The Experts below are selected from a list of 291255 Experts worldwide ranked by ideXlab platform
Olaf Kolditz - One of the best experts on this subject based on the ideXlab platform.
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multi physical continuum models of thermochemical heat storage and transformation in porous media and powder beds a review
Applied Energy, 2016Co-Authors: Thomas Nagel, Steffen Beckert, Christoph Lehmann, Roger Glaser, Olaf KolditzAbstract:Current climate, environmental and energy policies aim at a decarbonisation of the energy sector by a transition to renewable energies on the one hand and at an increased energy efficiency on the other hand. Thereby they stimulate the interest in space-, cost-, and energy-efficient heat storage technologies. Thermochemical conversion is an attractive candidate technology for heat storage fulfilling these efficiency requirements. The design of practically any complex engineered system is accompanied by theoretical analyses based on model representations. Thus, numerical Modelling is particularly important for thermochemical heat storage systems to help realise their potential and to advance the technology from the laboratory to a commercial setting. This article reviews Modelling Work in the context of heat storage and transformation aimed at capturing the coupled multi-physical processes that are relevant to the simulation of thermochemical heat storage in a space- and time-resolved manner.
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Multi-physical continuum models of thermochemical heat storage and transformation in porous media and powder beds—A review
Applied Energy, 2016Co-Authors: Thomas Nagel, Steffen Beckert, Christoph Lehmann, Roger Glaser, Olaf KolditzAbstract:Current climate, environmental and energy policies aim at a decarbonisation of the energy sector by a transition to renewable energies on the one hand and at an increased energy efficiency on the other hand. Thereby they stimulate the interest in space-, cost-, and energy-efficient heat storage technologies. Thermochemical conversion is an attractive candidate technology for heat storage fulfilling these efficiency requirements. The design of practically any complex engineered system is accompanied by theoretical analyses based on model representations. Thus, numerical Modelling is particularly important for thermochemical heat storage systems to help realise their potential and to advance the technology from the laboratory to a commercial setting. This article reviews Modelling Work in the context of heat storage and transformation aimed at capturing the coupled multi-physical processes that are relevant to the simulation of thermochemical heat storage in a space- and time-resolved manner.
Thomas Nagel - One of the best experts on this subject based on the ideXlab platform.
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multi physical continuum models of thermochemical heat storage and transformation in porous media and powder beds a review
Applied Energy, 2016Co-Authors: Thomas Nagel, Steffen Beckert, Christoph Lehmann, Roger Glaser, Olaf KolditzAbstract:Current climate, environmental and energy policies aim at a decarbonisation of the energy sector by a transition to renewable energies on the one hand and at an increased energy efficiency on the other hand. Thereby they stimulate the interest in space-, cost-, and energy-efficient heat storage technologies. Thermochemical conversion is an attractive candidate technology for heat storage fulfilling these efficiency requirements. The design of practically any complex engineered system is accompanied by theoretical analyses based on model representations. Thus, numerical Modelling is particularly important for thermochemical heat storage systems to help realise their potential and to advance the technology from the laboratory to a commercial setting. This article reviews Modelling Work in the context of heat storage and transformation aimed at capturing the coupled multi-physical processes that are relevant to the simulation of thermochemical heat storage in a space- and time-resolved manner.
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Multi-physical continuum models of thermochemical heat storage and transformation in porous media and powder beds—A review
Applied Energy, 2016Co-Authors: Thomas Nagel, Steffen Beckert, Christoph Lehmann, Roger Glaser, Olaf KolditzAbstract:Current climate, environmental and energy policies aim at a decarbonisation of the energy sector by a transition to renewable energies on the one hand and at an increased energy efficiency on the other hand. Thereby they stimulate the interest in space-, cost-, and energy-efficient heat storage technologies. Thermochemical conversion is an attractive candidate technology for heat storage fulfilling these efficiency requirements. The design of practically any complex engineered system is accompanied by theoretical analyses based on model representations. Thus, numerical Modelling is particularly important for thermochemical heat storage systems to help realise their potential and to advance the technology from the laboratory to a commercial setting. This article reviews Modelling Work in the context of heat storage and transformation aimed at capturing the coupled multi-physical processes that are relevant to the simulation of thermochemical heat storage in a space- and time-resolved manner.
Christoph Lehmann - One of the best experts on this subject based on the ideXlab platform.
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multi physical continuum models of thermochemical heat storage and transformation in porous media and powder beds a review
Applied Energy, 2016Co-Authors: Thomas Nagel, Steffen Beckert, Christoph Lehmann, Roger Glaser, Olaf KolditzAbstract:Current climate, environmental and energy policies aim at a decarbonisation of the energy sector by a transition to renewable energies on the one hand and at an increased energy efficiency on the other hand. Thereby they stimulate the interest in space-, cost-, and energy-efficient heat storage technologies. Thermochemical conversion is an attractive candidate technology for heat storage fulfilling these efficiency requirements. The design of practically any complex engineered system is accompanied by theoretical analyses based on model representations. Thus, numerical Modelling is particularly important for thermochemical heat storage systems to help realise their potential and to advance the technology from the laboratory to a commercial setting. This article reviews Modelling Work in the context of heat storage and transformation aimed at capturing the coupled multi-physical processes that are relevant to the simulation of thermochemical heat storage in a space- and time-resolved manner.
