Posts

Hybrid Power Plant (SOFC and MTG)

At the Palm Springs Fuel Cell Seminar (Nov 19), Edison Technology Solutions (ETS) announced plans to demonstrate and lead the commercialization of the first 250 kW “hybrid” generating plant integrating a fuel cell with a microturbine generator. The first unit, with a 200 kW pressurized SOFC and a 50 kW microturbine, will be installed in mid-1999 at the National Fuel Cell Research Center (NFCRC) at UC Irvine. Commercial launch is anticipated for 2001.

The hybrid plant will operate at an efficiency of 60 percent and a cost of $1000/kW, i.e. at lower capital costs than a standalone fuel cell, and with twice the efficiency of a standalone micro-turbine.

A variety of hybrid concepts have been discussed for several years by DOE. ETS is supporting an approach using the pressurized Siemens-Westinghouse tubular SOFC. It uses the microturbine compressor to pressurize the fuel cell to approximately three atmospheres. Exhaust gas at 1,500 deg F from the fuel cell is then used as the motive force for the microturbine, driving both its compressor and generator. While the plant at the NFCRC will run on natural gas, it is flexible to operate with other fuels. The plant has no detectable nitrogen oxide emissions, and greatly reduces carbon dioxide emissions.

Hospitals, hotels, universities and other customers with high load factors are seen as likely users of the hybrid power plant. ETS will work with utilities and energy service companies to commercialize and deploy the technology.

ETS is offering a proposition to utilities to become part of a focused fast-track commercialization program. From 5-10 participants will provide development funding in exchange for access to technical information and priority rights to commercialization opportunities. Based on earlier discussions with several prospective customers for the program, ETS is proposing a graduated series of commitment levels. Companies which commit to the highest level now would be first in line for commercialization rights.

By design, the program will remain flexible as to which brand of microturbine can be used, though the first plant is planned around a Northern Research unit. For the fuel cell, the entire program is integrally connected to the Westinghouse SOFC.

ETS has an exclusive license to a recent patent with broad claims focused on high speed turbines and pressurized fuel cell operation. ETS also has exclusive worldwide marketing rights to the hybrid power plant (based on the Westinghouse SOFC) up to 500 kW.

Contact: Jaime Medina, Edison Technology Solutions
626-815-0516, jmedina@edisontec.com
http://www.edisontec.com

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US 5811201: Power generation system utilizing turbine and fuel cell
Inventor(s): Skowronski; Mark J. , Walnut, CA
Applicant(s): Southern California Edison Company, Rosemead, CA
Issued/Filed Sept. 22, 1998 / Aug. 16, 1996
Abstract: A system for generating electricity comprises a fuel cell, a heating stage, and an integral, power generator. The power generator comprises a compressor, an electricity generator and a turbine. Hot exhaust gas from the fuel cell is used for driving the turbine, which in turn drives the generator and the compressor. Both the fuel cell and the generator produce electricity. The compressor is used for compressing air for use in the fuel cell. A portion of the waste heat from the turbine drive gas is used for preheating the air utilized in the fuel cell.

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(Edison Technology Solutions, a non-regulated company of Edison International, develops and markets new technologies, products, and services for the emerging energy and electricity marketplace.)

New Carbon Management Report

DOE has assessed fundamental research needs in carbon management through a series of workshops. A new report based on information from those workshops and other background materials is available on the Internet. The report identifies targets of opportunity for fundamental research likely to lead to the development of mid- to long-term solutions for reducing carbon dioxide concentrations in the atmosphere.

It covers five topic areas:

1) capture of carbon dioxide, decarbonization strategies, and carbon dioxide sequestration and utilization;
2) hydrogen development and fuel cells;
3) enhancement of the natural carbon cycle;
4) biomass production and utilization; and
5) improvement of the efficiency of energy production, conversion, and utilization.

The report is down loadable in a .pdf format from the Office of Science (Energy Research) website under the link in the website entitled “Carbon Management Research Needs”. http://www.er.doe.gov/

Contact: John Houghton, (301) 903-8288, John.Houghton@oer.doe.gov

Environ. Capital Forum, Chicago Oct 22

–> UFTO Utilities are especially invited to attend this event. Be sure to pass this along as appropriate in your company

Here is a notice for a venture forum in Chicago the week after next. Attendance is strictly limited to “qualified investors”.

—> Also note below a separate “invitation only” event –project financing.

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For more information about the ECN (Environmental Capital Network), check their website at http://www.bizserve.com/ecn

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Environmental Capital Forum — Promising Technology Companies

On October 21-22, 1998, the East Coast Environmental Capital Forum will introduce investors to selected companies commercializing a range of industrial process, energy, and other environmental technologies, products and services. The Forum will feature fourteen early- and expansion-stage companies that were selected based upon the strengths of their technologies, their markets and their management teams.

Congress Plaza Hotel and Convention Center

A Reception hosted by Coopers & Lybrand LLP will be held at the same location during the evening of October 21, 1998. The Forum will last from 8 am to 3 pm on October 22, 1998.

This specialized forum will capitalize on a growing investor interest in innovative technologies that enhance both industrial productivity and environmental quality. It will introduce the following promising companies to investors, and provide investors with opportunities to network with each other. A summary of the presenting companies by sector is below:

· Firm is commercializing an innovative, zero-emissions, high energy fuel cell technology.
· Firm is developing a leading electrochromic technology for building & transportation windows.
· Firm is expanding production of an electric motorbike.
· Firm is commercializing unique glazing material that reversibly turns windows from clear to white.

· Firm is expanding production of robotic metal working systems for industrial markets.
· Firm is commercializing novel thermal induction technology to treat and dispose of medical waste.
· Firm is producing advanced composite materials used in the construction, building trade and furniture industries.
· Firm is producing aerobic bio-reactor that pre-treats wastewater in food processing and other industrial settings.
· Firm is building plant to convert waste plastic into high quality diesel fuel.

OTHER TECHNOLOGIES, PRODUCTS AND SERVICES

· Firm is commercializing revolutionary process to remove hazardous organic contaminants from groundwater.
· Firm is commercializing environmental software for power facilities, airports and similar institutions.
· Firm is expanding production of composite reinforced plastic materials utilizing fiber waste.
· Firm is commercializing innovative characterization technology specifically adapted for nuclear waste.

