A multifunction flat plate heat exchanger including a heat exchanging flat plate, a spectrum selectivity absorption layer, a light transmissive layer, at least one heat-conductive structure, and at least one airflow driving device is provided. The heat exchanging flat plate has a first plate surface, a second plate surface and a pipe tunnel located between the first plate surface and the second plate surface. The spectrum selectivity absorption layer covers the first plate surface. The light transmissive layer covers the spectrum selectivity absorption layer, and the light transmissive layer and the first plate surface are respectively located at two opposite sides of the spectrum selectivity absorption layer. The heat-conductive structure is disposed on the second plate surface. The airflow driving device is disposed at one side of the heat exchanging flat plate and the heat-conductive structure.

An energy collector is disclosed. The energy collector contains an absorber and a working fluid. The working fluid is held in a state of two-phase equilibrium to minimize sensible heating and thus heat losses to the environment. The energy collector may be held under a vacuum to further prevent heat losses to the ambient environment. One or more energy collectors may be connected to other energy collectors, end uses, or thermal energy storage.

An energy collector is disclosed. The energy collector contains an absorber and a working fluid. The working fluid is held in a state of two-phase equilibrium to minimize sensible heating and thus heat losses to the environment. The energy collector may be held under a vacuum to further prevent heat losses to the ambient environment. One or more energy collectors may be connected to other energy collectors, end uses, or thermal energy storage.

A hybrid photovoltaic-thermal system provides co-generation of electrical energy and thermal energy. Electrical energy is efficiently generated by photovoltaic panels that are cooled by heat exchangers attached thereto, and the cooling of the photovoltaic panels improves the energy output efficiency of the photovoltaic panels. The heat exchangers flow fluid through its channels, and the fluid collects heat from the photovoltaic panels to which the heat exchangers are attached. The heated fluid is then received at and stored in a thermal battery. The thermal battery can be a fluid tank that encourages the fluid to retain the heat collected from the photovoltaic panels. The thermal battery can then supply the heated fluid to thermal loads as thermal energy.

A hybrid photovoltaic-thermal system provides co-generation of electrical energy and thermal energy. Electrical energy is efficiently generated by photovoltaic panels that are cooled by heat exchangers attached thereto, and the cooling of the photovoltaic panels improves the energy output efficiency of the photovoltaic panels. The heat exchangers flow fluid through its channels, and the fluid collects heat from the photovoltaic panels to which the heat exchangers are attached. The heated fluid is then received at and stored in a thermal battery. The thermal battery can be a fluid tank that encourages the fluid to retain the heat collected from the photovoltaic panels. The thermal battery can then supply the heated fluid to thermal loads as thermal energy.

A heat pipe panel comprising a conductive material block defining a plurality of channels or pathways disposed within the material block, fluid disposed within the plurality of channels or pathways, a dry coupling having a conductive outer surface and an interior chamber in fluid communication with the plurality of channels or pathways, a conduit having sockets configured and dimensioned to receive the dry coupling such that heat transfer fluid within the conduit is capable of being heated by conduction from the conductive surface.

A solar thermal collector for heating a fluid with absorbed solar thermal energy from solar radiations is provided. The solar thermal collector comprises an inlet configured to supply the fluid into the solar thermal collector, an outlet configured to evacuate the fluid from the solar thermal collector, and a solar absorber having an absorber plate and a base plate. The absorber plate has an absorber plate perimeter and an absorbing surface configured for absorbing the solar thermal energy from solar radiations. The base plate is connected to the absorber plate along the entire absorber plate perimeter so as to define a sealed cavity. The base plate and the absorber plate are connected at a plurality of contact points distributed so as to create an array of junctures across the sealed cavity, thereby allowing the fluid to circulate throughout the sealed cavity when flowing from the inlet to the outlet.

A solar thermal collector for heating a fluid with absorbed solar thermal energy from solar radiations is provided. The solar thermal collector comprises an inlet configured to supply the fluid into the solar thermal collector, an outlet configured to evacuate the fluid from the solar thermal collector, and a solar absorber having an absorber plate and a base plate. The absorber plate has an absorber plate perimeter and an absorbing surface configured for absorbing the solar thermal energy from solar radiations. The base plate is connected to the absorber plate along the entire absorber plate perimeter so as to define a sealed cavity. The base plate and the absorber plate are connected at a plurality of contact points distributed so as to create an array of junctures across the sealed cavity, thereby allowing the fluid to circulate throughout the sealed cavity when flowing from the inlet to the outlet.

A hybrid photovoltaic-thermal system provides co-generation of electrical energy and thermal energy. Electrical energy is efficiently generated by photovoltaic panels that are cooled by heat exchangers attached thereto, and the cooling of the photovoltaic panels improves the energy output efficiency of the photovoltaic panels. The heat exchangers flow fluid through its channels, and the fluid collects heat from the photovoltaic panels to which the heat exchangers are attached. The heated fluid is then received at and stored in a thermal battery. The thermal battery can be a fluid tank that encourages the fluid to retain the heat collected from the photovoltaic panels. The thermal battery can then supply the heated fluid to thermal loads as thermal energy.

A hybrid photovoltaic-thermal system provides co-generation of electrical energy and thermal energy. Electrical energy is efficiently generated by photovoltaic panels that are cooled by heat exchangers attached thereto, and the cooling of the photovoltaic panels improves the energy output efficiency of the photovoltaic panels. The heat exchangers flow fluid through its channels, and the fluid collects heat from the photovoltaic panels to which the heat exchangers are attached. The heated fluid is then received at and stored in a thermal battery. The thermal battery can be a fluid tank that encourages the fluid to retain the heat collected from the photovoltaic panels. The thermal battery can then supply the heated fluid to thermal loads as thermal energy.