A photovoltaic chip is designed to receive light energy from a light box arranged above it. The light can be sunlight guided by optical-fibers. For ease of replacement the photovoltaic chips can be supported in a carrier which is movably housed in a block. The blocks are housed on racks and are movable for ease of repair and replacement.

A photovoltaic chip is designed to receive light energy from a light box arranged above it. The light can be sunlight guided by optical-fibers. For ease of replacement the photovoltaic chips can be supported in a carrier which is movably housed in a block. The blocks are housed on racks and are movable for ease of repair and replacement.

High efficiency heat management devices for use with a component, are disclosed and include: at least one porous filled channel configuration component or at least one foam filled channel configuration component, wherein the at least one porous filled channel configuration component or at least one foam filled channel configuration component comprises a channel base and a surface; at least one jet impingement of at least one thermal management liquid or gas; at least one jet inlet, wherein the at least one jet inlet directs the at least one jet impingement of a liquid or a gas onto the surface of the at least one porous filled channel configuration component or at least one foam filled channel configuration component; and at least one thermal management liquid or gas exit channel.

A thermal pump system energized by a daytime heating phase and a night time cooling phase associated with a naturally occurring environmental heating and cooling cycle includes a hydraulic fluid source, a thermal fluid expansion chamber having a fixed internal volume, and a hydraulic accumulator at least partially filled by a compressible gas. A first unidirectional flow valve connected to a first duct permits flow only out of the hydraulic fluid source during the night time cooling phase. A second unidirectional flow valve connected to a second duct permits flow only out of the thermal fluid expansion chamber upon expansion of the hydraulic fluid trapped in the thermal fluid expansion chamber due to heating during the daytime heating phase. The thermal fluid expansion chamber has a thermally conductive wall communicating thermal energy from the naturally occurring heating and cooling cycle to the hydraulic fluid trapped in the fixed internal volume.

The problem is solved as follows: the photovoltaic thermal module consists of a photovoltaic module, on the rear side of which facing away from the sun a heat exchanger is located. The heat exchanger consists of at least one conduit through which heat transfer fluid flows. The conduits (which are optionally enlarged by heat transfer surfaces) are disposed at a distance from the photovoltaic module such that they are in good contact with the ambient air and also thermally conductively connected to the photovoltaic module. The surface area and the amount of heat exchange to the ambient air are increased by the main orientation of the surfaces of the heat exchanger running transversely to the PV module. As a result, a good flow of ambient air around both the heat exchanger and the rear side of the PV module is made possible. The PVT module is used, in particular, in combination with heat pumps for supplying heat to and/or cooling buildings.

The problem is solved as follows: the photovoltaic thermal module consists of a photovoltaic module, on the rear side of which facing away from the sun a heat exchanger is located. The heat exchanger consists of at least one conduit through which heat transfer fluid flows. The conduits (which are optionally enlarged by heat transfer surfaces) are disposed at a distance from the photovoltaic module such that they are in good contact with the ambient air and also thermally conductively connected to the photovoltaic module. The surface area and the amount of heat exchange to the ambient air are increased by the main orientation of the surfaces of the heat exchanger running transversely to the PV module. As a result, a good flow of ambient air around both the heat exchanger and the rear side of the PV module is made possible. The PVT module is used, in particular, in combination with heat pumps for supplying heat to and/or cooling buildings.

A photovoltaic chip is designed to receive light energy from a light box arranged above it. The light can be sunlight guided by optical-fibers. For ease of replacement the photovoltaic chips can be supported in a carrier which is movably housed in a block. The blocks are housed on racks and are movable for ease of repair and replacement.

A photovoltaic chip is designed to receive light energy from a light box arranged above it. The light can be sunlight guided by optical-fibers. For ease of replacement the photovoltaic chips can be supported in a carrier which is movably housed in a block. The blocks are housed on racks and are movable for ease of repair and replacement.

The present technology is directed generally to phase change materials for cooling enclosed electronic components, including for solar energy collection, and associated systems and methods. In particular embodiments, a system directs warm air through an airflow path in thermal communication with a phase change material to liquefy the phase change material and cool the air. The system also directs the cool air into thermal communication with electronic components to cool the electronic components via conduction and/or convection.

The present technology is directed generally to phase change materials for cooling enclosed electronic components, including for solar energy collection, and associated systems and methods. In particular embodiments, a system directs warm air through an airflow path in thermal communication with a phase change material to liquefy the phase change material and cool the air. The system also directs the cool air into thermal communication with electronic components to cool the electronic components via conduction and/or convection.