, research organizations, regulators, financial institutions, and others committed to facilitating the successful entry of clean, energy efficient Distributed Resources into a competitive electricity energy market.

CADER CONFERENCE SEPT 15-17, 1997, San Diego CA

CADER will host a three day conference to explore economically and environmentally viable alternatives to grid-based power systems. Key energy industry experts from across the country will assemble at this first-of-its-kind meeting to debate how distributed resources figure into the rapidly changing electricity marketplace.

The conference, entitled “Distributed Resources: Addressing the Challenges”, will take place September 15 through 17, 1997 at the Catamaran Resort Hotel, 3999 Mission Blvd., San Diego, California 92109. Hotel reservations are available by calling the hotel directly at 619-488-1081 or 800-288-0770.

The San Diego conference will highlight the latest technology developments such as photovoltaic solar systems, fuel cells, storage technologies such as flywheels and batteries, and advanced gas turbines. In addition to site visits and technical sessions, conference participants will discuss an array of environmental, regulatory and market-related issues.

Speakers invited to the CADER Conference include: Governor Pete Wilson; Congressman Dan Schaefer; California Senator Steve Peace; Amory Lovins, Rocky Mountain Institute; Federico F. Pena, Secretary, U.S. Department of Energy; and David Freeman, Trustee, ISO/PX.

Conference technical sessions will focus on the following areas:

Energy policy
Incentives and market rules
Legal, institutional and regulatory issues
Siting and environmental regulatory streamlining
Land use planning and computer tools
Manufacturer/technology issues

The conference builds on the success of CADER’s pioneering efforts to ensure the economic competitiveness of Distributed Resources and will focus on how distributed generation systems can provide local distribution utilities, end-users, independent power providers and energy service providers with another generation choice, improved power quality and more reliable service.

Contact Connie Bruins, California Energy Commission
(916) 654-4545 cbruins@energy.state.ca.us

Complete details and extensive documentation, and details about the conference, are available on the website

http://www.energy.ca.gov/CADER/

Renewable Energy Technology Characterizations

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In 1996, the U.S. Department of Energy’s Office of Utility Technologies (OUT) and the Electric Power Research Institute began preparing a document characterizing the current status and projected performance and cost improvements of several emerging renewable energy technologies. This detailed document was recently completed and can now be downloaded as a collection of files on the OUT Web site organized under the following major headings: Biomass, Geothermal, Photovoltaic (PV) Technologies, Solar Thermal Technologies, Wind Technologies, Project Financial Evaluation, and Energy Storage Technologies. (DOE April 3, 1998)

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http://www.eren.doe.gov/utilities/techchar.html
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U.S. Department of Energy Office of Utility Technologies

Renewable Energy Technology Characterizations

A joint project of the Office of Utility Technologies, Energy Efficiency and Renewable Energy, U.S. Department of Energy and the Electric Power Research Institute

The Renewable Energy Technology Characterizations describe the technical and economic status of the major emerging renewable energy options for electricity supply. These technology characterizations represent the best estimates of the U.S. Department of Energy (DOE) and the Electric Power Research Institute (EPRI) regarding the future performance and cost improvements expected for these technologies as a result of continuing research and development (R&D) and development of markets for renewable energy through the year 2030.

Background
These technology characterizations, which have existed as working drafts primarily for internal use at DOE, were originated in 1989 to support analyses in the development of the first National Energy Strategy. Because of growing interest in renewable energy technologies, an increasing number of researchers and energy policy analysts have expressed interest in having access to these technology characterizations. In response to requests to make these data more widely available, the current updates can now be downloaded from this Web site and are also available in paper form (EPRI Topical Report No. TR-109496, December 1997).

Copying and Distribution
The Renewable Energy Technology Characterizations are copyrighted, but permission is granted for unlimited copying for noncommercial use.

Ordering Information for Paper Version
The paper version of the report is available from EPRI, at $50.00/copy for domestic U.S. customers. Requests for paper copies of this report, as well as pricing for non-U.S. customers, should be directed to: EPRI Distribution Center, 207 Coggins Drive, P.O. Box 23205, Pleasant Hill, CA 94523; (510) 934-4212.

Technology Characterizations

The technology characterizations can be downloaded by selecting the PDF files below. (You must have Adobe Acrobat Reader 3.0 to view these files error free.) Learn about PDFs.

