A solar plant including a solar field for production of steam, a turbine using steam, and an excess steam storage and draw off system. The system includes a latent heat thermal storage module and a liquid displacement thermal storage module including a liquid volume and a steam blanket. The modules are connected together so that the steam produced passes through the steam blanket before passing through the latent heat module, condensing, to be injected in the liquid volume, the lower part of the liquid volume being connected to the solar field and to an outlet of the turbine to let in or return cold liquid. The liquid volume acts as a liquid displacement reservoir.

A solar composite tube, including a solar vacuum tube having two open ends; a water path; an adsorbent; and an adsorbate. The solar vacuum tube includes an outer metal tube and an inner metal tube which are coaxially disposed inside the solar vacuum tube. The water path is formed between the outer metal tube and the solar vacuum tube; the adsorbent is disposed between the outer metal tube and the inner metal tube and is configured to exchange heat with water in the water path outside the outer metal tube; the inner metal tube includes a plurality of through holes; the adsorbate is disposed in the inner metal tube; and the adsorbate and the adsorbent form an adsorption-desorption working pair. The invention also provides a solar composite bed including a lower header, an upper header, and the solar composite tube.

An integral collector storage solar water heat collecting apparatus comprises an integral solar heat collecting and storage apparatus having one or more solar ray and ambient temperature heat absorbing and storage material(s) which hold said energy within an enclosure, said enclosure having within it one or more heat exchange coils with pressurized water to be heated for the end-user or client from said heat storage. Said heat collector is combined with other system components to provide heated water to users.

A solar cooking appliance comprises a solar heat collector for collecting and storing solar heat. A first solid heat storage and conducting material for storing and conducting solar heat, the solid heat storage and conducting material is placed within the solar heat collector, the solar heat collector heats the solid heat storage and conducting material to a temperature higher than the water boiling temperature. A heat insulated solar cooking utensil is positioned outside of the solar heat collector, having a cooking utensil and a heat insulation. A second heat-transferring and conducting material connected thermally to the first solid heat storage and conducting material to the heat insulated solar cooking utensil for transferring solar heat.

The method is for using solar power in an efficient manner. A solar concentrator is provided in operative engagement with a storage unit. The storage unit has at least one glass rod disposed therein and at least one sheet enclosing the storage unit. The solar concentrator receives solar power as sunrays and conveys the solar power to the glass rod disposed in the storage unit. The solar power is in the glass rod is converted to heat to heat to the storage unit. Gas flows between the storage unit and the sheets. The storage unit heats the gas. The gas flows to a heat exchanger to exchange heat with steam.

Thermocline storage tanks for solar power systems are disclosed. A thermocline region is provided between hot and cold storage regions of a fluid within the storage tank cavity. One example storage tank includes spaced apart baffles fixed relative to the tank and arranged within the thermocline region to substantially physically separate the cavity into hot and cold storage regions. In another example, a flexible baffle separated the hot and cold storage regions and deflects as the thermocline region shifts to accommodate changing hot and cold volumes. In yet another example, a controller is configured to move a baffle within the thermocline region in response to flow rates from hot and cold pumps, which are used to pump the fluid.

The disclosed technology includes converting solar energy to thermal energy and delivering heat for use in a process. A representative method includes transferring solar energy to a working fluid and transferring energy from the working fluid to a heating element positioned inside a heating well. The heating well contains a thermal energy storage substance (TESS). A controller controls the heating element, which is in thermal communication with the TESS. In some embodiments, the TESS releases and absorbs heat as latent heat, which reduces temperature variation in heat exchange between the heating well and the formation surrounding the heating well. In such embodiments, the TESS is positioned between the heating element and an outer casing of the heating well. In addition to heating wells, the disclosed technology can be applied to other processes involving heat delivery.

The integrated solar absorption heat pump system includes an absorption heat pump assembly (AHPA) having a generator, a condenser in fluid communication with the generator, an evaporator/absorber in fluid communication with the condenser and the generator, and a heat exchanger in communicating relation with the evaporator/absorber; a solar collector in fluid communication with the generator of the AHPA; a photovoltaic thermal collector in communicating relation with the evaporator/absorber of the AHPA; a plurality of pumps configured for pumping a fluid throughout the system to provide the desired heating or cooling; a power storage source, e.g., a solar battery, in communicating relation with the photovoltaic thermal collector; and a coil unit in communicating relation to the evaporator/absorber for receiving an air-stream. The absorption heat pump assembly can include an absorber and a solution heat exchanger.

A single thermal energy storage tank is used so that costs can be reduced and an installation space can also be reduced compared to a case where two tanks, i.e., a high temperature tank and a low temperature tank are provided. In addition, the single thermal energy storage tank includes a porous block so that passage of molten salt can be more easily performed and flow pressure drop can be reduced. In addition, the porous block is configured by stacking a plurality of unit blocks so that the capacity of the single thermal energy storage tank can be easily adjusted. Furthermore, a plurality of single thermal energy storage tanks are connected in parallel so that the plurality of single thermal energy storage tanks can be selectively used according to an operation load and thus the solar thermal power generation system can easily cope with the operation load.

A hybrid solar concentrator that utilizes one or more dielectric mirrors to isolate components of the solar spectrum compatible with specific PV band-gaps and to pass longer wavelengths through to a heat receiver, generating both electricity and heat from a single set of dual-axis heliostats.