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Wind Turbine Co Making Progress

THE WIND TURBINE COMPANY

We first reported about WTC’s work in an UFTO Note 12 Dec 1996. The story is the same, except for the tremendous progress they’ve made in less than 3 years — pretty much according to their original plan!

The material below was adapted from the executive summary of their current business plan.

Wind energy is the fastest growing segment of the renewable energy industry and is by far the most economic form of grid-connected renewable electricity. Today, wind generated electricity costs as little as 5¢/kWh, and installed global wind energy capacity has increased by more than 25% annually since 1990. It now exceeds 11,000 MW. In 1998 alone, over 2,000 MW with a value exceeding $2 billion was installed. This figure is expected to increase to $5 billion by 2003.

The Wind Turbine Company (“WTC”) has developed new wind turbine technology that promises to slash 30% or more from the cost of wind generated power compared with today’s wind turbines. WTC did a ground-up, total system-level design of a 2-bladed downwind turbine (i.e. the turbine rotor blades operate downwind of the tower) whose principal advantage lies in its ability to shed excessive wind loads. This is in contrast to conventional upwind machines (i.e. blades upwind of the tower), which must be built sufficiently strong, rigid and consequently heavy, to absorb all foreseeable wind loads and avoid catastrophic blade-tower strikes.

Since the wind pushing on the blades causes them to bend in the direction the wind is blowing, blades oriented downwind of the tower can be made much less rigid than blades upwind of the tower. WTC’s turbine will weigh only 60% as much as a comparably rated 3-blade, upwind turbine. Its lighter weight will permit WTC’s turbine to operate higher above ground (100 meters or more) than is economic for upwind turbines, thus exposing it to higher winds resulting in more energy production. Lower weight and higher energy capture combine to provide a substantial reduction in the cost of wind generated electricity. The design incorporates a “yaw” braking mechanism to dampen the response to sudden changes in wind direction, a feature lacking in earlier downwind designs by Carter and others.

Windfarms using the WTC Turbine will be able to will produce power for an unsubsidized price of 3.5¢/kWh or less, including all capital and O&M.

WTC was founded in 1989 and has invested over $6 million in its technology. In 1995, WTC was selected by DOE for a $22 million contract to develop a 250 kW proof-of-concept (“POC”) turbine, followed by two full-scale 1000 kW wind turbines, over a 6-year period. This is the second largest wind energy contract ever awarded by DOE and the largest contract ever awarded by the National Renewable Energy Lab (NREL). The POC turbine should be operational in early 2000. (I have a photo I can send on request – jpeg format).

In 1998, WTC received a $950,000 contract from the California Energy Commission to develop a 500 kW commercial prototype to be developed early in 2000, following completion of initial POC testing. This unit will be operational in mid 2000. Commercial sales of 500 kW units will start in 2001, when WTC also plans to begin development of a 1000 kW commercial prototype.

To overcome market penetration barriers due to developers taking a wait-and-see attitude over concerns about technology and financial risk, WTC will develop and operate its own windfarms. In parallel with its manufacturing operation, WTC will establish project development and operating entities to manage windfarms using WTC’s equipment.

WTC’s initial project development strategy is to focus on the U.S. market where there is ample opportunity and relatively easy and inexpensive accessibility for Company personnel to ensure successful windfarm development and operation. WTC has already begun discussions with potential project participants and sources of financing for two separate projects. WTC is also looking to form partnerships with existing independent power developers to further leverage its project development effort.

WTC is now seeking up to $5 million in additional funding to satisfy match funding requirements under its NREL and CEC contracts, hire additional staff, develop its initial windfarm opportunities, and establish strategic partnerships with potential suppliers and customers. A detailed Business Plan is available upon execution of WTC’s Confidentiality Agreement.

For further information, please contact:

Lawrence W. Miles, President
The Wind Turbine Company, Bellevue, WA 98004
425-637-1470 MilesLW@msn.com

Sanford J. Selman, Managing Director
Energy & Environmental Ventures LLC
Weston, CT 06883
203-227-4111 sselman@eeventures.com

Renewable Energy Technology Characterizations

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

Next Generation Wind Turbine

Subject: UFTO Note – Next Generation Wind Turbine
Date: Thu, 12 Dec 1996 17:03:33 -0800
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
| NOTE NEW EMAIL ADDRESS: edbeards@ufto.com
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This Summary was prepared for UFTO by the Wind Turbine Company. Complete details on their business plan and technical approach are available from the company. The company is seeking business partners and equity investment capital.