The Forum’s Business Selection Committee was composed of prominent investors actively involved in the industry, including Ms. Stacy Gray of First Analysis Corp. (Chicago, IL); Mr. Ethan Stambler of Advent International Corporation (Boston, MA); Mr. Tony Biddle of Zolfo Cooper Capital (New York, NY); Mr. Nicholas Parker of Technology Development Corp. (Toronto, Ontario); Mr. Tony Lent of EA Capital (New York, NY); Mr. Samuel Hope of Asset Renewal Services (Milwaukee, WI); Mr. Bradley Whitehead of CoreResources (Cleveland, OH), Mr. Paul Purcell of Enertek Partners (Columbus, OH), and Ms. Dawn McGee of Global Partners LLP (Sebastopol, CA).

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Bio-Manufacturing Project Financing Opportunities
— Invitation only — Contact ECN for details.

October 21, 9:00 am to noon same location as above
Four presenting companies are seeking project finance capital. They have received earlier venture investment support from the AARC.

AARCC is the Alternative Agric. Research and Commcialization Corp., a venture investment subsidiary of the US Dept. of Agriculture that invests in startup companies that use agricultural waste materials in manufacturing.

12th Ann. Conf Fossil Energy Materials

Just obtained the program for this upcoming conference..
http://www.ornl.gov/fossil/FEP_WCon.html

Twelfth Annual Conference on Fossil Energy Materials

Knoxville, Tennessee
May 12-14, 1998

The Twelfth Annual Conference on Fossil Energy Materials will review the work performed by the Fossil Energy Advanced Research and Technology Development (AR&TD) Materials Program. The AR&TD Materials Program provides needed long-range research in areas not addressed by the Department of Energy line programs and focuses on the unique needs of fossil energy systems which cannot be met by currently available materials. The intent of the AR&TD Materials Program is to provide major materials developments that can dramatically affect the feasibility of some fossil energy systems concepts. Research is conducted at national and government laboratories, universities, and industrial research facilities.

Current research activities will be described in oral presentations and posters by the researchers working on the AR&TD Materials Program. These technical presentations will address research on ceramic composites, iron aluminide alloys, advanced high-temperature alloys, and functional materials such as inorganic membranes, filters, activated carbon absorbents, and solid oxide fuel cells. Several developments are in the demonstration and commercialization stage. The status of these technology transfer activities will be presented.

Conference Details
The Twelfth Annual Conference on Fossil Energy Materials, sponsored by the U.S. Department of Energy and ORNL, will be held May 12-14, 1998, at the Hilton Knoxville, 501 West Church Avenue, Knoxville, Tennessee. Your registration fee of $150 (in U.S. dollars) includes: continental breakfast, refreshment breaks, a buffet reception, the extended abstracts, and a copy of the proceedings mailed to the registrants after the meeting.
The registration fee of $150 (in U.S. dollars) is due on or before May 1, 1998 and is non-refundable after May 1. Credit cards are not accepted.
A block of rooms is reserved until April 15, 1997, at the Hilton Knoxville (423-523-2300) at a rate of $64 per night plus tax. When making your reservations, please mention the Conference on Fossil Energy Materials.
For more information, please contact the conference coordinator, Judy Fair, at 423-576-7270 (fax: 423-574-5812).

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PRELIMINARY PROGRAM
CONFERENCE ON FOSSIL ENERGY MATERIALS
Knoxville, Tennessee
May 12-14, 1998

SESSION I – Ceramic Composites and Functional Materials

Tuesday, May 12, 1998

7:00 Registration and Continental Breakfast
8:00 Welcome and Introductory Remarks, Program Managers, DOE and ORNL
8:20 Keynote Address – Marvin I. Singer,
Sr Advisor for Advanced Research,Office of Fossil Energy, DOE
8:40 Invited Speaker – Deborah Haught, Program Manager
Ceramic Fiber-Reinforce Ceramic Composites,
Office of Industrial Technologies, DOE
9:00 Development of Oxidation-Resistant Composite Materials and Interfaces
R.A. Lowden, ORNL
9:30 Environmental Barrier Coatings
J. A. Haynes, ORNL
10:00 BREAK

10:20 Corrosion Protection of SiC Based Ceramics with CVD Mullite Coatings
V. Sarin, Boston University
10:50 Iron-Aluminide Filters for IGCCs and PFBCs
P. F. Tortorelli, ORNL
11:20 Exposure Testing of Materials at Galatin Power Plant
J. L. Blough, Foster Wheeler
11:50 LUNCH

1:15 Development of Nondestructive Eval Methods for Structural Ceramics
W. A. Ellingson, Argonne National Lab
1:45 Mechanical Performance of Hi-Nicalon/CVI-SiC Composites with Multilayer SiC/C Interfaces
W. A. Curtin,Virginia Polytechnic Institute and State Univ
2:15 Modification of Slags and Monolithic Refractories to Reduce Corrosion Rates
J. P. Hurley Univ of N Dakota Energy & Environ Research Center
2:45 BREAK
3:00 Corrosion and Mechanical Properties of alloys in FBC and Mixed-Gas Environments
K. Natesan,Argonne National Lab
3:30 Solid State Electrolyte Systems
L. R. Pederson, Pacific Northwest Lab
4:00 Ceramic Membranes for High Temperature Hydrogen Separation
D. F. Fain, East Tennessee Technology Park

4:30 ADJOURN

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SESSION II – Ceramic, New Alloys, and Functional Materials

Tuesday, May 12, 1998
5:30 – 7:30 p.m.

