Transient Three-Dimensional Heat Transfer Model of a Solar Thermochemical Reactor for H2O and CO2 Splitting Via Nonstoichiometric Ceria Redox Cycling

A transient three-dimensional heat transfer model is developed for a 3 kWth solar thermochemical reactor for H2O and CO2 splitting via two-step nonstoichiometric ceria cycling. The reactor consists of a windowed solar receiver cavity, counter-rotating reactive and inert cylinders, and insulated reactor walls. The counter-rotating cylinders allow for continuous fuel production and heat recovery. The model is developed to solve energy conservation equations accounting for conduction, convection, and radiation heat transfer modes, and chemical reactions. Radiative heat transfer is analyzed using a combination of the Monte Carlo ray-tracing method, the net radiation method, and the Rosseland diffusion approximation. Steady-state temperatures, heat fluxes, and nonstoichiometry are reported. A temperature swing of up to 401 K, heat recovery effectiveness of up to 95%, and solar-to-fuel efficiency of up to 5% are predicted in parametric studies.

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Transient Three-Dimensional Heat Transfer Model of a Solar Thermochemical Reactor for H2O and CO2 Splitting via Nonstoichiometric Ceria Redox Cycling

ASME 2013 7th International Conference on Energy Sustainability ◽

10.1115/es2013-18040 ◽

2013 ◽

Author(s):

Justin Lapp ◽

Wojciech Lipiński

Keyword(s):

Heat Transfer ◽

Heat Recovery ◽

Fuel Efficiency ◽

Three Dimensional ◽

Reactor Design ◽

Heat Transfer Model ◽

Heat Fluxes ◽

Transfer Model ◽

Rotating Cylinders ◽

Solar Receiver

A transient heat transfer model is developed for a solar reactor prototype for H2O and CO2 splitting via two-step non-stoichiometric ceria cycling. Counter-rotating cylinders of reactive and inert materials cycling between high and low temperature zones permit continuous operation and heat recovery. To guide the reactor design a transient three-dimensional heat transfer model is developed based on transient energy conservation, accounting for conduction, convection, radiation, and chemical reactions. The model domain includes the rotating cylinders, a solar receiver cavity, and insulated reactor body. Radiative heat transfer is analyzed using a combination of the Monte Carlo method, Rosseland diffusion approximation, and the net radiation method. Quasi-steady state distributions of temperatures, heat fluxes, and the non-stoichiometric coefficient are reported. Ceria cycles between temperatures of 1708 K and 1376 K. A heat recovery effectiveness of 28% and solar-to-fuel efficiency of 5.2% are predicted for an unoptimized reactor design.

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Heat Transfer Analysis of a Solid-Solid Heat Recuperation System for Solar-Driven Nonstoichiometric Redox Cycles

Journal of Solar Energy Engineering ◽

10.1115/1.4023357 ◽

2013 ◽

Vol 135 (3) ◽

Cited By ~ 63

Author(s):

Justin Lapp ◽

Jane H. Davidson ◽

Wojciech Lipiński

Keyword(s):

Heat Transfer ◽

Heat Recovery ◽

Radiation Heat Transfer ◽

Heat Transfer Analysis ◽

Transfer Model ◽

Reactive Material ◽

Redox Cycles ◽

Heat Recuperation ◽

Rotating Hollow Cylinder ◽

Solar Thermochemical

Heat transfer is predicted for a solid-solid heat recuperation system employed in a novel directly-irradiated solar thermochemical reactor realizing a metal oxide based nonstoichiometric redox cycle for production of synthesis gas from water and carbon dioxide. The system is designed for continuous operation with heat recuperation from a rotating hollow cylinder of a porous reactive material to a counter-rotating inert solid cylinder via radiative transfer. A transient heat transfer model coupling conduction, convection, and radiation heat transfer predicts temperatures, rates of heat transfer, and the effectiveness of heat recovery. Heat recovery effectiveness of over 50% is attained within a parametric study of geometric and material parameters corresponding to the design of a two-step solar thermochemical reactor.

