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Zero Emission Engine

At the risk of “excess exuberance” …this looks like something that could change everything — a zero emission, fuel flexible– *steam engine*.

I first heard of them from announcements back in May 2000, and have finally been able to make contact, just in time to learn about the new company they’ve set up. They’re showcasing at the SAE conf (Soc. of Auto Engineers) in Detroit this week. My contact is Oliver Mehler, who’s heading the operation in the US.

I have the executive summary of their business plan, which seeks to raise 22 million Euros over the next four years.. The full 60 pg plan is now only in German, and they are preparing an English version.

The management team is in Detroit this week (only Oliver is stationed in the US). If you have anyone attending the SAE conference, you may want to have them visit the booth.

I asked what was different about this steam engine, and Oliver described a visit to a major US engine manufacturer. It was scheduled for 1 person for 45 minutes, and wound up with 12 people for 3 hours. They said “we tried (and failed) –you solved all the problems which stopped us” (e.g. lubrication materials, isothermal expansion, quick load changes, good combustion system). The website has neat pictures of their 6 kw APU prototype, which they estimate will be made for a cost of $700, in volumes of 10,000/yr. They are talking to corporations, financiers and VCs to raise money. They want manufacturing partners.

http://www.enginion.com — go to “Press” for the complete press release (excerpts below) and a pdf download brochure about the APU. I’ve also got a 12 page technical article from a year ago that explains the thermodynamics.
Contact:
Oliver C. Mehler, Ann Arbor, MI
734-971-1070 ext. 111 oliver.mehler@iavinc.com

Note- IAV is a major European automotive engineering company, 50% owned by VW. Enginion is spinning off with most of the development team that worked on the project. Since public (EU) funding was involved, it was deemed inappropriate for VW to have it to themselves.
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(excerpts)

Enginion AG Says New Engine is ‘Cleaner Than the Air we Breathe’
‘Zero Emission Engine’ Debuts at SAE World Congress In Detroit

ANN ARBOR, Mich., Feb. 28 /PRNewswire/ — Enginion AG, a technology provider for the automotive and energy industry plans to demonstrate an ‘Equal Zero Emission Engine’ (Ezee) at next week’s SAE World Congress in Detroit. The new technology does not require any catalysts. The Ezee uses external combustion that is based on a patented ‘Caloric Porous Structure Cell’ (CPS Cell), utilizing a newly developed thermo-chemical combustion reaction, which drives an electronically controlled, oil free thermal engine.

The technology has been developed with funding by the European Union as well as various institutions of the German government. It took six years and nearly one million man-hours of basic research to reach the stage of development presented at SAE. “The new drive appears to have the potential of substituting conventional combustion engines,” said Michael Hoetger, President of Enginion. “Its emissions profile is among the lowest of any existing combustion technology. At the same time its production price is expected to be equal or lower than current powertrains.” The technology incorporates the following benefits:

– Lowest pollutant emissions (no HC; NOx and CO at the limit of
measurability) No exhaust after-treatment needed
– Very high torque (5 times higher than regular Otto-cycle engines);
power output and dynamics are equivalent to diesel engines
– Fuel flexibility (gasoline, diesel, natural gas,
biofuels, hydrogen, etc.)
– Thermal and kinetic energy (both variable)
– High efficiency (better than gasoline engines,
according to U.S. FTP75 test cycle)
– Almost silent and vibration free
– Compact size
– Oil free; operation in ecologically sensitive areas possible
– Lower cost than existing technologies

Based on the encouraging research results, Hoetger and his colleagues initially plan to develop small Auxiliary Power Units (APU), as the fuel flexible and compact technology can deliver variable heat and electricity over a broad power range. The areas of application stretch from mobile use in vehicles to stationary operation in residential and industrial environments.

Enginion’s Ezee technology is further suited to build up stationary distributed power systems. With its co-generation capabilities (heat and electricity) it could deliver clean energy for residential as well as commercial purposes. In one of the largest market segments with heat outputs of up to 30 kW and a maximum electricity of 10 kW, the Ezee APU might be up to 90% cheaper than other solutions, including fuel cells and gas turbines. The APU’s electronic control shall additionally be equipped with networking capabilities for the development of small-scale local grids.