Front Matter (PDF 98KB)
Title page
Disclaimer and Copyright Notice
Report Summary and Abstract
Acknowledgments
Contents, Figures, and Tables

Introduction and Overview (PDF 279KB)

Biomass
Overview of Biomass Technologies (PDF 38KB)
Gasification-Based Biomass (PDF 337KB)
Direct-Fired Biomass (PDF 84KB)
Biomass Co-Firing (PDF 229KB)

Geothermal
Overview of Geothermal Technologies (PDF 64KB)
Geothermal Hydrothermal (PDF 178KB)
Geothermal Hot Dry Rock (PDF 179KB)

Photovoltaic (PV) Technologies
Overview of PV Technologies (PDF 368KB)
Residential PV (PDF 808KB)
Utility-Scale Flat-Plate Thin Film PV (PDF 349KB)
Utility-Scale PV Concentrators (PDF 119KB)

Solar Thermal Technologies
Overview of Solar Thermal Technologies (PDF 304KB)
Solar Power Tower (PDF 311KB)
Solar Parabolic Trough (PDF 380KB)
Solar Dish Engine (PDF 910KB)

Wind Technologies
Overview of Wind Technologies (PDF 227KB)
Advanced Horizontal-Axis Wind Turbines in Wind Farms (PDF 353KB)

Project Financial Evaluation (PDF 343KB)
Introduction to Figures of Merit
Financial Structures
Techniques for Calculating Levelized COE
Financial Model and Results
Payback Period

Appendix: Energy Storage Technologies
Overview of Energy Storage Technologies (PDF 36KB)
Battery Storage for Renewable Energy Systems (PDF 112KB)

EL-24496

National Combustor Code (NCC)–new software from NASA

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Based on contacts made during the UFTO visit last year to NASA Lewis, we received an early notice about this soon-to-be announced Technology Opportunity. NASA has developed a major new combustion modeling code, and is looking for new areas that it can be applied. Private companies can submit problems. Terms and scope of an agreement would then be negotiated, giving the company a one year head start in evaluating the merits of seeking a commercial license.

(I have a full color acrobat pdf file of the notice that I can send you on request.)
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April 15, 1998

Ed,

It was a pleasure speaking with you today and thank you for agreeing to send your utility clients a copy of the attached NASA Technology Opportunity sheet which describes the National Combustion Code (NCC).

Please have interested clients contact me prior to contacting Nan-Suey Liu (NASA Lewis Combustion Branch ph: 216-433-8722). Nan-Suey is the NASA Lewis contact who will discuss technical features of the NCC with interested parties.

Please give me a call if you have any questions and thank you for your cooperation!

Dan DeMiglio
Great Lakes Industrial Technology Center
(Div of Battelle Memorial Institute)
NASA Midwest Regional Technology Transfer Center
440-734-1209 demiglio@battelle.org

—- text of the notice ———————————
Technology Opportunity National Aeronautics and Space Administration

Lewis Research Center Turbomachinery TOP3-00093

A new software program – the National Combustor Code (NCC) – has been developed for aerospace and non-aerospace engineers and designers to enhance their understanding of physical and chemical processes which occur during continuous combustion. The NCC provides insight – for the first time – to the entire combustion process using a versatile and comprehensive set of tools. The National Aeronautics and Space Administration (NASA) seeks to transfer this multidisciplinary combustor design system to U.S. companies for advanced liquid and gaseous continuous combustion applications. The NCC utilizes computer-aided design (CAD) tools for geometry creation, advanced mesh generators for creating solid model representations, a common framework for fluid flow and structural analyses, and powerful tools for post and parallel processing. The National Combustion Code: A Multidisciplinary Combustor Design System

Potential Commercial Uses

• Evaluate the performance of current liquid and gas combustion systems leading to product improvement.

• Optimize the design of future liquid and gas combustion systems leading to increased performance and reliability.

• Examples of relevant liquid and gas combustion systems are:
– Aviation gas turbine engines
– Industrial/ground power gas turbines
– Industrial combustion devices involving continuous burning of liquids and gaseous fuels
– Hazardous waste incinerators
– Steel treating furnaces
– Domestic gas fired appliances

Benefits

• Product improvement for current combustion devices with respect to efficiency and durability
• Reduced time and costs for the design cycle of future combustion devices
• Optimized performance and reliability for future combustion devices

The Technology

The development of the National Combustion Code was pursued under a NASA/Department of Defense/ Department of Energy/U.S. industry partner-ship. Recent efforts have been focused on developing a computational combustion dynamics capability that meets combustor designer requirements for model accuracy and analysis turnaround time, incorporating both short–term and long–term technology goals. As a first step, a baseline solver for turbulent combustion flows was developed under a joint modeling and code development effort between the Aero-Industry and the NASA Lewis Research Center. This baseline solver is a Navier–Stokes flow solver based on an explicit four-stage Runge– Kutta scheme that uses unstructured meshes and runs on networked workstations. The solver can be linked to any computer-aided design system via the Patran file system. Turbulence closure is obtained via the standard k–e model with a high Reynolds number wall function. The following combustion models have been implemented into the code: finite– rate reduced kinetics for Jet–A and methane fuels, turbulence–chemistry interactions via an assumed probability density function for temperature fluctuations, and thermal emissions of nitrogen ox-ides. The solver can switch between a parallel virtual machine (PVM) interface and a message-passing interface (MPI) by using compiler flags. Its parallel performance on several platforms has been analyzed, and on the basis of the results, several improvements have been made. To date, the baseline solver has been used in the following applications: simulation of swirling flow experiments, computation of a generic swirling flow can combustor, computation of a multi-shear low NOx fuel nozzle and calculation of a multi-walled production fuel nozzle, and calculation of a flame holder/Cyclone 1-cup sector.