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THE WIND TURBINE COMPANY December 12, 1996

WTC’s 2-blade, downwind turbine design holds the promise of reducing the cost of wind generated electricity from its current level of 5¢/kWh to less than 3.5¢/kWh without resorting to available subsidies. WTC has significantly refined and improved upon the downwind design, incorporating proprietary technology, in a quest to reduce the initial turbine cost, the primary cost driver of wind energy, without sacrificing reliability. WTC’s turbine will weigh 60% as much as a comparably rated 3-blade, upwind turbine. Its lighter weight will permit WTC’s turbine to operate higher above ground (100 meters or more) than is economic for upwind turbines, thus exposing it to higher winds resulting in more energy production. Lower weight and higher energy capture combine to provide a substantial reduction in the cost of wind generated electricity.

WTC was selected by the Department of Energy’s National Renewable Energy Laboratory (DOE and NREL) to participate in Stage 2 (the hardware building stage) of the “Next Generation Turbine Development Project.” This is a $20 million project with the DOE picking up 70% of the cost. It will last 5-6 years. Two commercial wind turbines, the WTC 250 and WTC 1000, will be developed. As the result of its cost sharing, WTC will own all hardware produced.

A contract with NREL permitting work to begin on this project is expected by the end of December, 1996. To begin work, WTC needs to obtain initial funding for its share of the cost. WTC has identified two outside sources of funding and would like to identify one or two additional sources, one of which is ideally a strategic partner that can help commercialize the wind turbines when they are available.

The project will be executed in three phases corresponding to the development of three wind turbines:

In the “proof-of-concept” (POC) phase, WTC will manufacture and begin testing the POC 250, a 250 kW turbine. This turbine will demonstrate the technology that is novel to WTC’s design-WTC’s proprietary, hydraulically operated system in the turbine’s rotor that permits the cone angle between the blades to adjust depending on wind speed. Building the POC 250 will take approximately 12 months with an extended testing period to follow.

In the second phase WTC will develop the first full-scale 1000 kW turbine. This phase will begin in the second quarter 1998. During this phase, WTC will also develop an all new wind turbine blade for the 1000 kW turbine.

Concurrently, and independent of the NREL contract, WTC will refine the POC turbine with the intention of having the WTC 250 commercially available in early 1999.

3. The second full-scale turbine, the WTC 1000 production prototype, will be manufactured in the third phase. This turbine will be a commercial product.

To execute the project, commercializing the WTC 250 in parallel, WTC will have to raise approximately $12 million in equity funding over the next 5-6 years before reaching a break-even cash flow. This fund raising occurs in stages corresponding to the turbine development phases. Presently, WTC is raising $2 million by selling equity representing approximately 40% ownership of the Company. This will permit execution of the POC phase.

One of WTC’s current shareholders will participate in this financing, and WTC also expects a newly formed, electric utility-funded venture capital company to participate. Together these investors will account for a minimum of $1 million of the required initial funding, and could easily account for more. Both would like WTC to identify a strategic partner.

Markets for the WTC 250 and WTC 1000

The opportunity for the WTC 250 is in developing countries and in installations that are not grid connected. For example, the standard WTC 250 would be ideally suited for islands in the Caribbean, the Azores, etc., as well as mainland-based installations in Latin America and Asia. Primary considerations for this turbine are climates where fully weather protected maintenance is not critical, and where existing infrastructure such as roads, as well as the unavailability of large-size erection equipment, prohibit the installation of large wind turbines.

Many such installations are currently served by diesel generation units or are candidates for such units. Even in locations where diesel fuel is low cost, integrated wind/diesel systems will emit less pollutants and therefore should be viewed favorably by customers.

One modification to the WTC 250 which has been considered is the development of a cold weather version. Though the market for this wind turbine is a subset of the market for stand-alone systems, it is a high value opportunity. In many remote, cold weather locations, the cost of delivering diesel fuel is high.