Enginion plans to stay focused on research and development rather than becoming an engine producer themselves. Instead, they want to offer partnerships to professional manufacturers. “With our technology and product development skills we would develop the Ezee products ready for application” Hoetger summarized. “The production partners pay only a few dollars per unit for the production license. This way they can independently set their profit margins and use own distribution channels without our interference. But I think it might take quite a number of manufacturers in the long term. All studies we found indicated that the potential markets have a total business volume beyond US$200 billion,” Hoetger said.

Heat Transfer Research, Inc.(HTRI)

HTRI is a for-profit membership R&D consortium focusing on heat transfer in process industries. Members from all over the world include major engineering firms (e.g., ABB, B&W, Bechtel, Black & Veatch, Brown & Root, GE Power Systems, Kvaerner, Stone & Webster, etc.), major oil and chemicals companies, equipment makers, and exactly one utility (Ontario Hydro).
HTRI wants to increase its involvement with utilities, and has approached UFTO for help. While their work hasn’t yet addressed some of the core power plant systems (steam generators, surface condensers, etc.), they could certainly initiate programs in those areas.

At the same time, utilities do have innumerable other heat exchangers and heat transfer applications that are addressed by HTRI (e.g., shell-and-tube heat exchangers).

Perhaps more important, conventional steam boiler technology is being supplanted by combined cycles — primarily natural gas-fired at this time, but likely to include more coal, residual oil, and biomass gasification in the future. The major heat exchanger in a combined cycle plant — the heat recovery steam generator (HRSG) — is a relatively new type of heat exchanger in terms of widespread commercial use. There will be many challenging design and operating approaches and challenges associated with HRSGs as combustion turbine and steam turbine designs evolve into higher temperature regimes.

Also, it’s worth mentioning that utilities (or ESCOs) could use HTRI resources in their continuing role of helping industrial customers be more efficient, productive and successful.

Thus, there would appear to be a number of ways HTRI and the electric power industry could grow together. As one example, HTRI is planning a new “sub” consortium to address heat exchanger fouling, certainly an important topic for utilities.

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–>> UFTO Members are invited to attend the upcoming HTRI Annual Meeting, July 26-31, Amelia Island, FL, which will feature technical presentations and workshops on the IST and EHT codes (described below).
Contact Susan Edwards at HTRI to request a copy of the program agenda.
tel 409-260-6203 sme@htri-net.com

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CONTACT:
Claudette Beyer, President and CEO 409-260-6222, cdb@htri-net.com
Fernando Aguirre, Dir. Marketing 409-260-6200, fja@htri-net.com
Heat Transfer Research, Inc.
1500 Research Parkway, Suite 100
College Station, Texas 77845 USA
Tel 409-260-6200 Fax 409-260-6249

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The material attached below is excerpted and
adapted from HTRI publications and their website
http://www.htri-net.com
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1. Conducts research on heat transfer equipment of a type and scale, and with fluids and operating conditions, relevant to industry.
2. Develops methods for the thermal/hydraulic design and rating of heat transfer equipment that are soundly based on experimental data.
3. Creates, maintains, and supports superior quality computer programs that utilize HTRI methods, are user-oriented, and easily interfaced with other programs.
4. Serves as a source of support and expertise addressing current and future needs in heat transfer technology.
5. Recruits and supports staff and consultants or partners who bring the necessary expertise, dedication, and vision.

HTRI products are based on decades of member-sponsored proprietary R&D, and are not available on the open market. HTRI members have access to HTRI’s product line and become part of a research consortium comprised of industry leaders from around the world—all for less than the salary of a single additional engineer. (Membership fee varies with size of company–to a maximum of approximately $50,000 per year.) Subsidiaries of a member company may also use HTRI products, if they are more than 50% owned.

Joining HTRI is like adding a dedicated team of heat transfer experts to a member’s company. Members gain access not only to our software and research data, but also to the collective experience of the staff. HTRI technical support can improve productivity with expert answers to questions about software, methods, correlations, and research, as well as theoretical questions concerning heat transfer and exchanger design.