Options for Commercialization

The executables of the National Combustor Code, Beta Version 2.0, and the corresponding nonproprietary source code will be available for release to the non-aerospace industry by summer 1999. Beginning in the summer of 1998, NASA would be willing to demonstrate the accuracy and reliability of the NCC by applying it to a wide range of areas where it would be helpful to have accurate predictions of the combustor process.

Contact

Gynelle Steele, Technology Utilization Engineer
NASA Lewis Commercial Technology Office
NASA Lewis Research Center
Cleveland, OH 44135
Phone: (216) 433-8258 FAX: (216) 433-5012 Gsteele@lerc.nasa.gov

Dan DeMiglio, Client Services
Great Lakes Industrial Technology Center
Phone: (440) 734-1209 (440) 734-0686 demiglio@battelle.org

EMF Engineering Review Symposium, April 28-29, 1998

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Reporting briefly from ORNL–a heads up about this upcoming conference on EMF.

The RAPID program is drawing to a close, but more critically, DOE may not continue with its own core EMF program. This conference may be an important forum for that issue to be raised. One implication-a void in the U.S. when and if standards are set internationally!

An excellent contact on EMF issues overall is Paul Gailey at Oak Ridge.
423-574-0419 pg7@ornl.gov

http://www.emf-data.org/symposium98.html

(Note this website as a resource on emf generally)

EMF Engineering Review Symposium
Status and Summary of EMF Engineering Research

April 28-29, 1998
Sheraton Charleston Hotel
Charleston, SC

Organized by the United States Department of Energy

Last updated: February 11, 1998
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BACKGROUND

The Electric and Magnetic Fields Research and Public Information Dissemination (EMFRAPID) Program was established by Congress in the Energy Policy Act of 1992. The Department of Energy (DOE) and the National Institute of Environmental Health Sciences (NIEHS) are partners in the EMFRAPID Program’s effort to address the question of whether extremely low frequency electric and magnetic fields (EMF) produced by the generation, transmission, and use of electric energy pose a risk to human health, and if so, to determine the significance of the risk and to develop mitigation technologies.

ENGINEERING REVIEW SYMPOSIUM

Engineering results provide one of the foundations for understanding and characterizing EMF exposures in biological and epidemiological studies. DOE is convening a public symposium to assess the state of knowledge of EMF engineering issues and to present results of RAPID engineering studies conducted by DOE. These studies focus on exposure characterization and methodologies, exposure levels, and evaluation of strategies for field reduction.

Symposium presentations will address current knowledge of EMF exposure parameters, measurement technology, exposure systems, quality assurance, modeling, and exposure distribution. Participants will evaluate these results and discuss the potential social and economic implications. DOE will document the evaluations and conclusions of participants, together with summaries of each RAPID engineering study. Findings will be integrated into the risk evaluation process, which NIEHS is conducting.

Details and updates on the EMF Engineering Review Symposium will appear on this webpage.

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EMF Engineering Review Symposium

Status and Summary of
EMF Engineering Research

April 28-29, 1998
Sheraton Charleston Hotel
Charleston, SC

GOALS

1. To assess the state of knowledge of EMF engineering issues, and
2. to provide engineering input to the RAPID risk evaluation process.

PROGRAM

The symposium will allow all participants to attend all discussions (there will be no break-out groups). Both on-site discussions and written comments will be incorporated into the report. Proposed topics are listed below.

* Field Parameters
* Measurement Technologies
* Laboratory Exposure Systems
* Field Calculation Models
* Field Management
* Interaction with Biological Systems
* Exposure Assessment Methodologies
* Engineering Quality Assurance for EMF Studies
* Exposure Distribution Across Populations
* Implications of Imposing Field Limits

WHO SHOULD ATTEND

Investigators and users of EMF source characterization, exposure assessment,
laboratory exposure systems, field management techniques, and field modeling
are invited to attend and participate in the discussions. This symposium
will be of interest to researchers in engineering, biological sciences, and
epidemiology, as well as electric utility personnel and regulators. The
meeting is open to the public.

Hotel

A block of rooms is being held through March 27, 1998 at the Sheraton
Charleston Hotel, 170 Lockwood Drive, Charleston, SC 29403, at the
government per diem rate ($89.00 plus 12% tax). For reservations, call
800-968-3569, or fax 803-723-6276. Be sure to state that you are attending
the DOE Engineering Symposium.