WTC believes it can sell a limited number (20+/-) WTC 250 wind turbines in early 1999, generating its first revenue from commercial sales. Specific customers for these turbines have not been identified, however, a number of opportunities exist including the DOE/Electric Power Research Institute sponsored Turbine Verification Program. The US military is also known to be considering use of renewable energy technologies.

The opportunity for the WTC 1000 is large scale, grid connected applications. At present, and for perhaps the next 5-10 years, this market will be primarily in North America and “off-shore” in Europe. If the WTC 1000 achieves its cost and energy production targets, it will be competitive in the deregulated North American marketplace. Initially, it will displace higher cost sources of electricity from the grid when the wind is blowing. Storage technologies will eventually improve to the point where wind energy will become a major contributor in the North American electricity system.

During the next 3-5 years, however, there will be limited opportunities for new wind energy projects in North America as the generation industry deregulates and excess capacity is absorbed. This is the period during which WTC will be developing its new technology. By the time the WTC 1000 is available for commercial sale in the year 2000, the US market for low-cost wind energy will be rebounding.

The immediate opportunity for wind energy will be presented by the closure of aging nuclear power facilities. WTC believes the public will not accept a lessening of air quality as the price for a more competitive electricity market. Thus, in spite of an abundance of coal in North America, natural gas will to continue to be the fuel of choice. If the WTC 1000 achieves its cost objectives, electricity generators will turn their gas turbines off when the wind is blowing.

For more information please contact:

Larry Miles, President
The Wind Turbine Company
515 – 116th Avenue NE, Suite 263
Bellevue, WA 98004 USA
telephone: (206)637-1470
facsimile: (206)637-1483
email: MilesLW@MSN.com

Technology Transfer Opportunities – Livermore National Laboratory

by Edward Beardsworth
Nov 1994

Summary

This report details findings about technology and technology transfer opportunities at Lawrence Livermore National Laboratory (LLNL) that might be of strategic interest to electric utilities. It is based on several visits to LLNL in 1993 as part of a project for PSI Energy, which had the additional goal to establish relationships that would enable PSI to monitor developments and gain access on an ongoing basis.

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, PSI Energy supported this project to become familiar with the content and process of those programs, and to seek out opportunities for collaboration, demonstration or other forms of participation that will further the business objectives of PSI. PSI has agreed to make these results available to the participants in UFTO.

Findings
Detailed listings of LLNL people, technologies and programmatic capabilities (of relevance to utilities) were assembled in the course of the project, and are included. LLNL’s matrix organization is not easily understood, though we did begin to get a sense of it, and certainly identified the key people and groups to deal with. It was a matter of hearing similar accounts a number of times from a number of people, before one began to have confidence that an accurate picture was forming.

LLNL has a large body of work that is relevant to utilities, including storage and power conditioning (batteries and capacitors), toxics remediation, NOx reduction, modeling, hydrogen storage, sensors, materials (catalysts, coatings, insulators, thermoelectrics), etc.

Armed with a brief statement of PSI’s technical and business interests (and an understanding of generic industry interests), it was possible to sift very quickly through a large body of program information at LLNL, mostly through conversation with key contact individuals, and identify areas meriting further study. Additional information was requested for projects of particular interest.

On a practical note, it was interesting to discover that a degree of advance preparation is involved even in the practical matters of learning where facilities are located and the procedures for gaining entry (no minor matter in LLNL’s case, since it still operates as a secret weapons lab). After an actual visit, one can approach a facility with far greater ease and familiarity. Like putting names to faces, there is no substitute for seeing things for oneself.

Method of Approach
LLNL personnel repeatedly suggested that progress would be quicker with a list PSI’s specific needs/problems. LLNL could then do its own internal scan of technology resources to find a match. This certainly is a useful approach, however PSI had an additional broader mission in mind. The broader objective included a general familiarization with LLNL’s programs and the start of a fruitful ongoing set of (personal) relationships. Over time, as PSI becomes a known commodity to LLNL, one would expect LLNL to bring new opportunities to PSI’s attention.

Both the “specific needs” approach and a general awareness approach were used. The two overlap, each supporting the other. As interactions continue, each organization gains increasing awareness of the other’s methods, resources, needs and capabilities (“culture”), leading to a stronger potential for a mutually beneficial business relationship. (General Motor’s experience bears this out. See separate writeup.) No “deal” can be made without personal contact at some point, and conversation is the process by which that happens. In any case, when both parties are motivated to “do something”, the process moves with remarkably efficiency, as was the case in this study.

