Water heater solar panel with collector heat exchanger and storage tank of water manufactured with plastic materials. This solar panel for heating water is manufactured with expanded polystyrene foam, glasses, a metal sheet and some plastic fittings. The collector of sun and water storage tank are assembled together, allowing the transfer of heat from the primary circuit to the secondary circuit without tubes, through a heat exchanger consisting of a metal sheet. The storage tank is integrated in the collector so that improves handling and lowers the cost in fluid transport and the manufacture of it. The weight of this panel is distributed regularly on the roof or deck.

A heating system comprising a non-tlai transparent housing comprising walls made of heat isolating material; a tank within the housing for receiving liquid; a platform laid on the ground; legs holding the tank on the platform; light-absorbent and heat conductive fins coupled to the tank, and a cold fluid inlet with a non-return valve therein, and a hot water fluid, the inlet and outlet extending from the tank to outside the housing; means to transfer heated air from inside the housing to outside the housing.

A solar energy storage and generation system includes a housing mounted on a base, a solar collector installed inside the housing, at least one lens installed on the upper surface of the housing, and multiple liquid-level counterbalance devices installed separately at different corner positions inside the housing. The base includes a multi-axis adjustment device positioned corresponding to the center of gravity of the counterweights in the housing. By installing the liquid-level counterbalance devices inside the housing and the multi-axis adjustment device, the upper surface of the housing can be adjusted to face the direction of the sun, thereby achieving a sun-tracking effect.

A solar heat collection tube with improved optical transmittance and durability to the external environment includes an inner tube through the interior of which a heat medium can flow, an outer tube that covers an outer periphery of the inner tube such that an annular heat insulating space is formed between the outer tube and the inner tube, and thermal expansion difference absorbing means or absorbing a thermal expansion difference between the inner tube and the outer tube. The outer tube is a glass tube, a first anti-reflection film is formed on an inner surface of the glass tube, a second anti-reflection film is formed on an outer surface of the glass tube, the second anti-reflection film is more durable to the external environment than the first anti-reflection film, and the first anti-reflection film has a higher optical transmittance than the second anti-reflection film.

To overcome shortcomings of the conventional thermal receiver, embodiments of the technology disclosed herein are directed towards an improved thermal receiver. More particularly, the various embodiments of the technology disclosed herein relate to thermal receivers without a vacuum insulation, otherwise known as an approximation of a blackbody. Various embodiments of the technology disclosed herein enable greater absorption of sunlight collected by a parabolic solar trough concentrator compared with conventional thermal receivers.

A heat shield bladder includes first and second sheets of insulating material that form a bladder between the first and second sheets. At least one reflective foil is disposed within the bladder and a plurality of spacers are disposed within the bladder and positioned to space the at least one reflective foil from the first and second sheets of insulating material. Multiple reflective foils may be disposed within the bladder with spacers between each reflective foil. The heat shield bladder may be rolled into a tube shaped and used inside a pipe or formed into panels that may be used to line a vessel.

The present invention relates to SNS-595 and methods of treating cancer using the same.

A layered insulation system comprising one or more layers. A variety of types of layers can be used in conjunction with one another to deliver a range of desired Low-E and/or Low-U insulation properties and/or venting choices. Some types of layers can be foam layers with foam that inhibits heat conjunction interspersed with microparticles and/or nanoparticles that reflect, scatter, abate, and/or negate infrared radiation (IR) wavelengths, including dampening Ideal Model Matrix vibrations to inhibit heat flux through an IR opaque system. Other layers can be Low-E layers, Low-U layers, primarily empty layers, and/or other types of layers.

A solar collector, in particular a solar thermal collector, is formed of at least one circuit transporting a heat transfer fluid, and includes at least one insulator, in particular in the form of at least one layer, formed of flakes and/or nodules of mineral wool(s) or mineral fibers. A process is provided for insulating or manufacturing a solar collector into which flakes and/or nodules of mineral wool(s) and/or mineral fibers are blown, as insulator, in particular without adding binder or water.

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.