POSTER PRESENTATIONS – BUFFET RECEPTION

Development of Scale-Up CVI System for Tubular Geometries
T. M. Besmann, ORNL
Mass Transport Measurements and Modeling for Chemical Vapor Infiltration
T. L. Starr, Georgia Institute of Technology
Thermal Cycling Characteristics of Plasma Synthesized Mullite Films
I. Brown, Lawrence Berkeley National Lab
A Carbon Fiber Based Monolithic Adsorbent for Gas Separation
T. D. Burchell, ORNL
Mechanisms of Defect Complex Formation and Environmental-Assisted Fracture Behavior of Iron Aluminides
B. R. Cooper, West Virginia University
Study of Fatigue and Fracture Behavior of Cr2Nb-Based Alloys: Phase Stability in Nb-Cr-Ni Ternary Systems
P. Liaw, Univ of Tennessee
Weld Overlay Cladding With Iron Aluminides
G. M. Goodwin, ORNL
High Temperature Corrosion Behavior of Iron-Aluminide Alloys and Coatings
P. F. Tortorelli, ORNL
Electro-Spark Deposition Technology
R. N. Johnson, Pacific Northwest Lab
Poster
R. Walters, Albany Research Center
Oxide-Dispersion-Strengthened Fe3Al-Based Alloy Tubes
B. K. Kad, Univ of California at San Diego
Reduction in Defect Content of ODS Alloys
A. R. Jones, Univ of Liverpool
Low-Aluminum Content Iron Aluminum Alloys
V. K. Sikka, ORNL
Mo-Si Alloy Development
J. H. Schneibel, ORNL

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SESSION III –
Workshop on Materials for Separation Processes for Vision 21 Systems

Wednesday, May 13, 1998

7:00 Registration and Continental Breakfast

8:00 Speaker: William Fulkerson
President’s Committee of Advisors on Science and
Technology (PCAST) Energy R&D Panel – Chairman
Fossil Energy Committee
8:30 Speaker: Howard Feibus, Director
Office of Advanced Research, Fossil Energy, DOE
This year’s workshop will focus on separations issues particularly
as they apply to the FE Vision 21 concept. Although Vision 21 embodies
several technologies in yet-to-be-defined configurations, materials
for separations systems will be critical to any and all of the
possible technology elements of a Vision 21 plant. Separations process
include, among others, gas-gas separations, such as the separation of
hydrogen from synthesis gas or from carbon dioxide, air separation to
produce oxygen, and gas-solid separation devices, i.e., hot-gas
filters. Representatives from companies working on Vision 21
technologies will establish a commercial perspective for the
separations processes and materials required for these systems. The
objective of the workshop will be to establish the highest priority
materials developments for these separations systems, and determine
how well the AR&TD Materials Program is addressing these priorities.

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SESSION IV – New Alloys

Thursday, May 14, 1998

7:30 Registration and Continental Breakfast

8:00 Welcome and Introductory Remarks
8:10 Speaker:
John Stringer, Executive Technical Fellow
Strategic Science and Technology, EPRI
8:30 Development of ODS Fe3Al Alloys
I.G. Wright, ORNL
9:00 The Influence of Processing on Microstructure and Properties of Iron Aluminides
R. N. Wright, Idaho National Engineering Lab
9:30 Iron Aluminide Weld Overlay Coatings for Boiler Tube Protection in Coal-fired Low NOx Boilers
J. N. DuPont, Lehigh University
10:00 BREAK
10:15 Corrosion Performance of Iron Aluminides in Fossil Energy Environments
K. Natesan, Argonne National Lab
10:45 Effects of Titanium and Zirconium on Iron Aluminide Weldments,
G. R. Edwards Colorado School of Mines
11:15 Microstructure of Mechanical Behavior of Alumina Scales and Coatings
P. F. Tortorelli ORNL
11:45 LUNCH
1:15 Investigation of Austenitic Alloys for Advanced Heat Recovery and Hot-Gas Cleanup Systems
R. W. Swindeman, ORNL
1:45 Fireside Corrosion Testing of Candidate Superheater Tube Alloys, Coatings, and Claddings – Phase II
J. L. Blough, Foster Wheeler Development Corporation
2:15 Processing of Advanced Austenitics for Recuperator Service
P. J. Maziasz, ORNL
2:45 Ultrahigh Temperature Intermetallic Alloys
C. T. Liu and M. Brady, ORNL
3:15 SHS Processing and Properties of Intermetallic Alloys and Composites
W. Riley,Albany Research Center
3:45 ADJOURN

EPRI-GRI-DOE Fuel Cell Workshop

This notice just came in from the DOE Fuel Cell forum

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If you’re interested in fuel cells you should be on this email list!

To subscribe:
http://www.fetc.doe.gov/products/power/fuelcells/subscribe.html

For a good overview of fuel cells and the DOE program, see:
http://www.fetc.doe.gov/products/power/fc.html
————————————

*** I have confirmed that THIS MEETING IS OPEN TO EVERYONE ****

Joint EPRI-GRI-DOE Workshop

(Similar to DOE’s Annual Fuel Cell Contractors Review Meeting)

May 18-20, 1998

Sir Francis Drake Hotel
450 Powell Street
San Francisco, Ca.
(415) 392-7755 or 1-(800) 227-5480
Rate for workshop block of rooms is $149.00 (through 4/20/98)

Registration Fee of $200.00 includes proceedings, continental breakfasts and
luncheons

Conference Contact Person:
Melita Guellert, EPRI Conference Manager
(650) 855-2010 MGueller@epri.com

Technical Info:
John B. O’Sullivan, EPRI (650) 855-2292
AGENDA

Monday
Welcome/Introduction 1:00 – 1:15 PM
ONSI (PAFC) Status 1:15 – 1:40 PM
M-C Power (MCFC) Demos 1:40 – 2:05 PM
Energy Research Corp. (MCFC) Demos 2:05 – 2:30 PM
Westinghouse (SOFC-CT) Demos 2:30 – 2:55 PM
BREAK 2:55 – 3:20 PM
A. D. Little Inc. Fuel Processing 3:20 – 3:45 PM
Hydrogen Burner Technology Fuel Processing 3:45 – 4:10 PM
SOFCo Fuel Processing 4:10 – 4:35 PM
Northwest Power Systems Fuel Processing 4:35 – 5:00 PM

