The present invention discloses a solar heating system for cyclic heating of a swimming pool, relating to the swimming pool heating technology. The solar heating system structurally comprises a swimming pool, solar heaters and a water pump. Compared with the prior art, a solar panel is mainly added, and the water pump is installed on a solar heater in an integrated way that the water pump is connected with not only the solar heater as a waterway, but also the solar panel as a power supply circuit. After the above-mentioned improvements, the whole solar heating system has the advantages such as a compact structure, convenient disassembly and assembly, and miniaturization. Since the solar panel independently supplies power to the water pump, the solar heating system can be used normally in an outdoor place far away from a mains socket. The application place is not restricted with wide application scope.

Various embodiments of the present disclosure relate to systems and processes for collecting solar energy. According to particular embodiments, a solar collector device comprises a primary reflector, and a receiver assembly mounted on a frame structure. The receiver assembly comprises a heat transfer tube. The primary reflector comprises an elongated curved mirror mounted on a structural backing that is rotatably coupled to the frame structure such that the primary reflector may pivot around a pivot axis. The receiver assembly and/or the primary reflector may translate along the frame structure in a direction that is parallel to the pivot axis of the primary reflector. The one or more primary reflectors reflect light focused upon the receiver assembly such that heat energy from the reflected light is transferred to a heat transfer fluid in the heat transfer tube.

A modular, solar energy system comprising one or more modular solar panels. The solar panels include a pair of general planar, plates that are secured together to form a narrow channel therebetween for the circulation of a liquid. The solar panels have inlet and outlet fluid lines in fluid communication via manifolds with a cold fluid supply line and a warm fluid return line, respectively. The plates are preferably constructed of aluminum and one plate has a photovoltaic cell matrix affixed thereto to face the sun. The plates have dividers or partitions that enhance the heat transfer characteristics with respect to the liquid flowing though the channel between the plates.

A light-concentrating, solar system, comprising: a first Fresnel lens (111) provided with at least one tooth face, wherein each tooth face contains at least one Fresnel unit; two reflective faces (112, 113) arranged to enable incident sunlight to converge via the first Fresnel lens (111), and then to irradiate to a first reflective face (112), and at least part of the incident sunlight to be reflected onto a second reflective face (113) by the first reflective face (112); and a photovoltaic panel (114) arranged to enable at least part of the sunlight reflected by the second reflective face (113) to directly irradiate to or be led to irradiate to the photovoltaic panel (114). Since a twice-reflection structure is adopted, on one hand, the system can provide a higher light-concentration ratio; on the other hand, the height of the system can be reduced; and at the same time, a structural design of the system has better flexibility, so that a peripheral design, such as heat dissipation or heat energy utilization, of a photovoltaic panel can be performed more easily.

Provided is a solar collector that captures and utilizes solar energy and includes a plurality of vacuum tubes which are disposed by extending horizontally and are disposed parallel to each other with a predetermined distance; and a reflection plate having a substantially planar shape, which reflects solar light on an opposite side of the sun with respect to the plurality of vacuum tubes, in which the reflection plate includes a reflection surface having a serrated section at a corresponding position between vacuum tubes adjacent to each other, and in the reflection surface, one face of a serration forms a first reflection surface that reflects the solar light to the vacuum tube on a lower side among the vacuum tubes adjacent to each other.

The described embodiments provide thermal energy via solar powered heat exchangers. This energy can be implemented to heat hot water or heat residential/commercial structures. Parallel mounted vacuum insulated tubes heat water within a geometric heat transfer piping system. This thermal energy is transferred via a piping system to an insulated tank. A digital controller monitors and controls the temperature of the water within the system as well as provides frost/freezing protection. An electrical active pumping system is connected to the digital controller to circulate water within the solar heat exchanger. The electric active pump can be connected to a solar photovoltaic (electric) panel for reliable and uninterrupted heat/hot water delivery.

A modular integrated thermal-electric roofing system is disclosed. The system may include a thermal collector system configured with a photovoltaic system. The thermal collector system may include a liquid flowing through thermal tubing that may be heated by the sun. A pump and thermal control system may extract thermal energy from the liquid. A series of photovoltaic tiles may be configured on top of the thermal tubing to collect solar energy and convert it into electricity, and to aid in the heating of the thermal tubing. On doing so, the thermal tubing may cool the photovoltaic tiles. The system may be modular for easy installation. The system may also be mounted onto a support structure and may be portable and/or transportable.

A hybrid solar panel, comprising a photovoltaic panel coupled with transparent liquid thermal collector filled with coolant. Role of heat adsorber is coolant selectively transparent in the range of 400-1100 nm. Such panel is coupled with thermal collector by lamination.

A multi-function solar panel, the panel being of the tilted tray type which is divided into three chambers, one chamber being used for electricity generation, and cooling of the PV panel and partial preheating of the feed water to a still, one for processing the feed water to produce potable water and the other for water storage and other ancillary devices used in the production process and PAYG functionality of the multi-function solar panel.

Solar thermal units and methods of operating solar thermal units for the conversion of solar insolation to thermal energy are provided. In some examples, solar thermal units have an inlet, and a split flow of heat absorbing fluid to either side of the solar thermal unit, along a first fluid flow path and a second fluid flow path. Optionally, one or more photovoltaic panels can be provided as part of the solar thermal unit, which may convert solar insolation to electric power that may be used by a system connected to the solar thermal unit.