A digital television recording method comprising: broadcasting a television program associated with a broadcaster set of parameters enabling access to a first set of predetermined portions of the program; operating an agent for determining whether to record the program and for associating with the program, upon recording of the program, an agent set of parameters enabling access to a second set of predetermined portions of the program; storing the program together with the broadcaster set of parameters and the agent set of parameters to generate an addressable program; retrieving at least a portion of the addressable program; displaying the at least a portion of the addressable program to a user; receiving from the user a user set of parameters enabling access to a third set of predetermined portions of the addressable program; editing the addressable program to include the user set of parameters enabling access to the third set of predetermined portions of the addressable program thereby generating an edited addressable program; and storing the edited addressable program.

Advanced television system

High temperature electrolysis in alkaline cells, solid proton conducting cells, and solid oxide cells.

A survey is made of high-temperature membranes and several possible applications of membrane reactors for integration in power generation cycles with CO2 capture. Current performance and limitations of relevant inorganic membranes are presented and discussed. Integrated H2, O2 or CO2 membrane separation is analysed and it is concluded that development of power plant concepts including membrane technology is not yet fully explored. Significant design optimisation would be required in order to identify efficient, feasible and environmentally sound technical solutions. In addition, further development and validation of performance of membranes in real applications are needed.

High-temperature membranes in power generation with CO2 capture

Es wird ein Brennstoffzellenstapel mit Zelleneinheiten bereitgestellt, die eine Sammelleitung, eine offene Endplatte, die an einer Seite der Zelleneinheiten angeordnet ist und einen Reaktionsgaseinlass und -auslass hat, die mit der Sammelleitung verbunden sind, und eine geschlossene Endplatte enthalten, die an der an der anderen Seite der Zelleneinheiten angeordnet ist und die Sammelleitung abschliest. Insbesondere enthalt die Endplatte eine erste schrage Oberflache, die die Stromung eines Reaktionsgases am Reaktionsgaseinlass und an der Sammelleitungs-Schnittstelle regelt. Ein erster Ausrichtungsvorsprung bildet die erste schrage Oberflache und richtet die Zelleneinheiten aus, und die geschlossene Endplatte enthalt eine zweite schrage Oberflache, die die Stromung des Reaktionsgases an der Sammelleitungs-Schnittstelle regelt. Auserdem bildet ein zweiter Ausrichtungsvorsprung die zweite schrage Oberflache und richtet die Zelleneinheiten entsprechend aus.

Fuel cell stack

Definition and sensitivity analysis of a finite volume SOFC model for a tubular cell geometry

The solid oxide fuel cell (SOFC) is a simple electrochemical device that operates at 1000°C, and is capable of converting the chemical energy in natural gas fuel to AC electric power at approximately 45% efficiency (net AC/LHV) when operating in a system at atmospheric pressure. Since the SOFC exhaust gas has a temperature of approximately 850°C, the SOFC generator can be synergistically integrated with a gas turbine (GT) engine generator by supplanting the turbine combustor and pressurizing the SOFC, thereby enabling the generation of electricity at efficiencies approaching 60% or more. Conceptual design studies have been performed for SOFC/GT power systems employing a number of the small recuperated gas turbine engines that are now entering the marketplace. The first hardware embodiment of a pressurized SOFC/GT power system has been built for Southern California Edison and is scheduled for factory acceptance tests beginning in Fall 1999 at the Siemens Westinghouse facilities in Pittsburgh, PA. The hybrid power cycle, the physical attributes of the hybrid systems, and their performance are presented and discussed.

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Tubular Solid Oxide Fuel Cell/Gas Turbine Hybrid Cycle Power Systems: Status

/pdf/tubular-solid-oxide-fuel-cell-gas-turbine-hybrid-cycle-power-3figotkpm0.pdf

Tubular solid oxide fuel cell/gas turbine hybrid cycle power systems - status

The conceptual design of a 20 MWe-class hybrid power generating system that integrates a Siemens Westinghouse pressurized solid oxide fuel cell generator with a Mercury 50 gas turbine is discussed. The Mercury 50 was designed and developed by Caterpillar/Solar Turbines during the U.S. Department of Energy (DOE) Advanced Turbine Systems (ATS) program, and the hybrid system design concept was evaluated during a recently completed project that was part of the DOE high efficiency fossil power plant (HEFPP) program. While achieving a high power system efficiency by the hybrid cycle approach was important, the focus of the design study was to select the solid oxide fuel cell (SOFC) generator capacity such that the low specific cost of the ATS gas turbine and the high efficiency of the more expensive pressurized solid oxide fuel cell (PSOFC) generator would combine optimally to produce an attractively low cost of electricity (COE) for the overall power system. The system cycle and physical characteristics are described; power, efficiency, and emissions estimates are presented; and estimates of system cost and COE are provided. In addition, two bottoming cycle options (steam turbine and ammonia turbine) are described, and performance and cost projections for each are reviewed.

A High-Efficiency Solid Oxide Fuel Cell Hybrid Power System Using the Mercury 50 Advanced Turbine Systems Gas Turbine

Pressurized solid oxide fuel cell (PSOFC)/micro gas turbine generator (MTG) hybrid power systems have the potential to generate electric power at high efficiency [circa 60% (net AC/LHV)] at multi-hundred kWe and multi-MWe capacities. Thus, good fuel economy and low CO2 emissions are positive system attributes, as are low NOx and SOx emissions due to the propensity of the SOFC for low NOx generation, the need for no firing of the gas turbine combustor during normal hybrid system power operations, and the use of desulfurized fuel. Exhaust temperatures are sufficiently high to enable the recovery of heat for steam/hot-water production, and system energy efficiencies of at least 80% are feasible. Work is ongoing at Siemens Westinghouse on three PSOFC/MTG power systems. Two, with 220 kWe and 300 kWe capacities, are proof-of-concept demonstration units. The 220 kWe PSOFC/MTG power system is in test at the National Fuel Cell Research Center, University of California-Irvine, and the 300 kWe system, which is currently being designed, will be demonstrated in two tests to be performed in Europe. The status of work on the 220 kWe and 300 kWe power systems is reviewed. The third system is to have capacity of at least 500 kWe. This system, which will be demonstrated also, is viewed as a prototype commercial product. The 500 kWe-class PSOFC/MTG concept is described and performance estimates are presented.Copyright © 2002 by ASME

Status of Pressurized SOFC/Gas Turbine Power System Development at Siemens Westinghouse

A pressurized fuel cell system (10), operates within a common pressure vessel (12) where the system contains fuel cells (22), a turbine (26) and a generator (28) where preferably, associated oxidant inlet valve (52), fuel inlet valve (56) and fuel cell exhaust valve (42) are outside the pressure vessel.

Stephen E. Veyo

Papers

Tubular Solid Oxide Fuel Cell/Gas Turbine Hybrid Cycle Power Systems: Status

Tubular solid oxide fuel cell/gas turbine hybrid cycle power systems - status

A High-Efficiency Solid Oxide Fuel Cell Hybrid Power System Using the Mercury 50 Advanced Turbine Systems Gas Turbine

Status of Pressurized SOFC/Gas Turbine Power System Development at Siemens Westinghouse

Single module pressurized fuel cell turbine generator system