Travel Information

The Charleston International Airport services this area. Low Country
Limousine Service offers transportation to and from the airport. The one-way
fare is $15.00 per person. For reservations, call 800-222-4771. Taxis are
available at a slightly higher cost.

Registration

Advance registration is required in order to receive pre-conference
materials. The deadline for registration is March 27, 1998. To register,
please send the following information for each attendee:

* Name
* Name for badge
* Title/Position
* Company/Institution
* Address
* City/State/Zip
* Country
* E-mail address
* Telephone number
* Fax number

To:

W/L Associates
7519 Ridge Road
Frederick, MD 21702
Telephone: 301-663-1915
Fax: 301-371-8955
e-mail: 75230.1222@compuserve.com

Nortel Digital Power Line Joint Venture

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The story is picking up speed. (See UFTO Note March 6 for the last installment.) Nortel and United Utilities have formed a joint venture to pursue the Digital PowerLine Technology worldwide. Part of the Nortel group in Atlanta will form the nucleus for the joint venture’s North American effort.

As last week’s press release explains, 10 major utilities around the world are already committed to deploy DPL. The situation in North America is less far along, due to the technical issues that need to be resolved, however the forming of the joint venture will certainly accelerate the momentum.

Considerably more technical information is now available on the new website at:
http://www.nortel.com/powerline/menu.htm

As explained in the March 6 UFTO Note, two unnamed US utilities are already providing system data, as Nortel continues to work on the details on their business case for N. America. Many utilities have contacted Nortel and indicated a readiness to get involved immediately. The company is keeping a list, but will go slow until it feels it has enough information to proceed.

If your utility hasn’t contacted them yet, it might be wise to get on the list, if not pursue it a bit more aggressively.

The contact is: Barbara Warren, Senior Manager, Digital PowerLine Marketing
770-708-5117, bswarren@nortel.com

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Here’s the text of the latest press release:

Nortel: Joint Venture Formed to Market Digital PowerLine Technology Worldwide; Initial Agreements Reached — Serving More Than 35 Million Homes

March 26, 1998

LONDON, March 25 /PRNewswire/ via NewsEdge Corporation — Nortel (Northern Telecom) and United Utilities PLC today announced the formation of a joint venture company, NOR.WEB DPL, to develop and market Digital PowerLine solutions on a worldwide basis.

Digital PowerLine, which was developed jointly by Nortel and Norweb Communications, part of United Utilities PLC, enables data communications, including Internet traffic, to be transmitted over electrical power distribution networks at speeds of more than one Megabit per second-up to 10 times faster than ISDN, currently the fastest speed generally available.

Nortel and United Utilities will each take a 50 percent stake in the joint venture, which will develop and market Digital PowerLine equipment, software and services. John Beckitt of United Utilities will serve as chairman and Steve Pusey of Nortel has been named chief executive officer.

In conjunction with the formation of the joint venture, NOR.WEB is also announcing that to date, 10 international utilities have signed agreements declaring their commitment in proceeding with initial market deployment of the Digital PowerLine technology.

The potential market for Digital PowerLine through these agreements is more than 35 million homes in seven European and Asian countries.

“We believe that the roll-out of Digital PowerLine will enable the mass deployment of high-speed data access and applications on an unprecedented scale in these markets,” said Steve Pusey, chief executive officer of NOR.WEB. “This first wave of customer agreements demonstrates the scale of global interest in Digital PowerLine.”

“NOR.WEB takes the collaboration between Nortel and Norweb Communications on Digital PowerLine to a new level of commercial activity,” said John Beckitt, chairman of NOR.WEB. “NOR.WEB power utility customers will find that Digital PowerLine provides a low-risk, high-return investment that can be implemented step by step in line with demand.”

A new version of the Digital PowerLine technology (DPL 1000) was launched on March 18, 1998 at the CeBIT ’98 exhibition in Hannover, Germany. Applications over DPL 1000 are planned to support bundled information and energy services. Examples include high-speed Internet access, multimedia, smart applications/remote control, home automation and security, on-line banking/shopping, data back-up, telecommuting, entertainment, and planned IP telephony.

The new Digital PowerLine solution consists of a network interface at the substation, a data unit on the side of the subscriber’s house, and a stand-alone PowerLine communications module. In addition, a complete software and management capability adds functionality and flexibility to the system. The total package provides a competitively positioned access network which integrates seamlessly into today’s WAN networks.

Today, NOR.WEB is announcing agreements with the following seven companies: Norweb Communications of the UK, Vattenfall and Sydkraft of Sweden, RWE and EnBW of Germany, Singapore Power, and EDON of the Netherlands.

NOR.WEB will utilize Nortel, and its associated joint ventures, as one of its primary, worldwide channels-to-market-leveraging Nortel’s extensive capabilities to integrate total network solutions.