Tuesday
ERC MCFC 8:00 – 8:25 AM
M-C P MCFC 8:25 – 8:50 AM
Argonne National Lab MCFC 8:50 – 9:15 AM
Westinghouse SOFC Research 9:15 – 9:40 AM
BREAK 9:40 – 10:05 AM
ZTEK SOFC Systems 10:05 – 10:30 AM
TMI SOFC Systems 10:30 – 10:55 AM
AlliedSignal SOFC Systems 10:55 – 11:20 AM
Ceramatec/SOFCo SOFC Systems 11:20 – 11:45 AM
LUNCH 11:45 – 1:15 PM
University of Utah (Virkar) SOFC Research 1:15 – 1:40 PM
U. of Missouri (Anderson) SOFC Research 1:40 – 2:05 PM
U. of Pennsylvania (Worrell) SOFC Research 2:05 – 2:30 PM
Pac NW Natl. Lab (Armstrong) SOFC Research 2:30 – 2:55 PM
Break 2:55 – 3:20 PM
Georgia Tech (Liu) Proton Cond. Research 3:20 – 3:45 PM
Cal Tech (Haile) Proton Cond. Research 3:45 – 4:10 PM
Jet Propulsion Lab Direct MeOH. Research 4:10 – 4:35 PM
Proton Energy (Regen FC) PEMFC 4:35 – 5:00 PM

DINNER SPEAKER David Rohy CA Energy Commission

Wednesday
Ballard Stationary PEM 8:00 – 8:25 AM
H-Power Stationary PEM 8:25 – 8:50 AM
Analytical Power Stationary PEM 8:50 – 9:15 AM
Plug. Power (Ernst) Stationary PEM 9:15 – 9:40 AM
BREAK 9:40 -10:05 AM
3M Membrane Tech. 10:05 – 10:30 AM
DuPont Membrane Tech. 10:30 – 10:55 AM
F-M Membrane Tech. 10:55 – 11:20 AM
Gore Membrane Tech. 11:20 – 11:45 AM
Ballard Automotive PEM 1:15 – 1:40 PM
ONSI Automotive PEM 1:40 – 2:05 PM
Plug. Power (Ernst) Automotive PEM 2:05 – 2:30 PM
AlliedSignal Automotive PEM 2:30 – 2:55 PM
BREAK 2:55 – 3:20 PM
ElectroChem PEM Research 3:20 – 3:45 PM
Discussion/Comments 3:45 – 4:30
ADJOURN 4:30 PM

Hybrid power system splits petroleum fuel for fuel cell and IC engine

Subject: UFTO Note – Hybrid power system splits petroleum fuel for fuel cell and IC engine
Date: Mon, 21 Jul 1997
From: Ed Beardsworth

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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
————————————————————-

Hybrid power system splits petroleum fuel for fuel cell and IC engine

Procyon Power Systems Inc is developing an innovative hybrid power plant that combines an internal combustion engine and a fuel cell. The system features a unique proprietary fuel processor that extracts a portion of the hydrogen from the hydrocarbon fuel for use in the fuel cell. The remaining carbon-rich fuel is used in the IC engine.

As a power system for vehicles, the fuel cell delivers high power, while the IC engine handles the base loads. This combination gives an overall fuel efficiency about 2 1/2 times current vehicle engines, coupled with ultra-low emissions. The company has filed a patent application for this hybrid system concept. In addition to vehicle applications, Procyon is also exploring use of the system for stationary distributed power generation.

The fuel processor uses pyrolysis (thermal decomposition in the absence of oxygen) to split the hydrocarbon liquid fuel, and avoids the need for complex gas separation and filtering. A patent application has been filed for the processor.

This breakthrough technology was proven in tests at Pacific Northwest National Lab in December 1996, which showed that 20% of the fuel could be converted to hydrogen without coking. The process heat requirement is a small fraction of the total fuel energy content. As it converts only a portion of the fuel to hydrogen, the process is much cheaper and simpler than partial oxidation or steam reforming.

The Atkinson cycle engine has greater thermal efficiency at low loads than conventional Otto engines. (Otto engines use identical compression and expansion ratios and have a 10 to 1 peak to average power rating, giving better efficiency at full power. In the Atkinson cycle, the volumetric expansion ratio is much larger as compared with the compression ratio, resulting in the best efficiency at a fraction of peak load.)

Thus the Atkinson engine doesn’t have the wide power range of the Otto cycle, but this is exactly what is wanted to provide base load in this hybrid system approach. In a timely confirmation of Procyon’s approach, Toyota recently announced that its new production battery-hybord will also use an Atkinson cycle IC engine.

The company is seeking investment capital to continue its development.
Contact:
Gary Noland, President
Ambrose Manikowski, Vice President
Allen McKee, CFO

Procyon Power Systems Inc.
Alameda CA 510-864-3179 fax 510-864-3180
procyonpwr@aol.com

Climate-Change, Fuel-Cell, Cost-Sharing, Grants

Subject: UFTO Note – Climate-Change, Fuel-Cell, Cost-Sharing, Grants
Date: Thu, 02 Jan 1997 16:43:58 -0800
From: Ed Beardsworth

Hot off the wire, from Commerce Business Daily
(I fixed a lot of typos, and split it into paragraphs.)

————————————————————–
| ** 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
————————————————————–

CLIMATE CHANGE FUEL CELL PROGRAM

Category: B–Special Studies and Analyses–Not R&D (PROCUREMENTS)

Date Published: December 30, 1996

Contact: US ARMY ARDEC, TACOM, AMSTA-AR-PCW-B, BLDG. 10, PICATINNY ARSENAL NJ 07806 POC Christine Bernosky email=cbernos, Contract Specialist, 201-724-2754, Paul Milenkowic, Contracting Officer,201-724-5391 (Site Code W15BW9)

Synopsis: CLIMATE CHANGE FUEL CELL PROGRAM SOL 066&&&-9612-0012 The U.S. Army ARDEC is planning a cost sharing program in the form of multiple grants in support of the Climate Change Fuel Cell Program. This program involves using fuel cells in power plants to reduce greenhouse gas emissions through the efficient use of fossil fuels. In an effort to reduce pollutants to the environment, stimulate commercialization of stationary fuel cell power plants, and utilize fuel cells in unique mission needs for DOD, Congress has established a grant program to support fuel cell demonstration projects.

The Climate Change Fuel Cell Program consists of installing, operating, and demonstrating a fuel cell. Applicants can utilize DOD or non-DOD sites; however, DOD installations must partner with a private entity. Priority will be given to those applicants who use a DOD installation. Foreign participation is limited to those entities which will provide power to a DOD facility within their national borders.