In particular, the “general awareness” mode identified a LLNL technology of potential interest to PSI that is just at a stage where utility interest was being sought (flywheels). In the “specific problem” mode, an unexpected match was identified between a need of PSI to find uses for glass microspheres from flyash, and LLNL’s work on hydrogen storage (itself a spin off from inertial fusion research).

To accomplish the “general awareness” goal, there is no real substitute for personal contact, visits and probing into the various programs and perceptions at a complex organization like LLNL. Published materials are likely to be out of date and certainly will not provide any of the nuance or subtlety of understanding that could eventually lead to an actual working relationship or “deal”.

The various search databases and services can only help to identify contacts for a particular, rather well-defined, question or problem. Even then, however, it is noted in a couple of test cases that neither the National Technology Transfer Center (NTTC) or the Federal Labaratory Consortium (FLC) identified LLNL’s activity in a particular area.

Business Arrangements
Livermore, as with all the federal labs, are feeling strong pressure to show results in technology transfer, to get their technology out into the marketplace and help the U.S. economy. Likewise, they are very concerned with the survival of their programs, and are anxious to obtain additional outside resources. So, while money is a concern, the motivation is not the same as a business profit motive. The primary goal is to get things used, so society benefits.

While there is a long list of mechanisms for industry-laboratory collaboration, including exchange programs, licenses, and cost-sharing, nearly all new agreements are being prepared under the provisions of CRADAs. The business arrangements possible under a CRADA are very flexible, and can accomplish most if not all of kinds of objectives. Importantly, it is only under CRADA (and directly funded “work-for-others”) that the industrial partner can gain a measure of protection for intellectual property (for up to 5 years) while gaining benefit from the government’s technical capabilities.

CRADAs can be approved more quickly if they do not involve new (i.e. unplanned) expenditure by the lab program. Generally, the concept is a 50-50 split, with each party’s contribution provided by funding, intellectual property rights, technology know-how, use of facilities, man-hours, etc. The only restriction is that government money cannot flow to the industrial partner.

Federal Policies and Programs in Flux
Federal efforts in this arena are very much in flux and the subject of considerable debate and political controversy. The future of the major labs is by no means clear or assured. A new study “Defense Conversion, Redirecting R&D” [Office of Technology Assessment May 1993] cites the continuing difficulties of intellectual property, liability, US only use, funding, and bureaucracy that bedevil the “CRADA” negotiation process, against a backdrop of major debate on the appropriate government role in fostering competitiveness and economic growth (in the context of the end of the cold war and all it implies for defense R&D). Such periods of uncertainty and transition often present big opportunities to those willing to jump in and see what can be done.

General Observations

• TECH TRANSFER is much easier to approach with specific needs/problems!!!!
The message from everyone contacted at LLNL (also a dominant theme from General Motors’ experience) is that a potential industrial partner is best served by coming forward with a statement of its own needs, problems, and goals, and a characterization of its own interests, abilities, and resources. Lab people will then get you together with the right contacts.

• Utilities could have high leverage/influence on LLNL’s ability to get the attention and funding from DOE/Fossil Energy. As a defense lab, LLNL tends not to be regarded as an likely player in fossil work, and is often prohibited by law from responding to DOE solicitations. If PSI sees work of interest at LLNL, its opinion alone would carry considerable weight.

• “TT is a contact sport” Ultimately, deals will be made between individuals, who have to first find each other. The Lab’s objectives are funding and commercial utilization, so they want real business deals to happen.

• The scale of material, technology, personnel and organizational complexity of LLNL is staggering. Over 10,000 people work there. [Note what it takes for a utility to keep up-to-date and tapped in to EPRI]

• Noteworthy that in LLNL’s case, the bulk of the core program is for weapons, isotope separation or magnetic and inertial fusion. Only a relatively small portion is “applied”. Tremendous spin-off potential, however.

• There are tremendous time lags in all aspects of the the TT process, from making first contact to signing a deal.
– Telephone tag and people’s travel schedules mean that initial contacts can take weeks to establish, and meetings can be difficult to arrange. If LLNL perceives a real opportunity, then they are likely to respond more promptly, but they seem very open and accommodating as a general rule.
– At least 4 sets of lawyers get involved in putting a deal together — DOE , U Calif, LLNL and the industrial partner. Sometimes DOE regional office at odds with headquarters. Policy subject to varying interpretations. Policies also evolving.
– DOE budget cycles delay, limit resources available for matching funds.