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Heat Transfer Analysis of a Solid-Solid Heat Recuperation System for Solar-Driven Non-Stoichiometric Redox Cycles

ASME 2012 6th International Conference on Energy Sustainability, Parts A and B ◽

10.1115/es2012-91078 ◽

2012 ◽

Author(s):

Justin Lapp ◽

Jane Davidson ◽

Wojciech Lipiński

Keyword(s):

Heat Transfer ◽

Heat Recovery ◽

Radiation Heat Transfer ◽

Heat Transfer Analysis ◽

Transfer Model ◽

Reactive Material ◽

Redox Cycles ◽

Heat Recuperation ◽

Rotating Hollow Cylinder ◽

Solar Thermochemical

Heat transfer is analyzed numerically for a solid-solid heat recuperation system employed in a novel directly-irradiated solar thermochemical reactor realizing a metal oxide based non-stoichiometric redox cycle for production of synthesis gas from water and carbon dioxide. The system is designed for continuous operation with heat recuperation from a rotating hollow cylinder of a porous reactive material to a counter rotating inert solid cylinder via radiative transfer. A transient heat transfer model coupling conduction, convection, and radiation heat transfer modes is developed to predict temperatures of both components, rates of heat transfer, and the effectiveness of heat recuperation. Heat recovery effectiveness of over 50% is attained within a parametric study of geometric and material parameters corresponding to the design of a two-step solar thermochemical reactor.

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Improvement of Engine Heat-Transfer Calculation in the Three-Dimensional Simulation Using a Phenomenological Heat-Transfer Model

10.4271/2001-01-3601 ◽

2001 ◽

Cited By ~ 20

Author(s):

Marco Chiodi ◽

Michael Bargende

Keyword(s):

Heat Transfer ◽

Three Dimensional ◽

Heat Transfer Model ◽

Transfer Model ◽

Dimensional Simulation ◽

Heat Transfer Calculation

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Fast three-dimensional heat transfer model for computing internal temperatures in the bearing housing of automotive turbochargers

International Journal of Engine Research ◽

10.1177/1468087418804949 ◽

2018 ◽

Vol 21 (8) ◽

pp. 1286-1297 ◽

Cited By ~ 4

Author(s):

Antonio Gil ◽

Andrés Omar Tiseira ◽

Luis Miguel García-Cuevas ◽

Tatiana Rodríguez Usaquén ◽

Guillaume Mijotte

Keyword(s):

Heat Transfer ◽

Coke Formation ◽

Three Dimensional ◽

Heat Transfer Model ◽

Operating Conditions ◽

Thermal Design ◽

Working Fluid ◽

Transfer Model ◽

Lumped Model ◽

Bearing System

Each of the elements that make up the turbocharger has been gradually improved. In order to ensure that the system does not experience any mechanical failures or loss of efficiency, it is important to study which engine-operating conditions could produce the highest failing rate. Common failing conditions in turbochargers are mostly achieved due to oil contamination and high temperatures in the bearing system. Thermal management becomes increasingly important for the required engine performance. Therefore, it has become necessary to have accurate temperature and heat transfer models. Most thermal design and analysis codes need data for validation; often the data available fall outside the range of conditions the engine experiences in reality leading to the need to interpolate and extrapolate disproportionately. This article presents a fast three-dimensional heat transfer model for computing internal temperatures in the central housing for non-water cooled turbochargers and its direct validation with experimental data at different engine-operating conditions of speed and load. The presented model allows a detailed study of the temperature rise of the central housing, lubrication channels, and maximum level of temperature at different points of the bearing system of an automotive turbocharger. It will let to evaluate thermal damage done to the system itself and influences on the working fluid temperatures, which leads to oil coke formation that can affect the performance of the engine. Thermal heat transfer properties obtained from this model can be used to feed and improve a radial lumped model of heat transfer that predicts only local internal temperatures. Model validation is illustrated, and finally, the main results are discussed.

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