The applicant cannot be a developer of fuel cell technology or a fuel cell manufacturer, and the applicant’s chosen fuel cell power plant(s) must be manufactured in the U.S. Applicants who have existing, installed fuel cells at the site or who have placed an order for one prior to 26 September 1994 are ineligible. The applicant must identify the intended use of each power plant. Power plants purchased as factory packaged shall be full power tested prior to installation. An applicant shall identify the site (specific name of DOD installation, hospital, university, etc.) and the intended use at the time of proposal submission. Prior to installation, the specific location at the site must be identified.

The applicant may transfer the power plant to a third party for installation and operation. Prior to installation, the applicant shall be responsible for supplying local National Environmental Policy Act-related information to DOD and for assuring that its power plant(s) is (are) installed and operated in accordance with all regulatory requirements. Applicants must use a fuel cell manufacturer who has at least 2 megawatts (MW)/year manufacturing capability to support the project. Projects must be greater than 100 kilowatts (kW) and are anticipated to be below 400kW. The period of performance is three years at which time the project shall operate at a rated power.

The applicant shall provide a project schedule with each proposal. Applicants will be required to submit a summary report of the power plant installation and operational history upon successful completion of one year of power plant operation. The report will be consistent with the format provided.

The federal contribution will be $1,000/kW and shall not exceed 1/3 of the total cost of the program, including unit cost, installation, an pre-commercial operation. If partnering with a DOD installation, the remainder of the costs shall be borne by the private partner and payment of the grant will be made to the private entity. There may be multiple grants to each applicant, although Th. Government reserves the right to limit the number of plants to an applicant to provide for customer and functional diversity. Payment of 80% of the grant shall be made upon demonstrating that the unit operates at the unit’s maximum power capacity for 8 hours for the purpose identified in the project proposal. The remaining payment of 20% of the grant shall be issued upon submission of the final demonstration report. The proposal period for the Climate Control Fuel Cell Program grant ends 1 May 1997.

This Broad Agency Announcement is available from the World WideWeb Electronic Commerce Home Page called the Procurement Network (ProcNet) available at the following Web address: “http://procnet.pica.army.mil/””. (I-361 SN015533)

Technology Transfer Opportunities – Sandia

UFTO

PROPRIETARY

Final Report

Technology Transfer Opportunities in the National Laboratories

Sandia National Laboratories

Albuquerque, New Mexico

& Livermore, CA

July 1995

Prepared for:

Utility Federal Technology Opportunities (UFTO)

By:

Edward Beardsworth

Consultant

 

This report is part of a series examining technology opportunities at National Laboratories of possible interest to electric utilities

 

Contents:

 

1. Summary
1. Sandia Organization
2. Sandia Technologies & Programs
11. Sandia Contacts

 

This report is proprietary and confidential. It is for internal use by personnel of companies that are subscribers in the UFTO multi-client program. It is not to be otherwise copied or distributed except as authorized in writing.

 

Summary

This report details findings about technology and technology transfer opportunities at the Sandia National Laboratories (Sandia) that might be of strategic interest to electric utilities. It is based on visits to Sandia in March 1995, as part of the UFTO multiclient project.

Background

Noting the tremendous scope of research underway in the research facilities of the U.S. government, and a very strong impetus on the government’s part to foster commercial partnering with industry and applications of the technology it has developed, the UFTO program has been established as a multi-client study of the opportunities thus afforded electric utilities.

Sandia Organization

Sandia began in 1945 as a small part of Los Alamos Laboratory, and in 1949 became a separate laboratory managed by AT&T. (The University of California, which manages Los Alamos, did not want to become involved in the actual manufacture of weapons.) Due to AT&T’s culture and management approach, Sandia grew up with an organizational style similar to Bell Labs, and quite different from the other national labs. There is a line management structure, and from the beginning, a strong “industrial R&D” approach that emphasizes practical results and getting them into use.

AT&T has managed Sandia (as a public service, for $1 per year) from 1949 until 1993, when Martin Marietta won the bid to take over. Martin (now Lockheed Martin) has a subsidiary company called Sandia Corporation that manages the laboratory (similar to the arrangement at ORNL and INEL).

Sandia is located on Kirtland Air Force Base in Albuquerque, and at Livermore California (across the street from L. Livermore National Lab). Total staff number about 8500 people, with about 1000 in California. About 60% of the staff are in technical and scientific positions.

Managers of “directorates” or “centers” have a fair degree of autonomy, and report up to a “sector” vice president level which in turn report to Al Narath, the president and lab director.

The sectors include:

Defense Programs (the largest), which does engineering and design for weapons systems,

Energy & Environment, led by Dan Hartley, deals with all other areas of the Dept. of Energy, with programs in Applied Energy, Nuclear Waste Management, Environment, Nuclear Energy, and Energy Research.

Work for Others (other government agencies) also known as Systems Applications and Research & Exploratory Technology

Sandia has specific major cross-cutting initiatives in agile manufacturing, electronics, and advanced information processing.

A general point of information: each lab annually publishes an “Institutional Plan”, which is organized according to which DOE Program Office supports the work, not the lab’s own organizational structure. Thus a “mapping” between the two structures is required to be able to see the work of the groups within a lab.

Sandia Technologies & Programs

 

Covered in this section:

  • Combustion Research
  • Advanced Batteries and SupercapacitorsUtility Batteries/Storage/UBG
  • Renewables
  • Fuel Cells
  • Robotics
  • High Consequence Operations
  • High Performance Computing
  • Distributed Information Technologies (NII)
  • Sensors
  • Materials
  • Reliability/Decision Making
  • Micro SMES
  • HyMelt
  • High power switching

General Telephone # is (501) 844-5678
In Livermore, CA (510) 294-3000

Programs of greatest direct applicability to utilities are in the:
Applied Energy Program Dan E. Arvizu, Director 505-845-8336

 

Three major program areas:

1. Renewable Energy: solar thermal, PV, wind, geothermal, biomass

2. Energy Efficiency: utility energy management, materials & manufacturing processes, combustion technologies, transportation batteries, superconductivity

3. Fossil Energy: coal combustion, oil & gas production, strategic petroleum reserve
Industry collaborations involve many electric utility companies and manufacturers.