• If companies approach LLNL, LLNL can respond 1 on 1. If LLNL seeks partners, they must make good faith effort to make opportunity available to any/all companies in the industry.

• LLNL’s internal organization is in constant flux–responding to very real threat of extinction by trying lots of new things. New faces appear, new programs–a moving target to try to know who’s who. Roles and missions of people and offices are changing over time. There appears to be some friction between some of the new “marketers” and some technical people, although most people seem to appreciate the seriousness of the need for LLNL to change in order to survive.

• Information systems, publications, conferences and trade shows are good as hunting grounds, but the Federal R&D resource is immense. Again, having a specific need/topic/problem/question is very helpful.

• Although there is a long list of “mechanisms” for tech transfer with the labs, ranging from cost-sharing and exchange programs to licensing and “work-for-others”, most new agreements are being written as CRADAs (cooperative R&D agreements). This is the only mechanism that affords the industrial partner a degree of protection for intellectual property.

Specific LLNL Technologies Identified

[“Ref Oppty’s ” refers to LLNL publication “Opportunities for Partnership” Technology Profiles — one page write-ups on selected items.]

Batteries:
Zn-Air — [like Al-Air which was commercialized from LLNL work in 70’s (Alu-Power, NJ)]
Cheaper cycle, due to low temp reduction process. Instant refueling. Very little environmental impact of discard.

Flywheel –1, 5, 25 KWH versions. very high specific energy (100-150 kwh/kg) and high power. Conceivably could compete with Pb-Acid in $/kwh. A demo is being built at LLNL. Can tailor design for applications from railroads to UPS (uninterruptible powr supply). Better than SMES. Utility application — interest being pursued by an equipment mfg.

Li-Ion — improvement over Sony/AT&T technology (Reversible intercalation of Li in carbon anode) using foam technology get 1-1/2 times current 80-100 wh/kg. High cycle life. Utilizes aerogel carbon foam technology (see aerogels below).

Renewables:

Windpower: NDE for blade mfg; windflow modeling for siting and dispatch; flywheel storage.

Solar: advanced solar rankine cycle (MHD) very speculative

Thermoelectric Materials. Thermoelectric power generation and cooling has always been limited to very specialized applications, due to low efficiency and high cost. Very recent theoretical work (paper to be published soon) indicates the possiblity of a new class of devices based on new materials and very thin multi layers, with dramatically enhanced figures of merit that would make them competitive. At the stage of basic R&D, first application of interest is cooling of electric vehicles. LNLL has a relationship with MITand a company that is developing solid state replacements for alternators on truck diesels(which use waste exhaust heat).
Contact is Joseph Farmer 423-6574 or Jeff Wadsworth

Storage Reservoir Characterization — acoustic and seismic imaging techniques from work in geothermal applicable to CAES or gas storage? Contact is Alan Burnham. (The principal investigator is Paul Kasameyer, Earth Sciences.)

Hydrogen/fuel cells: LLNL concentrating on vehicle storage–composite materials for tanks; cryogenic carbon adsorption and glass microspheres.
Contact is Glenn Rambach 423-6208
– 10-12 years ago, they needed “perfect” glass microspheres for inertial laser fusion (fill with deuterium or tritium — tiny H-bombs when blasted with lasers). Commercial ones too irregular–sorted thru and found that only 1 in 10**13 that were good enough. (Note one of the commercial processes involves flyash in a turbulent flame.) They developed a way to make perfect ones. Now seeking to scale up the manufacturing process, to use spheres for bulk storage of H2.
– They’re in discussions with a vendor interested in a near term commercial application.
– Need to scaleup mfg. by factor of 10**12 — already accomplished 10**6.
– Still may be able to use commercial/imperfect spheres–sorting process to pick out the ones that are good enough.
– Reference: Robert Teitel, BNL Report # 51439, May 81 “Microcavity H2 Storage, Final Progress Report”. Also, there is an LLNL report on properties, manufacture and use.
– LLNL has best capability in the world to study structure/characteristics of microspheres.