Norweb Communications provides an extensive range of advanced voice and data services and has achieved significant success in providing resilient networks for businesses throughout the north west of the UK. The company plans to use power line technology to provide public access networks for residential customers in the region. United Utilities has a combined capability in water and waste water, electricity, gas and telecoms, employing 10,000 people worldwide with revenues of pnds. stlg. 2.4 billion in 1997. This new technology will strengthen its competitiveness as a multi-utility service provider.

Nortel works with customers in more than 150 countries to design, build and integrate their communications products and advanced digital networks. Customers include public and private institutions; Internet service providers; local, long-distance, cellular mobile and PCS communications companies; cable television companies; and utilities.
Nortel had 1997 revenues of $US15.5 billion and has approximately 73,000 employees worldwide.

SOURCE Northern Telecom Limited
/CONTACT: Frank McNally, 703-712-8374 or frank.mcnally@nortel.com, or Michelle Murray, 770-708-4434 or michelle_murray@nortel.com, both of Nortel/ /Company News On-Call: http://www.prnewswire.com or fax, 800-758-5804, ext. 122158/ /Web site: http://www.nortel.com/powerline/ (NTL. NT)

Environ Capital Forum NYC

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Press Release
March 31, 1998
Contact: Loch McCabe, Keith Raab
For immediate release
Environmental Capital Network
(313) 996-8387; (313) 996-8732 fax; ecn@bizserve.com

CAPITAL FORUM TO SHOWCASE PROMISING ENVIRONMENTAL TECHNOLOGY COMPANIES FOR INVESTORS

On June 3, 1998, the EAST COAST ENVIRONMENTAL CAPITAL FORUM will be held in New York City. The East Coast Environmental Capital Forum will capitalize on growing investor interest in industrial process, energy and other environmental technologies. The East Coast Environmental Capital Forum will introduce investors to selected companies commercializing technologies, products or services that enhance both productivity and environmental quality.

“Our Forums are a terrific opportunity for investors to meet selected companies and to network with other investors focused on the environmental and energy industries,” says Loch McCabe, Director of the Environmental Capital Network (ECN). Nearly sixty (60) individual, professional, institutional, and corporate investors or their representatives attended the Environmental Capital Network’s West Coast Environmental Capital Forum, held in San Francisco on January 30, 1998.

The companies that will present at the East Coast Environmental Capital Forum will be determined by a Business Selection Committee composed of investors familiar with the environmental and energy industries. The Committee includes: Ethan Stambler (Advent International Corporation), Nancy Floyd (Nth Power Technologies), Jud Hill (HSBC Securities), Stephen Lynch (R.S. Lynch & Company), William Osborne (Venture Investment Management Company), Ann Partlow (Rockefeller & Company), Robert Shaw (Arete Corporation), and John Quirk (Quirk Carson Peppet).

“Investors and companies want to use their time well, ” reports Ira Rubenstein, Executive Director of the Environmental Business Association of New York State, Inc. “Investors want top quality deals. Companies want exposure to investors who understand their business. This environmental capital forum creates value for both investors and companies.”

Interested individual, professional, institutional and corporate investors should contact the Environmental Capital Network at 313-997-8387 or ecn@bizserve.com for registration information. Space is limited and advanced registration is strongly suggested.

The Environmental Capital Network (Ann Arbor, MI) and the Environmental Business Association of New York State, Inc. (Troy, NY) are organizing the Forum. The Environmental Capital Network (ECN) is a service that introduces investors to emerging and expanding environmental technology companies raising capital. ECN is a program of the Center for Environmental Policy, Economics and Science, a not-for-profit corporation. The Environmental Business Association of New York State, Inc. is a trade association that provides networking and educational resources to the environmental industry.

MC Power Seeking Strategic Partners

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MC Power is quietly looking for strategic business partners to participate directly with them in the commercialization of molten carbonate fuel cells. MC Power plans to concentrate on building the fuel cell stack based on their proprietary technology, and have others do balance of plant fabrication and system assembly, and marketing, sales, distribution, and service. They’re also looking for preferred equipment and materials supplier arrangements.

The company has a detailed business plan which involves several stages leading up to operation of a number of commercial prototype generators in 2000 and 2001, and manufacturing capability for delivery on commercial orders in 2002. They believe that their extensive intellectual property (patents and know-how) puts them in a good position to provide electricity at a levelized cost of 5.5-7 cents/kwh, below the forecast average price paid by commercial users; with superior environmental performance; and with advantages for the restructured marketplace (small scale and cogeneration).

There are many attractive market segments: utilization of waste gases from industrial processes, landfill and water treatment plants; commercial and light industrial users, distributed generation on networks; and international markets.

MC Power is currently owned 51% by IGT, and 24.5% each by Bechtel and Ishikawajima-Harima Heavy Industries. Notably, the company will offer ownership positions, and the opportunity to invest at pre-IPO valuations.