• Combustion Research Don Hardesty, Manager, Combustion Research 510-294-2321

Charles M. Hartwig 510-294-3047

Over 1000 Sandia employees are located in facilities in Livermore California, and operate several special facilities, one of which is the Combustion Research Facility, the only one of its kind in DOE. Can handle industrial scale burners to 3 million BTU/hour. It is a “user facility” and outside visitors and users are encouraged. Partnerships with industry include GM, Cummins and Beckman Instruments and many others. Developed a number of specialized flame/combustion observational, measurement and diagnostic techniques. Provided fuel blending strategies to midwest utilities to meet SOx requirements.

The Burner Engineering Research Laboratory is a user facility for industrial burner manufacturers, is booked for a year in advance. Wide range of studies include air toxics modeling

NOx program addresses measurement and prediction of NO formation in turbulent flames.

Sensors for steel industry for in situ measurement of CO and CO2 in furnaces.

Combustion properties of biomass derived fuels and char.

Laser and remote atmospheric sensing (invented Lidar).

The Engine Combustion Technology Program involves all the major car and engine makers, universities and other labs.

In Hydrogen, work in progress on combustion, engines, storage, and hydrides.

Publications: CRF News published bimonthly. Contact William J. MacLean, 510-294-2687

 

• Advanced Batteries and Supercapacitors

Electrochemical R&D for DOE is longstanding and diverse, meeting many needs for high quality and reliable systems for weapons programs, and working at the forefront in many nonweapons areas of technology. Lawrence Berkeley Lab is well known for fundamental research, and Sandia for devices, having supplied all the power supplies for nuclear weapons systems since the 1950s.

Until a reorganization on July 1, Sandia’s work in battery technology was part of a larger activity called the “Electronic Components Center”, which includes microelectronics, modules, optoelectronics, components and reliability. Full fabrication capability. [This Center could be a valuable resource for a utility’s customers in these industries. Ray Bair, Director, 505-844-1912.]

Battery programs now reside in the “Energy Components Center” (Joan Woodard, Director 505-845-9917) along with work in explosives and neutron generators, though personnel will continue their close coordination with the Electronics Center.

There are four battery development groups at Sandia, each with a different emphasis, but closely interrelated. The department heads form a coordinating team.

Dan Doughty Battery Programs 505-845-8105

Ken Grothaus Battery Research 505-844-1654

Dennis Mitchell Battery Development 505-844-8656

Paul Butler Testing Program 505-844-7874

(Full range of performance, abuse, failure, and qualification testing. Extensive facilities.)

 

– Work in Zinc/Silver Oxide, Sodium Sulfur, Zinc Air, Zinc Bromine, Advanced Lead Acid, Nickel Hydrogen, Nickel Cadmium, Lithium/Sulfur Dioxide, Supercapacitors

– USABC CRADA, with automakers, lithium rechargeable battery development and testing

– Implantable long life battery development for medical application

– Battery Technology Initiative — funds-in CRADA with 4 companies for consumer batteries

– Ultracapacitor — thin film to get 1000 F in a D cell.

– Reserve Batteries — primary energy sources; one-shot devices activated by external means. For weapons systems; not likely to have commercial application.

 

• Utility Battery Storage Program Paul Butler, 505-844-7874 Abbas Akhil, 505-844-3353

Battery technology development (Pb-acid with GNB, Sodium sulfur with Silent Power, etc.), modular systems (AC Battery/Delco), systems studies (SDG&E, Chugach, Oglethorpe, BPA), feasibility studies (SMUD, Chugach), test & demos (PG&E, Metlakatla Alaska, PREPA) subsystems engineering, integration, industry outreach.

Strictly electric power industry oriented. About half of budget goes to industry in heavily cost shared projects. Sandia sees utility applications as being very nearly ready for take off. (Phase 2 of “Opportunities” project just getting underway–needs industry participation! Phase 1 report available from Paul Butler.) Broad view of potential emphasizes T&D benefits, DSM and UPS/Power Quality applications, which don’t require very large scale demos. Problems with large scale installations leading to new approach to do smaller units that are flexible or transportable. More of a T&D asset like a transformer. Puerto Rico’s experience with 20 MW unit has them convinced to meet their estimated need of 100 MW with turnkey units.

 

Provide support to the Utility Battery Group (UBG)

[An excellent and very cost effective way for utilities to stay abreast of developments; controlled by its utility members Many UFTO members already active. Contact Rick Winters, UBG chairman (PG&E/Endicon) 510-867-0904, or Paula Taylor, Energetics, 410-290-0370.]

• Renewables Paul Klimas, Manager, Renewable Energy Office, 505-844-8159

Sandia’s goal is to develop commercially viable energy technologies based on solar, wind and geothermal resources so they beocme significant domestic and international supplies. They have a long-term focus on the utility sector, expecting remote markets to play a key role in supporting the industry.

Photovoltaics Marjorie Tatro 505-844-3154

Activities in all aspects, from cell development to system applications. Work closely with industry on technology development for crystalline silicon cells and modules and other systems components (e.g. inverters, battery charge controllers and controls), and with the systems integration industry and users through the PV Design Assistance Center. The Center did a thorough evaluation of existing installations and identified new opportunities for the National Park Service. They have an extensive publications list (including some on utility interconnection issues), and provide support to project developers here and abroad.

In the past, Sandia had a number of partnerships under an initiative on concentrators, but chose not to support this work when funding levels were reduced in 1993. The only concentrator effort funded through FY94 was the low concentration line focus concept advanced by SEA Corp.

In one-sun cell development, Sandia emphasizes crystalline silicon, working on cell designs and processes. (NREL tends to be more involved in advanced materials and thin film.) Sandia believes their broad resources in manufacturing are valuable, bringing optimized high temperature processes, surface treatments and reduced waste streams to the manufacturers of cells.
Solar Thermal Craig Tyner 505-844-3340

Manage the conversion of Solar One (still operational!) to Solar Two. IR 100 awards for Solar Detox and Dish-Stirling. $150 million jointly funded program with utilities and manufacturers on Dish Stirling engines (Cummins 7 kW remote power unit is making good progress, and there are two other larger system efforts, both with utility involvement). (“Compendium of Solar Dish/Stirling Technology”, SAN93-7026 Printed Jan. 1994, by W.B. Stine and R.B. Diver, a new report surveys international state of the art.)

The National Solar Thermal Test Facility has an array of heliostat, dish and trough systems for running tests of various kinds.