Economic Modeling: Genlzd Equilibrium modeling (3rd generation) network/market model; (relaxation of Lagrange coefficients.) Want opportunity to use methods to meet a utility’s needs. (Tom Edmunds and Alan Lamont)

– National market model –policy applications — market clearing/capacity additions — with accurate detailed charactization of technologies, linked in a network model.
– Distributed Utility (DU) they contributed to PG&E DU report — their approach apparently was not adopted. They feel confident their approach would be useful to utility planners–based on idea of value/market clearing prices determining what is built and when.
– For EIA/DOE — Emission trading and natural gas models.
– META•NET is beta software “language/platform” for this kind of modeling — user’s manual provided.
– Suggest LLNL’s has special competence in sensors, data mgt, control/response moment-to-moment, that would be important in operation of DU.

Supercapacitors:

Thin-layer — < 4 µ layer dielectric – very rugged, high voltage, very high power for pulse applications and high voltage power conditioning. 0.6 wh/kg. With other materials,can go to megavolts! [ref 9-13 Opptys] This is one application of very thin film multilayer manufacturing technology.

Aerogel — (see aerogel discussion) 10**4 better! up to 40 Farads/gm,
high energy 5-10 wh/kg , power 2-20 kw/kg (contact is Jim Kaschmetter, Physics)
Uses carbon aerogel foam in thin layer as electrode in liquid electrolyte. Extremely large surface area and double layer capacitor effect. Carbon aerogel manufacture appears to be closer to practicality, as it doesn’t require non-critical extraction. Very low cost. Opens up possibilities for very low energy desalination via capacitive deionization.
[Update: Jim Kaschmetter left LLNL to form Polystor, a spinoff startup company that is commercializing this technology.]

Materials (general): Contact Alan Burnham or Jeff Wadsworth
Ceramics–non-brittle “plastic”, moldable and fracture resistant.
Blast resistant laminates
Anti-corrosion coatings; modeling of coating properties

Granular Flow Modeling
Over last 10-15 years, developed new class of modeling capability applying molecular dynamics to macroscopic materials. Otis Walton is a world expert. Lots of interest from chemical mfg, and some discussions re coal handling (need better inroads with coal/utilities).
(Potentially applicable to ground source heat pump work.)

Combustion Modeling (Charles Westbrook) work for IC engines, use of refinery gas.
Works very closely with Sandia/Livermore’s combustion group. He does chemical kinetics, toxics, Clean Air Act, etc. They do more numerical work, and have a major coal program.
– Big CRADA with auto makers, Cummins & other engine makers, Sandia and Los Alamos for modeling to reduce HC and NO emissions from engines. (Separate from post combustion NOx project).
– Haven’t had much contact with utilities–have gone to auto, oil, mfg industries first.
Putting together concept for consortium with oil companies for a “Clean Air Act Center”
– Ultra low NOX nat. gas burner subcontract to UC Irvine/Calif Instittute for Energy Efficiency.
– GRI project similar/related
– Also for GRI — Burner Engineering Research Lab at Sandia

NOx reduction: — pulsed plasma and hydrocarbon catalysis — (Henrik Wallman) CRADA with diesel mfg. -Cummins– (advantages over ammonia and urea injection) [ref 3-11 Opptys & handout] Interested in developing power plant application.

Methane-to-methanol in conjunction with power generation: (A. Burnham) once thru system for conversion, with the effluent used for power generation. Avoids expense of multi-pass and separations to utilize all the methane. Conversion takes place via pulse plasma (Henrik Wallman), or “bio-mimetic” catalysts (Bruce Watkins).

Sensors:
Electochemical [ref 9-3] measure contaminants in waste streams, monitor corrosion

Fiber Optic [ref 9-7]

Aerogels:
… “frozen smoke” lowest density solid — many remarkable properties and potential applications. very high surface area 300-1000 sq meters/gm, lowest thermal conductivity of any material. Supercritical extraction of solvents leave open-cell structures of Silicon, Carbon-based or metal oxide materials. Fabrication not cheap yet. [ref 6-5 Opptys]
Supercapacitors ( see above)
Metal Oxide catalysts [ref 6-17 Opptys]
Insulation (can be made from agar–seaweed!)
Natural Gas storage
new electrodes for fuel cells

Environment: (contact is Jesse Yow) [additional details available in “Environmental Technology Program Annual Report FY91 — UCRL-LR-105199-99]

In-Situ Remediation:

Sensors: — New class of fiber optic sensors down in a drill hole detect concentrations 1:10**6 (benzene => gasoline) and 1:10**9 (TCE). Dramatic reduction in cost to characterize/monitor an underground site in almost real time.

