The invention relates to a method which comprises making a hole in a metallic support of an absorber tube, putting a vacuum pump in fluid communication with the chamber of the absorber tube by means of the hole, actuating the vacuum pump to generate a vacuum in the chamber until reaching a predetermined vacuum threshold, and introducing an inert gas inside the chamber and performing a plurality of sweeps with said inert gas, removing hydrogen from the chamber, allowing to thus reduce or remove the accumulation of hydrogen in said chamber, such that, as a result, at least part of the hydrogen absorption capacity of the getter material is recovered.

According to an embodiment, a transparent solar cell, a photovoltaic system including the transparent solar cell, and a method for manufacturing the transparent solar cell are provided. The transparent solar cell comprises a substrate, an adhesive layer formed on the substrate, a metal layer formed on the adhesive layer, a solar cell layer formed on the metal layer, and a coating layer formed on the solar cell layer. The solar cell layer and the metal layer include a plurality of holes having a predetermined diameter.

The invention provides in some aspects a thermal energy collection system comprising a first solar collector through which a first heat transfer fluid flows to absorb energy from sunlight as it passes through the first solar collector, and a second solar collector that collects energy from sunlight that has passed through the first solar collector. The first heat transfer fluid of the thermal energy collection system according to these aspects of the invention is in thermal coupling with the first solar collector, but not with the second solar collector. In other aspects, the invention provides a radiator system, comprising a multi-wall panel, an interior of which is in fluid coupling with, and that forms part of, a fluid circuit through which a first heat transfer fluid flows. A reflective surface is disposed in a vicinity of a second face of the multi-wall panel. Still other aspects of the invention provide a reflective film solar energy collector and a solar energy absorber.

The invention provides in some aspects a thermal energy collection system comprising a first solar collector through which a first heat transfer fluid flows to absorb energy from sunlight as it passes through the first solar collector, and a second solar collector that collects energy from sunlight that has passed through the first solar collector. The first heat transfer fluid of the thermal energy collection system according to these aspects of the invention is in thermal coupling with the first solar collector, but not with the second solar collector. In other aspects, the invention provides a radiator system, comprising a multi-wall panel, an interior of which is in fluid coupling with, and that forms part of, a fluid circuit through which a first heat transfer fluid flows. A reflective surface is disposed in a vicinity of a second face of the multi-wall panel. Still other aspects of the invention provide a reflective film solar energy collector and a solar energy absorber.

An urban concentrated solar power for mounting on a roof top is provided. The urban concentrated solar power has a heat receiver has a non-circular duct that distinguishes an insulated area with an insulation layer on the outer surface of the non-circular duct and a non-insulated area. The non-circular duct contains a heat transferring fluid which can reach temperatures of at least 500 degrees Celsius. A parabolic trough with an aperture of below 2 meters concentrates sunlight onto the non-insulated area of the non-circular duct of the heat receiver. The heat receiver can be placed in a glass tube. Due to roof top mounting the electricity can be generated in proximity of the user and as a result decrease net congestion. The low-cost heat receiver design will make electricity generated by urban CSP competitive with electricity from fossil fuel plants and PV combined with lithium-ion battery storage.

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 concentrated solar energy collection system includes an array of heliostats and a solar receiver that further includes a plurality of tubes having at least one inlet and at least one outlet for carrying a heat transfer fluid (HTF). A flow control arrangement is provided for controlling the flow of HTF through the tubes. This includes at least one radiation sensor such as a pyranometer for sensing values representative of the aggregate solar radiation falling on the solar receiver via the heliostats. At least one temperature sensor measures input temperature of the HTF at or near the inlet. A controller coupled to the radiation and temperature sensors regulates the outlet temperature of the HTF by controlling the flow of HTF through the tubes via the flow control arrangement. A pressure differential sensor arrangement measures pressure differential across the flow control arrangement, providing an input to the controller.

A concentrated solar energy collection system includes an array of heliostats and a solar receiver that further includes a plurality of tubes having at least one inlet and at least one outlet for carrying a heat transfer fluid (HTF). A flow control arrangement is provided for controlling the flow of HTF through the tubes. This includes at least one radiation sensor such as a pyranometer for sensing values representative of the aggregate solar radiation falling on the solar receiver via the heliostats. At least one temperature sensor measures input temperature of the HTF at or near the inlet. A controller coupled to the radiation and temperature sensors regulates the outlet temperature of the HTF by controlling the flow of HTF through the tubes via the flow control arrangement. A pressure differential sensor arrangement measures pressure differential across the flow control arrangement, providing an input to the controller.

Multi-effect-distillation (MED) systems of several designs are among the most energy-efficient technologies used in seawater desalination, throughout the world today; typically, energy consumed being <15 kWh / m^3 distillate produced. One caveat in all MED systems is the disposition of the brine-waste reject product with respect to the environment; per unit volume fresh water produced, typically, two units of waste brine media with salinity in excess of 50 g/l, must be dispersed responsibly. Herein is described a MEDX design coupled with thermal-vapor-expanders (TVX) utilizing energy recovered in said brine-waste media, wherein salt-gradient-solar-ponds (SGSP) are used alongside molten salts single-temperature thermal energy storage (SITTES) as principle thermal energy sources (TES) redirected to the MEDX plant, 24/7. Quantifiable electric power production and an additional ~2500 m^3/d distillate, is attained above that produced in a hypothetical 20-effect MEDX plant thru recycling said waste brines into said 20-effect MEDX plant, integrating both flash-chambers (FC) and negative pressure tanks (NPT) in the fore and end-stages, respectively of said MEDX plant.

Multi-effect-distillation (MED) systems of several designs are among the most energy-efficient technologies used in seawater desalination, throughout the world today; typically, energy consumed being <15 kWh / m^3 distillate produced. One caveat in all MED systems is the disposition of the brine-waste reject product with respect to the environment; per unit volume fresh water produced, typically, two units of waste brine media with salinity in excess of 50 g/l, must be dispersed responsibly. Herein is described a MEDX design coupled with thermal-vapor-expanders (TVX) utilizing energy recovered in said brine-waste media, wherein salt-gradient-solar-ponds (SGSP) are used alongside molten salts single-temperature thermal energy storage (SITTES) as principle thermal energy sources (TES) redirected to the MEDX plant, 24/7. Quantifiable electric power production and an additional ~2500 m^3/d distillate, is attained above that produced in a hypothetical 20-effect MEDX plant thru recycling said waste brines into said 20-effect MEDX plant, integrating both flash-chambers (FC) and negative pressure tanks (NPT) in the fore and end-stages, respectively of said MEDX plant.