A number of utilities, including one or two UFTO members, are already members of the Alliance to Commercialize Carbonate Technology, who will be notified of these developments. The company has a confidential “Partnering Opportunity” memorandum which presents a broad summary of the plan described here.

Contact: Lee Camara, President
630-986-8040 x151, fax 630-986-8072, lee_camara_mcpower@compuserve.com

Sandia: Critical Infrastructure

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Energy and Critical Infrastructures
(Notes from UFTO visit to Sandia 12/97.)

Sam Varnado, Director
Energy and Critical Infrastructure Technology Center
505-845-9555, sgvarna@sandia.gov

Sandia is at the forefront of the big wave of attention currently being paid to “critical infrastructure surety” as it impacts national security. (Surety means “assurance”, and encompasses safety, integrity, authenticity, security, reliability, and technology.) Coming at the issue from a long background in systems analysis in the nuclear energy and weapons programs, they’ve emerged as a major player. Their experience in probabilistic risk assessment (PRA) is seen as directly translatable to infrastructure systems analysis. Since it is impractical to define threats, the approach is “consequence based”, as a means to determine why and where protections are required. It begins by identifying consequences that must be avoided, and then finds the system failure modes that could lead to them.

Sandia supported the President’s Commission on Critical Infrastructure Protection (PCCIP), which has an extensive website (http://www.ppcip.gov) featuring the complete text of their major report issued in October 1997. An Interim Group is continuing the Commission’s work. Also, the National Security Council is heading another interagency group that is drafting a Presidential Decision Directive to assign responsibility for the different infrastructures to the different agencies (due to be released soon).

The PCCIP report identifies the electric power grid as one of the most critical infrastructure sectors, notably in terms of the high degree of interdependence and interconnectedness of power with all the other sectors: telecommunications, finance and banking, oil and gas distribution, transportation, and vital human services (e.g. banking depends on information systems which depend on power). The power grid is very susceptible to physical and cyber threats, the latter especially in light of the increasing role of computers in the hardware, markets and financial dealings of the industry.

There is also a high degree of concern over the uncertain implications of utility industry restructuring. The transition from regulated rate based monopolies to competitive energy markets will most certainly impact reliability of service and vulnerability to disruption. Existing reliability models are not capable of accurately reflecting the issues that will arise.

Safety and Reliability of Nuclear Systems

Nestor Ortiz, Director, Nuclear Energy Technology Center,
505-844-0955, nrortiz@sandia.gov

For the DOE Nuclear Energy Program, there is research in Plant Lifetime Improvement, Aging of Reactor Components, and Instrumentation and Control Upgrade.

Sandia developed and maintains several noteworthy PRA codes. To mention some of them:
– MELCOR is used internationally and by the NRC. Modeling fully integrated engineering systems, it simulates the propagation accident to consequences. (U.S. utilities use MAP).
– CONTAIN is a research and design certification tool for containment systems
– RADTRAD design basis dose calculations for NUREG 1475. Revised baselines may eliminate the need for some equipment and maintenance procedures.

¥ Loss of Off Site Power (LOSP)
Of particular note, Loss of Off Site Power (LOSP) studies have led to major concerns over the potential impact of restructuring. In the PRA safety analysis of a nuclear power plant, the probability of loss of offsite power (i.e. power on the grid) is a very important factor. Plant safety systems are stressed by LOSP events, contributing over time to increased probabilities of malfunctions (e.g. resulting in higher probabilities of a loss of coolant accident).

While grid reliability has generally been excellent (

At the same time, Sandia has extensive experience and has developed a Generic Network Reliability Analysis Toolset, which is extremely effective for analysis telecomm networks. However, preliminary efforts to investigate the applicability of this model indicate that it is not immediately extensible to networks with direction and capacity constraints inherent in bulk power grids.

Contact Dennis Berry, 505-844-0234, dlberry@sandia.gov

Electricity Interdependencies – Estimating Economic Risks

Sandia has surveyed existing economic risk models to see if they can be usefully applied to estimate impacts of electric power disruptions.
– Lifeline LLEQE — effects of earthquake, for insurance
– FEMA – consequence assessment tool
– Electric Sector — 44 different models
– NDAC – telecom

They chose ENERGY 2020, the most recent incarnation of the Dartmouth (“Club of Rome” and FOSSIL 89) systems dynamic modeling approach, which has been used by EPA to analyze effects of green house gases on the electric system. It is “agent-based” and adaptable, and is available for free.

It feeds into REMI, a commercial (expensive!) dynamic regional macro-economic model. In preliminary runs with the Texas grid study results, it showed clearly that regions could experience permanent loss of jobs and increased costs. Future work will include use of Sandia’s own ASPEN model, an agent-based simulation of the US economy.