Underground Imaging: — Electromagnetic techniques using RF or DC current–can get 3-d images of pollutant plumes, or of the burn front of in situ coal gasification.

Spill Cleanup — Electric resistance heating and steam injection used to drive volatile compounds out of the earth, reducing time scale from 10’s -100’s of years to 10’s of months.
(Ground heating may be applicable to ground source heat pump work.)

Radiolytic Decomposition of toxic Materials (Steve Matthews)
Use of E beams, x-rays and ultraviolet ionizing radiation to break down organic materials into harmless or less toxic materials. Can be applied to vapor or liquid phase, in remediation applications or process streams.

Global Emissions / Atmospheric Release Modeling — LLNL was called upon for analysis of Chernobyl, the Kuwaiti Oil Fires, etc. Can handle accident/leak situations on any scale.

LLNL Organization

LLNL has a complex matrix organizational structure, consisting of “directorates”, or “programs” and “divisions”. The general pattern is for technical personnel to belong administratively in discipline-based divisions (physics, chemistry & material science, engineering, etc.). Most project work is organized in the programs, to which personnel are assigned and bill time, etc. There are many exceptions, however. Some projects are administered in the divisions, and a number of people “wear several hats”, reporting to different groups within LLNL at the same time. Organization charts are of little help. Key contact personnel can provide guidance about who to talk to on any given subject, though it does pay to get more than one perspective on program content and direction.

A recent reorganization is reflected in the attached organization charts.

LLNL Personnel Contacted/Identified: (general phone # 510-422-1100)

Alan Burnham 422-7304, Program Leader, Energy Technologies. is our main point of contact. He is in EMATT, in the Energy Division(see below).

Alan Bennett, 423-3330, Director, Industrial Partnerships and Commercialization.
New to LLNL inDec ’92, to handle “institutional marketing”, and to develop new business for the lab as defense/ weapons budgets shrink. [Promoted 11/94 to new position in charge of tech transfer overall.]

Technology Transfer Initiative Program (TTIP):
(This group of about 30 people has seen its role transition from initiator to production administrator. Where previously they were trying to promote tech transfer and make the connections between Lab staff and industry, they now find themselves with more than enough proposals, and responsible to oversee negotiations and contracting–more of a classic intellectual property/licensing “production” operation. They also coordinate trade show participation and visits to the lab by outsiders.)

(vacant) 423-1341, Director
Dave C. Conrad 422-7839 Acting Director. Came in Feb. 93 from weapons program to set up business procedures; took over when former director Gib Marguth left to go to Sandia Livermore.
Ann Freudendahl 422-7299

“TACTs” Technical Area Coordination Team —
This designation relates specifically to the $140 million DOE Technology Transfer Initiative, and is comprised of technical staff members secunded to review proposals and to meet with reps from other labs to do overall rankings.

Alan Burnham Energy 422-7304
Bill Robson Environment 423-7261 [Laser/Environment Program]
Jeff Wadsworth Chemistry & Materials Sci 423-2184 [Ass’t Asoc. Director]
Bart Gledhill Biotech
Mike Fluss Microelectronics

Their are also TACTs assigned for the new special DOE AMTEX program with the textile industry. (See discussion about Industry Partner Programs.)

Anthony K. (Tony) Chargin 422-5196, head of EMATT (Energy, Manufacturing and Transportation Technologies), a new program established late ’92 bridging the Energy and Engineering Directorates, now reporting directly to the Energy Division.

Alan Burnham, 422-7304, Program Leader, Energy Technologies. Point of contact for energy supply and storage. Also a member of TACT. Most of the work is in oil & gas production, espec oil shale and petroleum geology. Physical Chemist — 1/4 time doing technical work. He is also LLNL’s point of contact with Morgantown Energy Technology Center (METC), which handles DOE coal gasif. work.