The Solar Thermal Design Assistance Center provides technical assistance, helping clients select and apply solar thermal technology. (Contact David Menicucci, 505-844-3077).
Wind Henry Dodd, 505-844-5253

Historically, Sandia’s emphasis was on the vertical axis concept, however they have a new initiative to approach wind with a systems view, and have worked on materials and blade design improvements for all wind machines.
Geothermal Jim Dunn, 505-844-4715

Working to reduce costs — developing down hole instrumentation to reduce loss circulation, and”slim-hole” technology that could cut cost of drilling by 1/2 (appropriate for remote village applications). Also working on geothermal ground source heat pump concept (drilling, placement and heat exchanger design). Helped commercialize new drill bit.
• Fuel Cells Gary Carlson, Manager, Fuel Science Dept. 505-844-8116

This is a small program, using most internal lab directed funds, except for work for the DOE Office of Transportation Technology on advanced concepts. Goal is to develop partnerships with industry, and capitalize on Sandia’s capabilities in batteries, catalysis, and especially manufacturability. Note need for better materials to get long term performance. Sandia/Livermore is doing some work in PEM thin films, applying membrane supported catalysis to enable on board hydrogen production.

 

They see special opportunity to develop a small fuel cell (less than 1 KW) for remote applications, to compete with PV and batteries. One application could be gas pipeline condition monitoring.

Sandia has a broad capability to tailor properties of carbon foams, as applied to supercapacitors, advanced (Li) batteries, and fuel cells.

 

• Robotics Sandia Intelligent Systems and Robotics Center, Phil Bennet, 505-845-8777

Sandia is at the forefront of bringing defense and weapons related “Intelligent Systems and Robotics” to bear on commercial needs, and has grown to be the leading robotics R&D effort in the U.S. They focus on critical national needs (hazardous waste clean up and manufacturing competitiveness), reducing the time and cost to develop applications of advanced technology into practical systems, and improving the speed, quality and safety of operations. There is a strong emphasis on working with industry, universities and other government facilities.

Their approach is based on an open-architecture communications-based integration of sensors, mechanisms and software. Computer-model and realtime sensor-based control strategies make off-line programming possible, speeding the development of applications and systems.

Historically, DOE’s internal need for systems to handle small production lots led to the development of ways to reduce the costs of programming and fixturing.

Specific projects relevant to utilities include robotic welding of spent fuel barrels, saving on the order of $250 million and thousands of man rems of exposure. Another involves hot repairs to boilers — in fossil plants (proprietary — with an unnamed utility)!

This Center is clearly a potentially valuable resource for automating utility operations, as well as for industrial customers who develop or use robotics. A good overview is contained in a booklet called “Sandia is Changing the Way the U.S. Does Robotics.” Sandia staff have also authored a number of papers at robotics conferences.

 

• High Consequence Operations Russ Skocypec, 505-845-8838

Sandia’s Engineering Sciences Center encompasses computation, testing, and validation, enabling design trade-offs to be confidently evaluated. Evolving from a historical mission to support systems design and safety for nuclear munitions, they now can offer industry a means to quantify efficiency and safety issues pertaining to industrial accident phenomenology. Detailed risk assessment and coupled analysis and testing provide understanding of the physics of fires, crashes and blasts, enabling better decisions about prevention and response.

 

• High Performance Computing Sudip Dosanjh, 505-845-7018

DOE operates the Massively Parallel Computing Research Laboratory (MPCRL) at Sandia, which applies these new levels of computing power to a broad array of scientific and engineering problems, ranging from structural mechanics and acoustics to chemical reaction dynamics, genome mapping and astrophysics. In the last 4 years alone, the computational speeds have increased by a factor of 100. In collaboration with the University of New Mexico, Sandia has developed a unique operating system called SUNMOS, and their own linear equation problem solver gives them powerful capabilities in parallel computing.

A newletter called the MPCRL Research Bulletin is available.

[Perhaps a place to try some new approaches in power system modeling? Particularly in connection with the next item.]

 

• Distributed Information Technologies,

Rich Palmer, Manager, California Program Development, 510-294-13126

Sandia has a major role in developing technologies for distributed information systems that will contribute to building the “National Information Infrastructure.” Industry has needs similar to DOE’s Defense Programs to use cost-effective distributed information systems to access and process information. The issues are the same: manipulating large data sets, moving them around efficiently, and dealing with privacy and security issues. DOE labs have developed synthetic data sets as benchmarks for participants to perform their own validations and comparisons. The goal is to be able to run problems on very large parallel or distributed systems via high-speed networks.

Sandia has also built extensive testbeds to develop and evaluate distributed applications over Asynchronous Transfer Mode (ATM) networks tying together distributed computing resources. The testbeds include long-link emulators that simulate delays and errors encountered in wide-area networks over large distances. To complement those testbeds, Sandia has also developed a Monte-Carlo simulation based modeling capability for studying realistic network component performance and issues such as congestion control mechanisms for large networks. By including the proper physical representations of traffic models for sources and sink, the same modeling capability could by used to simulate the performance, utilization, and potential overload of wide-area electrical transmission grids.

 

• Sensors Marion Scott, Manager, Sensor Programs Dept., 505-845-8146

Sandia’s work in microsensor development includes acoustic, micro machine/micro electronics, fiber optics, and micro impedance techniques. They have their own complete CMOS IC fabrication capability in-house, as well as for gallium arsenide, enabling them to undertake unique development challenges, such as combining micro machined structures and associated electronics on an IC.

– A bulk quartz resonator can look at the condition of oil in situ. Other possible applications–monitor the state of charge of a Pb acid battery or the capacity of coolants.

– Surface acoustic wave devices coated with chemically sensitive films can sense chemical species in gas at parts per million by looking at resonance changes. With multiple coatings and using pattern recognition techniques it’s possible to distinguish multiple species. Has been packaged in a down hole tool for pollutant sensing.

-Hydrogen sensor on a chip uses special alloys that change their resistivity with maximum sensitivity to H2 concentration.

– Fiber optics offer another technique to sense a wide range of chemicals, such as hydrogen, mercury, SO2, chlorine, and various oxidants. The end of the fiber is coated with a thin chemically sensitive film that changes its reflectivity. CRADA underway with the JW Harley & Assoc to develop a H2 sensor for utility transformers.

