Design and optimization of a natural gas-fired thermoelectric generator by computational fluid dynamics modeling

•A natural gas fired thermoelectric generator with 50W output power is designed.•Vertical layout with three functional regions: heating, combustion and active.•Original, simplified approach for modeling the global effects of combustion.•Five final design variables for optimization (max. output power...

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Vydáno v:Energy conversion and management Ročník 149; s. 1037 - 1047
Hlavní autoři: Bargiel, Paweł, Kostowski, Wojciech, Klimanek, Adam, Górny, Krzysztof
Médium: Journal Article
Jazyk:angličtina
Vydáno: Oxford Elsevier Ltd 01.10.2017
Elsevier Science Ltd
Témata:
Aerodynamics
air
Building codes
CAD
CFD
Computational fluid dynamics
Computational mathematics
Computer aided design
Computer applications
Configuration management
Design
Design optimization
Design parameters
Development projects
electric current
electric generators
Exhaust emissions
Exhaust gases
Flow channels
Fluid dynamics
fluid mechanics
Generators
heat
Heat transfer
Hydrodynamics
Island mode supply
Mathematical models
Natural gas
Numerical modeling
Optimization
Parameter estimation
Parameter identification
prototypes
R&D
Research & development
Response surface methodology
Studies
Target recognition
temperature
Temperature effects
Temperature gradients
Temperature requirements
Thermoelectric generators
Thermoelectricity
Numerical modeling
CFD
Island mode supply
Thermoelectricity
Heat transfer
Natural gas
Optimization
ISSN:0196-8904, 1879-2227
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Shrnutí:•A natural gas fired thermoelectric generator with 50W output power is designed.•Vertical layout with three functional regions: heating, combustion and active.•Original, simplified approach for modeling the global effects of combustion.•Five final design variables for optimization (max. output power).•Three candidate points on the response surface: simulated output 49.0–49.6W. The paper reports the results of the computational part of an ongoing research and development project aimed at designing and optimization of a thermoelectric generator fired with natural gas. The idea of the project is to provide an independent and reliable source of power in the power range of 50–100W for island-mode supply, tailored for remote objects of the natural gas distribution infrastructure which, for economic reason, are not connected to the electric grid. The device includes a burner as a heat source, flow channels for air and for exhaust gases and a set of thermoelectric modules generating electric current if subject to temperature difference. The pre-selected design configuration (type E) was subject to parametric optimization. A corresponding numerical model based on the Ansys/Fluent computational fluid dynamics code was built. The optimization procedure aims to maximize the temperature difference across the thermoelectric module in order to maximize the generated power output. Simultaneously, it is essential to maintain the hot-side temperature below the required technical limit of 320°C. First, thirteen design parameters (most of them concerning geometry) influencing the target function were identified. A central value and a possible range for each parameter have been set. Next, the partial impact of each parameter on the target function was found, and the set of the design parameters was limited to eight. Finally, only five parameters were estimated to be non-monotonically related to the generated power. The impact of the selected five parameters on the target function was investigated using a central composite design optimization plan. The set of points obtained in the multi-dimensional response surface was then limited to points meeting the imposed limitation of maximum temperature. Eventually, three candidate points (i.e. three sets of design parameters) have been proposed for the next stage of the project involving an experimental set-up for the design of the prototype.
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ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2017.05.030