— History

Incorporated in 1962, Heat Transfer Research, Inc. was chartered for the purpose of conducting application-oriented research on large-scale equipment in the general field of heat transfer and associated fluid flow, and converting the results into dependable design methods for industrial purposes. This was a depar-ture from the more typical method of companies conducting individual experiments based on university-derived theory. A few years later, the company moved from Bartlesville, Oklahoma, to Alhambra, California, and continued to grow in size and reputation. While in California, HTRI’s experiments were conducted on research units located at C. F. Braun, Inc., an HTRI member.

In 1990, HTRI relocated from California to College Station, Texas, where we built a multi-million dollar research facility with industrial-scale units. This strategic location also provides collaboration opportunities with the Texas Engineering Experiment Station (TEES) and Texas A&M University, one of the United States’ top engineering schools.

— Research Facilities
The HTRI Research Facility, developed in 1991, is a well-equipped multimillion dollar experimental facility. The site has four research units with supporting facilities and equipment. The facility can be customized to meet the changing needs of our customers. We also are available to conduct research and construct new rigs under contract.

The facility’s physical plant includes a 500-horsepower Johnson Boiler with a heating capacity of 17 million Btu/hour and a two-cell Marley Cooling Tower with a cooling capacity of 21 million Btu/hour. The machine shop includes welding equipment, a milling machine, lathe, drill press, band saw, and pipe threader. Instrument calibration and electrical tests are performed on site using a variety of testing components.

A laboratory also is on site to perform tests ensuring compliance with environmental regulations and to analyze test fluids from the research units.
– High Temperature Fouling Unit – provides data for defining process operating conditions and exchanger design features so that fouling of typical industrial fluids can be minimized. A wide variety of fluids can be tested, including gas oils and crude oils. The unit can operate at up to 1000 psig (6,895 kPa) and 800 °F (427 °C). The HTFU has two test sections that can operate simultaneously at different conditions.

– Multipurpose Boiling Unit – provides flow boiling heat transfer and pressure drop data for pure fluids, hydrocarbon mixtures, and alcohol-water mixtures. The MBU can operate over a range of conditions typical of industrial heat exchange processes.

– Single Phase Unit – (formerly known as the Plate Heat Exchanger Unit) provides information to develop heat transfer and pressure drop methods in single-phase flow. This unit has two plate-and-frame heat exchangers, a spiral heat exchanger, and a welded plate heat exchanger. The SPU can operate under a wide range of conditions with a variety of process fluids.

– Vertical In Tube Condensation Unit – provides data used to develop heat transfer and pressure drop methods for intube condensation. A variety of fluids including alcohols and hydrocarbon mixtures with and without inerts can be tested. The unit can operate from low vacuum to 450 psia.

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— Software
Software modeling and simulation tools, based on proprietary, relevant, and quality research, helps HTRI members design efficient heat exchangers.

HTRI software methods are derived from extensive research and documented in our publications. Many of the research programs are ongoing, leading to continual improvement of methods and simulations. All software accepts data in U.S. Customary, SI, and MKH units (except our Fired Heater program, which currently accepts U.S. Customary units only). Most programs have identical user interfaces and input structure: process conditions and physical properties are specified similarly, using the same data input lines. To ease interpretation of data, printed output follows a standard format in nearly all applications.

Interfaces between our software and other computer programs allow easy data transfer to process simulators, mechanical design systems, and database systems. Interfaces are available for software from such companies as AspenTech, B-JAC, Bryan Research & Engi-neering (BR&E), Physical Properties Data Service, ABB Lummus, SimSci, and others. HTRI is a member of the Process Data eXchange Institute (pdXi).

Before release, every HTRI program undergoes a rigorous testing process on several different platforms. These tests verify software results against HTRI’s proprietary research data. Test sets are extensive, making use of as many as 2,600 separate cases.

– ACE rates and simulates air-cooled heat exchangers and economizers. The program handles forced draft, induced draft, and “fans off” air-cooled heat exchangers. The economizer option also may be used to rate air preheater bundles. ACE is a fully incremental program.

