A device for supplying cold energy, heat energy and electrical energy by efficiently converting renewable deep-space energies includes a solar-energy conversion device, a radiation refrigeration device, a rotary bracket, a dip-angle adjustment component, and a support base. The solar-energy conversion device and the radiation refrigeration device are connected to the rotary bracket in a mutually perpendicular manner, and the rotary bracket is connected to the dip-angle adjustment component which is connected to the support base. The dip-angle adjustment component is configured to adjust a dip angle between the rotary bracket and a horizontal plane, and the rotary bracket is configured to drive the solar-energy conversion device and the radiation refrigeration device to rotate, such that a sunward side of the solar-energy conversion device is always perpendicular to light rays irradiated by the sun, and a reflective surface of the radiation refrigeration device is always parallel to the light rays.

The disclosure discloses a flat-plate water-heating photovoltaic/thermal module and a production process thereof. The flat-plate water-heating photovoltaic/thermal module includes a frame, wherein the lower surface of the frame is provided with a heat preservation back plate, the upper surface of the frame is sequentially laminated with a glass cover plate, a first photovoltaic cell laminating adhesive, a photovoltaic cell slice, a second photovoltaic cell laminating adhesive, a transparent back plate, a third photovoltaic cell laminating adhesive and a heat absorbing component from top to bottom, and a heat preservation cavity is formed between the heat preservation back plate and the heat absorption part.

A thermal cell panel system for heating and cooling using a refrigerant includes a plurality of solar thermal cell chambers, and a piping network for a flow of the refrigerant through the plurality of solar thermal cell chambers. In addition, the system includes a compressor having a motor coupled to a variable frequency drive (“VFD”), where the compressor is coupled to the piping network upstream of the plurality of solar thermal cell chambers and the VFD is configured to adjust a speed of the motor in response to the pressure of the refrigerant within the plurality of solar thermal cell chambers. The piping network includes an inlet manifold coupled to the inlet of each solar thermal cell chamber, and an outlet manifold coupled to the outlet of each solar cell chamber.

A hybrid solar thermal and photovoltaic panel based cogeneration system and heat pump and non-tracking non-imaging solar concentrator based CSP stabilized power generation system comprises a hybrid solar thermal and photovoltaic panel based cogeneration subsystem to cogenerate electricity and heat, a heat pump subsystem to raise the temperature of the cogenerated heat, a non-tracking non-imaging solar concentrator based CSP subsystem to further upgrade the cogenerated thermal energy, a thermal storage to store the cogenerated heat, and a thermal power regeneration system, to take the stored cogenerated heat to regenerate power. The power output of the cogeneration subsystem supplemented with the power output from the thermal power regeneration system realizes stabilized power output.

A portable solar powered pool heater comprising a housing, a hose, a controller, a solar panel and at least one leg having a first position for supporting the housing above a surface, and a second position disposed inside of the housing. This heater can include a hinge, wherein the leg comprises a leg that is coupled to the housing via the hinge. In one embodiment the leg comprises a telescoping leg having a first leg, and a second leg wherein said second leg is telescoping inside of the first leg.

A portable solar heating device that having a mat shaped flexible main body with bounded edges, the main body including a front flexible layer formed of a material transparent to electromagnetic radiation, a back flexible heat insulating layer, and a flexible electromagnetic radiation absorbing layer located between the front and back layer, the electromagnetic radiation absorbing layer including a plurality of protrusions extending towards the front flexible layer, at least one allowing ambient fluids into a fluid heating chamber located between the front layer and the electromagnetic radiation absorbing layer and at least one outlet allowing heated fluids to escape from the chamber, an electric fan attached to the outlet to assist in moving heated fluids out from the chamber, and at least one solar cell for powering the electric fan.

A Multiple Bifacial Photovoltaic Transparent Panels Thermal Triangles Reflective Minors Ensemble system which is configured to be oriented towards the sun and relative to the horizon, the mirrors reflecting the sunray to the bifacial PV panels front, back and underside faces. There is a plurality of rhombus or trapeze shaped sunray path openings, mounted on a small footprint, above a two axes tracking mechanism. Further, an Micro-Electric Power Station MEPS capable of obtaining energy from a plurality of Rear/Back and side sun ray reflectors sources, located in between various bifacial photovoltaic transparent solar thermal panels. The reflector sources may include an integrated laminated mirror film around the inside of a casing/envelope of a rhombus thin (e.g. glass) box or of transparent sunrays magnifying concentrator envelope balloon. The MEPS facility may be mounted above streets and traffic junctions, on a structure which may be referred to as Micro-Grid Electric Pylons MGEP.

A thermal cell panel system for heating and cooling using a refrigerant includes a plurality of solar thermal cell chambers, and a piping network for a flow of the refrigerant through the plurality of solar thermal cell chambers. In addition, the system includes a compressor having a motor coupled to a variable frequency drive (“VFD”), where the compressor is coupled to the piping network upstream of the plurality of solar thermal cell chambers and the VFD is configured to adjust a speed of the motor in response to the pressure of the refrigerant within the plurality of solar thermal cell chambers. The piping network includes an inlet manifold coupled to the inlet of each solar thermal cell chamber, and an outlet manifold coupled to the outlet of each solar thermal cell chamber.

A thermal cell panel system for heating and cooling using a refrigerant includes a plurality of solar thermal cell chambers, and a piping network for a flow of the refrigerant through the plurality of solar thermal cell chambers. In addition, the system includes a compressor having a motor coupled to a variable frequency drive (“VFD”), where the compressor is coupled to the piping network upstream of the plurality of solar thermal cell chambers and the VFD is configured to adjust a speed of the motor in response to the pressure of the refrigerant within the plurality of solar thermal cell chambers. The piping network includes an inlet manifold coupled to the inlet of each solar thermal cell chamber, and an outlet manifold coupled to the outlet of each solar thermal cell chamber.

A solar collector with reflecting surfaces according to the present invention prevents overheating of the solar collector by reflecting the radiation in a way that the light beams, by means of a first transparent surface, are corrected to the preferred angle and further directed towards channels. On a second transparent surface the beams are directed again and on a third transparent surface the light beams are reflected if in the channels is air. If the working fluid flows through the channels, on the third surface there is no reflection, so the light beams pass through the opaque part of an absorber where the solar radiation is converted into the thermal energy that is then removed by the working fluid.