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Multi-physical continuum models of thermochemical heat storage and transformation in porous media and powder beds—A review
Applied Energy, 2016Co-Authors: Thomas Nagel, Steffen Beckert, Christoph Lehmann, Roger Glaser, Olaf KolditzAbstract:Current climate, environmental and energy policies aim at a decarbonisation of the energy sector by a transition to renewable energies on the one hand and at an increased energy efficiency on the other hand. Thereby they stimulate the interest in space-, cost-, and energy-efficient heat storage technologies. Thermochemical conversion is an attractive candidate technology for heat storage fulfilling these efficiency requirements. The design of practically any complex engineered system is accompanied by theoretical analyses based on model representations. Thus, numerical Modelling is particularly important for thermochemical heat storage systems to help realise their potential and to advance the technology from the laboratory to a commercial setting. This article reviews Modelling Work in the context of heat storage and transformation aimed at capturing the coupled multi-physical processes that are relevant to the simulation of thermochemical heat storage in a space- and time-resolved manner.
Roger Glaser - One of the best experts on this subject based on the ideXlab platform.
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multi physical continuum models of thermochemical heat storage and transformation in porous media and powder beds a review
Applied Energy, 2016Co-Authors: Thomas Nagel, Steffen Beckert, Christoph Lehmann, Roger Glaser, Olaf KolditzAbstract:Current climate, environmental and energy policies aim at a decarbonisation of the energy sector by a transition to renewable energies on the one hand and at an increased energy efficiency on the other hand. Thereby they stimulate the interest in space-, cost-, and energy-efficient heat storage technologies. Thermochemical conversion is an attractive candidate technology for heat storage fulfilling these efficiency requirements. The design of practically any complex engineered system is accompanied by theoretical analyses based on model representations. Thus, numerical Modelling is particularly important for thermochemical heat storage systems to help realise their potential and to advance the technology from the laboratory to a commercial setting. This article reviews Modelling Work in the context of heat storage and transformation aimed at capturing the coupled multi-physical processes that are relevant to the simulation of thermochemical heat storage in a space- and time-resolved manner.
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Multi-physical continuum models of thermochemical heat storage and transformation in porous media and powder beds—A review
Applied Energy, 2016Co-Authors: Thomas Nagel, Steffen Beckert, Christoph Lehmann, Roger Glaser, Olaf KolditzAbstract:Current climate, environmental and energy policies aim at a decarbonisation of the energy sector by a transition to renewable energies on the one hand and at an increased energy efficiency on the other hand. Thereby they stimulate the interest in space-, cost-, and energy-efficient heat storage technologies. Thermochemical conversion is an attractive candidate technology for heat storage fulfilling these efficiency requirements. The design of practically any complex engineered system is accompanied by theoretical analyses based on model representations. Thus, numerical Modelling is particularly important for thermochemical heat storage systems to help realise their potential and to advance the technology from the laboratory to a commercial setting. This article reviews Modelling Work in the context of heat storage and transformation aimed at capturing the coupled multi-physical processes that are relevant to the simulation of thermochemical heat storage in a space- and time-resolved manner.
Steffen Beckert - One of the best experts on this subject based on the ideXlab platform.
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multi physical continuum models of thermochemical heat storage and transformation in porous media and powder beds a review
Applied Energy, 2016Co-Authors: Thomas Nagel, Steffen Beckert, Christoph Lehmann, Roger Glaser, Olaf KolditzAbstract:Current climate, environmental and energy policies aim at a decarbonisation of the energy sector by a transition to renewable energies on the one hand and at an increased energy efficiency on the other hand. Thereby they stimulate the interest in space-, cost-, and energy-efficient heat storage technologies. Thermochemical conversion is an attractive candidate technology for heat storage fulfilling these efficiency requirements. The design of practically any complex engineered system is accompanied by theoretical analyses based on model representations. Thus, numerical Modelling is particularly important for thermochemical heat storage systems to help realise their potential and to advance the technology from the laboratory to a commercial setting. This article reviews Modelling Work in the context of heat storage and transformation aimed at capturing the coupled multi-physical processes that are relevant to the simulation of thermochemical heat storage in a space- and time-resolved manner.
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Multi-physical continuum models of thermochemical heat storage and transformation in porous media and powder beds—A review
Applied Energy, 2016Co-Authors: Thomas Nagel, Steffen Beckert, Christoph Lehmann, Roger Glaser, Olaf KolditzAbstract:Current climate, environmental and energy policies aim at a decarbonisation of the energy sector by a transition to renewable energies on the one hand and at an increased energy efficiency on the other hand. Thereby they stimulate the interest in space-, cost-, and energy-efficient heat storage technologies. Thermochemical conversion is an attractive candidate technology for heat storage fulfilling these efficiency requirements. The design of practically any complex engineered system is accompanied by theoretical analyses based on model representations. Thus, numerical Modelling is particularly important for thermochemical heat storage systems to help realise their potential and to advance the technology from the laboratory to a commercial setting. This article reviews Modelling Work in the context of heat storage and transformation aimed at capturing the coupled multi-physical processes that are relevant to the simulation of thermochemical heat storage in a space- and time-resolved manner.