Contact Diane Marozas, 505-844-5504, dcmaroz@sandia.gov

Impacts of Storage on National Grid Reliability

Storage on the power grid can be seen in several different lights: 1. as a source of peak supply; 2. as a load and demand-side management option, and 3. as a means to render renewable generation more reliable from a systems operation perspective. Sandia has just completed an initial scoping study relating the 3rd option, to develop recommendations for how modeling methodologies need to be enhanced in order to address the question. In particular, the NEMS model could be used for such analyses with some modifications. (NEMS is DOE/EIA’s general equilibrium model of the national energy system. It’s Electricity Market Module doesn’t currently have the capability to model storage on the national grid.)

“Modeling of Battery Energy Storage in the National Energy Modeling System”,
SAND97-2926, Dec 1997

Contact Paul Butler, 505-844-7874, pcbutle@sandia.gov

Vital Issues Panel

Sandia uses its own “Vital Issues Panel” methodology to identify strategic issues in areas of national importance, particularly where there is a potential for Sandia to make contributions from its technological capabilities. Topics have included Global Climate, Environmental Security (i.e. the environment as a national security issue (e.g. effluents used aggressively, destabilization potential in Eastern Europe, terrorist targets, etc.) Infrastructure has been examined in two case studies, Critical Issues and Vulnerabilities in the Electric Sector, and separately, Vulnerabilities of the North American Power Grid.

Critical Issues and Vulnerabilities in the Electric Sector

To study vulnerabilities associated with the Electric Sector, Sandia convened a panel of experts representing the electric utility sector(April 1997). The group and identified critical issues and discussed how technology can help address those issues. They determined the top eight most critical issues arising from industry restructuring. In priority order, they are:

– Management and ownership of data streams
– The importance of consumer choice
– Competitive market pricing systems that will determine the mix of options
– Environmental issues
– State/federal role in collaborative and strategic research
– Integration of the national electric grid
– Incentives for keeping distribution systems up to date
– Accelerated retirement of a significant amount of generating capacity.

The panel also discussed the past, present and future of utility R&D, and ranked federal and private R&D spending priorities:
– Federal: Integration of the national grid and environmental issues
— Private: Importance of consumer choice, management and ownership of data streams, and environmental issues.

A concern remains whether the utility participants were sufficiently representative of the industry, and whether they – or the industry – appropriately estimate the importance of broader security issues, as compared with individual business concerns (e.g. with data ownership and dividing of system responsibilities). The Sandia team is anxious to have greater involvement from the industry in these efforts.

The discussions are summarized in the report: SAND97-1659, August 1997
Contact Arnie Baker, 505-284-4462, abbaker@sandia.gov

North American Power Grid (NAPG)

In April and June 1997, panels attended by stakeholders from government, industry and academe discussed vulnerabilities associated with the NAPG. The first panel was tasked to develop a mission statement and to define criteria by which risks and threats could be identified and prioritized. The second panel identified and defined categories of risk to the NAPG and assessed their relative importance, based on the groundwork laid by the first group.

The overall results:

–Criteria: Likelihood, Consequence, Timeframe, Cost/Benefit

–Risks: In rank order of importance
– Unrecognized risks embedded in new technologies and operating structures
– “Tragedy of the Commons” *
– Physical Threats and non-natural disaster
– Shorter time horizons driven by cost reduction
– Reliability and liability implications of reregulation
– Cyber threats

*”Tragedy of the Commons” (a term originated by Garrett Hardin his classic 1968 article in Science Magazine), is the idea that no single actor has enough concern for the whole system, but each has the ability and self-interest to overtax available resources. In the context of the power grid, obligation to serve and cooperation are being replaced by competition and opportunism.

A partial outline of the results are available at: http://www.iGAiA.sandia.gov
It hasn’t been decided yet whether the report will be released outside Sandia, in view of proprietary information it contains.

Center for System Reliability
http://reliability.sandia.gov

Contact Robert Cranwell, 505-844-8368, rmcranw@sandia.gov

Sandia technologies and expertise:
Modeling, simulation, optimization, maintenance strategies, network reliability/vulnerability, risk management, sensitivity/uncertainty analyses, human factors/human reliability, life-cycle cost analysis, software reliability, prob. risk assessment.

Applied to:
Power Generation, telecommunications, transportation, health care, equipment

Sandia has done analyses for many large corporations, e.g., design for reliability; predict and optimize impact of upgrades; optimization of spares inventory, etc.

Reliability Analysis Software Packages
Reliability enters into every phase of a product life cycle, from concept to design to production and operation to phase-out. Sandia has developed computer models to support the entire reliability engineering cycle.

WinR –Over 100 copies sold, available on a commercial basis from Sandia (they’re looking for a vendor). PC based reliability modeling and analysis provides a “dashboard” showing status of system components and performance.