– CST, using a fully incremental approach with HTRI’s latest pointwise correlations, designs shell-and-tube condensers from a set of process conditions and rates the performance of a geometrically specified condenser. Used with confidence since 1974, CST handles TEMA E, F, J, and X shells.

– FH simulates the behavior of fired heaters. Its capabilities include the solution of combustion and tube design problems and the simulation of cylindrical heaters, box heaters, and convection tube banks.

– IST rates the performance of geometrically specified shell-and-tube heat exchangers. A fully incremental program, IST contains HTRI’s latest pointwise equations for predicting condensing, boiling, and single-phase heat transfer and pressure drop. IST handles TEMA E, F, G, H, J, and X shells.

– PHE rates plate heat exchangers for liquid-phase applications. The program uses average local properties within each plate group. Various plate types may be selected from an automatic data bank or entered manually.

– RKH designs and rates kettle reboiler, column internal bundles, and horizontal thermosiphon reboilers.

– RTF designs and rates shell-and-tube vertical thermosiphons and vertical or horizontal forced-flow reboilers with the boiling on the tube side. The program also rates spiral plate reboilers. RTF is a fully incremental program.

– ST designs single-phase shell-and-tube heat exchangers from a set of process conditions. It also rates the performance of a geometrically specified exchanger. ST handles TEMA E, J, X, H, G, and F shells.

– ST Educational is an educational package for engineers wanting to learn about or review shell and tube heat exchanger calculations. Utilizing the full calculation engine from ST, this product provides companies and educational institutions with an accurate and user-friendly training tool.

– TWALL calculates the mean tubewall metal temperature in each tubepass for a TEMA E shell with fixed tubesheets. The TEMA Standards use these temperatures in their design equations.

– VIB conducts a rigorous analysis of the vibration of a single tube in a tube bundle. Additionally, VIB calculates natural frequencies for up to 15 modes.

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–Publications

This program centers around applied research and data taken from industrial-scale experimental rigs. Findings are published in the Design Manual, data books, and reports, all of which are available only to members. HTRI’s research programs provide the data and correlations which make our software the most accurate available—a distinct advantage over software based only on simulations and theory.

Over 120 reports are available to members. Multi-volume report books, data books, and our design manual provide you with an edge over your competitors. Some of our report areas include

– Agitated Vessels
– Air-cooled Heat Exchangers
– Boiling in Tubes
– Boiling in Kettle Reboilers
– Condensation on the Shell Side
– Crossflow Boiling outside Horizontal Tube Bundles
– Extended Surfaces
– Fouling
– General Studies in Boiling
– General Studies in Condensation
– Plate Heat Exchangers
– Flow-Induced Vibration in Shell-and-Tube Heat Exchangers
– Shellside Heat Transfer and Pressure Drop Methods
– Tubeside Enhanced Heat Transfer and Pressure Drop Methods
– Tubeside Heat Transfer and Pressure Drop Methods
– Two-phase Flow
Our data books provide you with raw data from experiments run on HTRI’s industrial-scale research units.

The Design Manual, our most used publication, provides you with a single source for our methods and correla-tions. This manual is also a great place to browse HTRI technology, providing you with an easy way to search for information from our reports. And if you need more detail, each report is referenced in the appropriate section of the Design Manual.

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In conjunction with meetings, hands-on software workshops and theoretical short courses are routinely conducted. Software workshops provide participants with practical information on the computer programs, an overview of the program’s inputs and outputs, example cases for discussion, and an actual problem to solve. The length of short courses varies by topic.

If regularly scheduled training sessions don’t meet the need, customized training can be arranged either at HTRI facilities in Texas or at a company’s site. Charges for customized training are based on the specific request.

Interaction is important both to members and to HTRI. For this reason, HTRI holds meetings and training sessions all over the world, providing a wide range of opportunities for members to:

– Help to shape the direction of future research and development by serving on subcommittees
– Learn new skills at our training and workshop sessions

Members are encouraged to interact with HTRI and each other through Communication Committees. These committees can be formed by any group with common goals, providing a formal means of communication.