– Micro impedance and capacitive sensors can measure physical features for manufacturing applications, e.g. detecting surface flaws in real time. This has been applied to textiles.

– Accelerometers measure vibration indicating structural changes. Sandia has developed a fiber optic/micro machine hybrid device.

• Materials Jim Jellison, Manager, Technical Business Operations,
Materials & Process Sciences, 505-844-6397

Sandia’s Materials Science and Technology program has 600 staff, and is the largest in DOE. Originally developed to provide non-nuclear components for weapons, it now offers services to a wide range of government customers and private industry. The forte is concurent design of the product and the process to make it.

Expertise includes welding, especially cold welding, and soldering; mechanics; tribology, especially lubricant free, with a focus in electromechanical devices; corrosion, emphasis on electronics (e.g., fluxes on circuits, dissimilar metals, batteries); corrosion kinetics, atmospheric testing facility (sensitivities in ppb); aluminum coatings–developing replacement process with less environmental impact; laser surface ablation.

Smart Processes — predictive models using phenomenological data enhances casting, heat treatment, welding, induction heating, etc.

Aging of organic/polymer materials-accurately accelerated aging tests. Applied to electrical cable in work for the NRC

• Reliability/Decision Making

Robert Cranwell, Manufacturing Systems Reliability, (505)844-8368

Industry and the nuclear weapons complex (NWC) rely upon the availability and reliability of equipment which can greatly influence operational costs. Equipment design, reliability, maintenance strategies, and spares inventories all contribute to the cost-of-ownership of factory or plant equipment. Sandia has developed capabilities to assist industry and the NWC in “design for reliability”, equipment improvement analyses, creation of maintenance strategies, and optimization of spares inventories. These capabilities have been broadly applied throughout industry, including the U.S. semiconductor industry, biomedical industry, machine tool industry, automotive and aircraft manufacturing industries, and solar power industry. The capabilities include custom reliability analysis software, optimization analysis techniques, predictive maintenance capabilities, and cost-of-ownership analysis tools. Key partners include SEMATECH and several of its member companies, Cincinnati Milacron, McDonnell Douglas, and USCAR (a consortia of the “big three” auto makers).

Sandia has been working with several major companies, including Motorola and Texas Instruments, to evaluate and qualify new environmentally conscious “no clean” soldering technologies that do not require subsequent cleaning of newly soldered printed wiring assemblies. These new processes are being used extensively throughout industry with great success (Two reports, 11/92 and 6/95, describing these efforts have been issued.)

The Energy Analysis Diagnostic Center (EADC) is a DOE/Office of Industrial Technology program at 30 universities around the U.S., which perform energy audits of companies. In conjunction with this program, Sandia is working with two of the NIST Manufacturing Technology Centers (MTCs) to develop an integrated energy, environment and manufacturing (EEM) assessment tool, the concept being that these three areas (energy, environment, and manufacturing) need to be assessed on an integrated basis, as an attempt to optimize in one area could cause problems in the others. This integrated tool would be used by MTC field agents to assist U.S. manufacturers in EEM related issues, and is being piloted in SIC codes 345, 346 and 347 (screw machines, stampings and forging and metal coating). The Sandia/MTC program is jointly funded by EPRI, NIST, EPA, DOE/OIT, and Sandia.

Follow-on opportunities are needed.

Detailed briefings or information are available on request.

[Perhaps this group would be a good resource to go after the T&D maintenance issue?]

• Micro SMES, Dean Rovang, 505-845-8277

Both Sandia and Los Alamos have a hand in this program to build a SMES unit that would be about 10x larger than Superconductivity, Inc.’s unit, and smaller than the B&W/Anchorage device. The application is Power Quality for industrial customers, and/or at the substation level — on the order of 10’s of MW for seconds. This is seen as a development project, not a research one, with the goal to learn if such a device is the solution to an industry problem.

CRADA negotiations are underway with one utility already, however there is very likely a way for other utilities to participate, if only by providing modest funding for a seat at the table.

• HyMelt, Stuart Purvis, 505-845-8392

The technology makes it possible to convert low grade hydrocarbon feedstocks (or fossil fuels) directly into Hydrogen and Carbon Monoxide (separate product streams!) while sequestering impurities, even producing elemental sulfur. There is no stack, and no emissions.

Ashland wants this technology for its refineries, to deal with the sour crude it often must buy, to produce hydrogen, and to handle refinery “bottoms”, which are a costly disposal headache. As a Hydrogen producer, HYMELT is estimated to be 30% cheaper than steam reforming when using the same feedstock, i.e. fuel gas. It is cheaper still when a waste stream is used as the feedstock instead.

Ashland Oil has demonstrated proof of concept in their labs, and has funding committed for a production installation. What’s missing is the piece in the middle — the intermediate scale demonstration R&D. Sandia is proposing to DOE/Fossil to fund the government side of a CRADA with Ashland, but with budget cuts, funds might not be available. Ashland has asked Sandia to look discretely for a partner interested in other fields of use, and who could put up $800k/year for 3 years, leveraging the many $ millions that Ashland has spent and committed.

[This information should be handled with discretion.]

Contact Al Sylwester Tel # 505-844-8151
• High power switching Don Cook, 505-845-7446

Sandia has developed very fast, very high power switching capabilities in connection with pulsed particle accelerators for fusion research and other work requiring fast pulses. For example, they can make a 20 megavolt, 10-20 megamp pulse with a 50 nsec. risetime.

It has been suggested that this technology might be applicable to utility needs, however an initiative would be needed to establish a dialogue between the developers and someone from the utility industry to explore the possibilities.

Sandia Contacts
General Telephone # is (505) 844-5678
In Livermore, CA (510) 294-3000

The primary contacts for UFTO are:
Alan P. Sylwester, Technology Integration Dept., 505-844-8151
Dan E. Arvizu, Director, Applied Energy Program 505-845-8336
Technology Transfer: 505-271-7888

Information Source Contacts / Technical Information Services:

Office of Public Relations and Communications : 505-845-7759

Publications:
“Laboratory Publications” 505-844-4902
Technical Publications 505-844-9285
Technical Library 505-845-8364