Simulation of an oxygen membrane-based combined cycle power plant: Part-load operation with operational and material constraints

Energy and Environmental Science

Volumn 2, Issue 12, 2009, Pages 1310-1324

  Colombo, Konrad Eichhorn ^a   Bolland, Olav ^a   Kharton, Vladislav V ^b   Stiller, Christoph ^c  

^a NORWEGIAN UNIVERSITY OF SCIENCE AND TECHNOLOGY   (Norway)

^b UNIVERSITY OF AVEIRO   (Portugal)

^c Ludwig Bolkow Systemtechnik GmbH   (Germany)

Author keywords

[No Author keywords available]

Indexed keywords

A-STABILITY; CATALYTIC COMBUSTORS; CHEMICAL SPECIES; COMBINED-CYCLE EFFICIENCY; CONCENTRATED CO; CONSTANT ROTATIONAL SPEED; CONTROL STRATEGIES; CRITICAL REACTORS; DEGREE OF FREEDOM; DESIGN VALUE; EXIT TEMPERATURE; GAS TURBINE COMPRESSORS; LOAD CONTROL; LONG-TERM STORAGE; MASS FLOW; MEMBRANE MODULE; MEMBRANE REACTOR; MIXED-CONDUCTING MEMBRANES; NEAR STOICHIOMETRIC; OPERATING WINDOWS; OXYGEN CONCENTRATIONS; OXYGEN MEMBRANES; PART LOAD; PERFORMANCE MAPS; POWER PLANT OPERATIONS; PROCESS COMPONENT; TURBOMACHINERY COMPONENTS; VARIABLE GUIDE VANES; WALL TEMPERATURES;

BIOREACTORS; CARBON MONOXIDE; COMBINED CYCLE POWER PLANTS; COMBUSTION; COMBUSTION CHAMBERS; GAS INDUSTRY; GAS TURBINES; LOADS (FORCES); MEMBRANES; OXYGEN; SIMULATORS; TEMPERATURE; TURBOMACHINERY;

COMPRESSIBILITY OF GASES;

CARBON DIOXIDE; CATALYSIS; COMBUSTION; CONTROL SYSTEM; DESIGN; ENERGY BALANCE; MEMBRANE; NATURAL GAS; PERFORMANCE ASSESSMENT; POWER PLANT; SPATIAL DISTRIBUTION; STOICHIOMETRY; TEMPERATURE EFFECT; TURBINE;

EID: 72149112814     PISSN: 17545692     EISSN: 17545706     Source Type: Journal    
DOI: 10.1039/b910124a     Document Type: Article

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