Jeff Richardson, 423-5187, formerly in Chemistry & Materials Sci., is now Program Leader in EMATT for Materials Manufacturabilit
Dick Post, 422-9853, developer of Flywheel (electromechanical battery)
Henrik Wallman, 423-1522, Staff Scientist, Fossil Fuels. Has work going on in hydrocarbon catalysis and pulsed plasma — NOx reduction. Also proposing partial oxidation of methane coupled to power generation,

Tom Edmunds 422-5156 System Sciences, Engineering Research Div.
Alan Lamont 423-2575
Genlzd Equilibrium modeling (3rd generation) network/market model
Charles Westbrook 422-4108 , Physics Department, Combustion Modeling
Works very closely with Sandia/Livermore’s combustion group. He does chemical kinetics, toxics, Clean Air Act, etc. They do more numerical work, and have a major coal program.
(Sandia/Livermore Combustion Program: Don Hardesty 510-294-2321.)
Glenn Rambach 423-6208, Hydrogen/fuel cells: LLNL concentrating on vehicle storage–composite mat’ls for tanks; cryogenic carbon adsorption and glass microspheres. Also some new concepts in materials for fuel cell electrodes and electrolytes.

Chemistry & Materials Science
Jeff Wadsworth, Chemistry & Materials Sci 423-2184 [Assoc. Director] Joined LLNL in ’92 from Lockheed (metallurgy)

Jean H. dePruneda, 422-1339, [Division Leader, Chem. Sciences Div.] does internal and external networking for tech transfer–point of contact. Aerogels for catalysts, supercapacitors, insulation.

Lucy Hair, 423-7823, Point of contact for aerogel catalysts
Troy Barbee 423-7796, Point of contact for thin layer supercapacitors
Bruce Watkins Methane –> methanol conversion, biomimetic —
synthesize materials to mimic enzyme/proteins — with GRI

Steve Mayer 422-7702, Electrochemist working on Li-ion battery. (Reversible intercalation of Li in carbon anode. Rick Pekala is materials person 422-0152) He is on DOE Utility storage group. Sees utility applications for supercapacitors for Power conditioning, motor starting, etc.
These two people are also the developers of the aerogel supercapacitor.

Laser Program
Ralph Jacobs 424-4545, Director, New Technology Initiatives, Laser Program, (also microelectronics) Focused on laser isotope separation, advanced chemical processing
Bill Robson 423-7261 Environment TACT, industry partnering for Environ Protection Program,
Don Prosnitz 422-7504 contact for emission monitoring
Booth Myers 422-7537 Sr. Scientist, Isotope enrichment (gadolinium for LWR control rods), waste processing/incinerator replacement
Steve Matthews 423-3052, Environmental Protection Dept / E-Beam, LLNL’s own site remediation, and some research. (This group is not in the Laser Program).

Physics and Space Sciences Directorate
Steve Hadley 423-2424 (Assistant Assoc Director for Tech Transfer) Point of contact for Industry partnering. Joined LLNL 11/92 from Aerospace industry. Notes that Physics at LLNL is focused heavily in weapons/SDI related work and basic research. Can also look in other departments (lasers, chem & materials) for items that one might expect to see under physics.

Environmental Programs Directorate (created in a recent reorganization, combining several related functions from other areas. Acting Director is Jay Davis.)
Jesse Yow 422-3521 Deals with wide range of environmental technologies, especially in-situ monitoring and remediation.

Information Source Contacts / Technical Information Services:

Public relations. General # is 422-4599
Marybeth Acuff 423-4432 knowledgable contact.
Loren Devor, Technical Info. Dept. (liaison to Directors Office) 422-0855
She handles corporate publications/ mailing lists;
Energy & Technology Review (monthly magazine), and the 5 yr. Institutional Plan

Research Library (for internal lab use–but individuals seem willing to help over the phone)
Circulation Desk /general # 422-5277 — Betty Herrick is Ass’t Group Leader
– There’s an on line database avail to employees and contractors only of their card catalog/holdings, also to the entire U.C. system (Univ. Calif)
– New LLNL reports list published monthly is for internal use only.
Howard Lentzner 422-5838 — Research Librarian (chemist by training)
– They can help outsiders for pay–complicated administratively. Can help gratis on quick items. Better to get copies of lab reports thru NTIS or directly from the researcher.
– Everything is in DOE databases, on Dialog and other services.