Arramis – PRA for larger systems

WinR-PdM — Predictive Maintenance — combine real time sensor data with WinR for a dynamic view of component aging and overall system reliability. Demo at Allied Signal on a flexible manufacturing system

CRAX — The CassandRA eXoskeleton (CRAX) is a new reliability analysis tool that is being developed at Sandia National Laboratories to support the Materials Aging and Reliability Program (another key capability at Sandia is the detailed understanding of the physics of aging phenomena–fatigue, fracture, corrosions, etc., which have myriad and complex implications for systems reliability).

There are three major elements to CRAX:

Analysis Engine (Cassandra)
User Interface (Tcl/Tk GUI)
Physical Model (User Supplied)

The Cassandra uncertainty analysis engine consists of a number of software routines which permit the user to select a variety of methods for including uncertainty in their analyses. Cassandra is CORBA compliant and platform independent permitting easy interface with many of the new engineering design and analysis software packages. Existing uncertainty analysis techniques include a variety of Monte Carlo and analytically based approaches. The specific methods are constantly being updated and improved.

In addition to the CORBA interface structure, access to the Cassandra uncertainty analysis engine is also available via a Tcl/Tkgraphical user interface. There is also an effort to permit this interface to be accessed through a WWW browser. This will greatly aid in access to the analysis software within the using community.

The final element of CRAX is the physical model. A major decision early in the development of CRAX was the decision to not include any physical modeling tools. Rather than develop a new modeling tool (e.g. finite element model or fault tree tool) it was decided to let the engineer rely on the existing tools that they were comfortable with and had confidence in. While not the ideal situation in terms of analysis speed, it was felt that for the engineers to become comfortable with incorporating uncertainty into their deterministic models, we did not want to stretch their belief system too far. Hence the reliance on existing, deterministic analysis tools and the reference to CRAX as an exoskeleton. Within CRAX is the capability to either recompile the existing software into the tool, thereby significantly increasing computational efficiency, or rely on ‘hand-shaking’ between the CRAX program and the existing software. TheTcl/Tk GUI handles either of these situations very easily.

David G. Robinson; 505-844-5883, drobin@sandia.gov

Strategic Surety & Risk Management

Contact Laura Gilliom, 505-844-9104, lrgilli@sandia.gov

(Surety means “assurance”, and encompasses safety, integrity, authenticity, security, reliability, and technology.)

(The following discussion is extremely sketchy–intended only to bring identify some of these subject areas and to highlight Sandia’s involvement and expertise.)

This program addresses itself to the state-of-the-art of “surety”, bringing together many of Sandia’s core capabilities. It’s overarching goal is to bring risk and reliability analysis from its current statistical foundations to become a predictive capability. “Consequences” are the starting point, as mentioned earlier, and “interdependencies” are a major theme. The work proceeds by combining what is done at the level of engineering design codes with analyses of scenarios for risk.

Risk Management is broadly defined as a management tool that encompasses these different but closely related activities:
1. Identification of hazards associated with a technical system
2. Determination of the risks (consequences and likelihoods) of those hazards.
3. Reduction of risks to acceptable levels through appropriate design and control measures.
4. Thorough documentation of the above 3 activities.
5. Continuing reevaluation to improve the system or solution.

At Sandia, several hundred professional staff apply these activities in 8 major areas :
– Environment and environmental restoration
– Information systems
– Nuclear Reactors
– Physical Security
– Production and Manufacturing
– Transportation
– Waste Management
– Weapons

To realize benefits of overlapping interests, these staff participate in an internal organization of risk professionals at Sandia, called Sandia’s International Institute for Systematic Risk Studies (SIIRS, or “scissors”).

–High Integrity Software
Abstract Synthesis Transformation — make short pieces of code that are “provably correct.”
Software Event Execution Reliability (SEER) involves a math overlay to be sure that sequences occur correctly.

–Information Assurance- Cryptography
Most methods of cryptography involve the use of a key and function. Sandia has developed a new approach to split the function, so no one person can have everything.

Sandia is the only DOE lab allowed to do R&D on cryptography, primarily for use and control of nuclear weapons. They have a major crypto library which is widely licensed.

–Devices–safe and secure. Doing new research to have confidence in the behavior of a system when a “chip makes a decision”.

–Authentication Center of Excellence (ACE) for banking, devices and software…physical tokens of authenticity; smart cards and highly secure smart card readers–systems for the Defense Department. (Think about SCADA systems and how susceptible they are to outside interference and control!)

–Information Warfare assessments–information and physical security. Imagine the havoc of an all out cyber war, i.e. an attack from an enemy country or syndicate, not just hackers.

–Auctions – imagine a new player who wants to disrupt it–gray areas between gaming the system and dishonesty….not just an issue of terrorists, but of businesses vulnerable to other players. How can bids/contracts be authenticated and when and how can they be disowned or repudiated?