Abstract: Device for collecting rainwater and heat originating from solar radiation to both drain the rainwater and generate sanitary or heating hot water, capable of being fitted at the base of a roof or on the edge of a balcony, comprising an open channel 2 having longitudinal walls and side walls 7, 8, characterized in that a translucent or transparent covering element 3 is fitted inside the open channel 2, being maintained by the side walls 7, 8 and defining inside the open channel a watertight sealed chamber 2b, in that a heat-exchanger device 12 inside which a heat-transfer fluid can circulate is fitted inside said sealed chamber 2b, and in that the translucent covering element 3 defines, with at least a part of a longitudinal wall of the channel 2, a flow section for the rainwater.

Abstract: A wall integrated thermal solar collector with heat storage capacity includes a transparent layer and a solar radiation absorption layer, that is separated by an air gap from the transparent layer. A heat storage layer of phase changing material is positioned in close contact with the solar radiation absorption layer to facilitate heat transfer. A structural panel of thermally insulating material is positioned adjacent to the heat storage layer.

Abstract: An overmolding insert includes a base having at least one opening in a first surface, the opening communicating with a second surface opposite the first surface, at least one hollow projection extending from the first surface, the hollow projection having a first opening communicating with the opening of the first surface and a second opening located at a terminal portion of the hollow projection, the insert further having two opposed side walls, each side wall being joined to the first surface, two opposed end walls being joined to an opposite end of the first surface and extending from one side wall to the other side wall. The side walls, the end walls, and the first surface define a partially closed space, with the terminal portion of the hollow projection extending beyond the partially closed space.

Abstract: A solar water heater comprising a water tank, a solar heating compartment for heating water, and an air pump. The water tank and the solar heating compartment are both substantially cylindrical, and the bottom surface of the heating compartment overlaps the top surface of the water tank. The solar heating compartment has an upper surface and a side surface which are substantially constructed from transparent materials. The heating compartment contains water tubing in communication with water in the water tank and at least one stainless steel parabolic reflector positioned for reflecting incident sunlight upon the water tubing for absorption. The water tubing terminates in at least one hot water outlet. The air pump is in communication with the water tubing within the solar heating compartment. Operation of the air pump causes a stream of water to continuously flow from the water tank to the hot water outlets by the siphoning effect.

Abstract: A stationary solar photovoltaic array module design, which constitutes four steps of optical concentrations of photovoltaic electric power generation systems. A compound parabolic concentrator (CPC) is mounted under a first and second optical concentrating fresnel lenses that concentrates the intensity of sunlight. Then the focused sunlight is further concentrated twenty times by the third optical concentrator CPC. The high mirror quality of CPC allows 98% of the reflected rays to be focused at the bottom of the CPC. At this point, the intensified sunlight is homogenized as it passes through a fourth optical concentrator glass lens, which with anti-reflection coating on the top of the glass lens' surface, incident on the multi-junction solar cell accomplish the fourth optical concentration for the photovoltaic electric energy conversion.

Abstract: An apparatus for converting solar energy to thermal and electrical energy including a photovoltaic grid for converting the concentrated solar energy into electrical energy mounted on a copper plate that provides even temperature dispersion across the plate and acts as a thermal radiator when the apparatus is used in the radiant cooling mode; and a plurality of interconnected heat transfer tubes located within the enclosure and disposed on the plane below the copper plate but conductively coupled to the copper plate for converting the solar energy to thermal energy in a fluid disposed within the heat transfer tubes. Fresnel lenses are affixed to the apparatus on mountings for concentrating the solar energy on to the photovoltiac grid and functioning as a passive solar tracker.

Abstract: A hybrid roof covering element, which suitable for simultaneously heating a medium and generating electricity, and which comprises a single or multiple transparent layer, a flexible thin film solar cell sheet with a heat capacity of less than 3.5 kJ/m2K and a thermally insulating material, and a medium to be heated. The flexible thin film solar cell sheet comprises a carrier, a back electrode, a photovoltaic layer, and a transparent conductive front electrode and has a heat capacity of less than 3.5 kJ/m2K. This hybrid roof covering element has a response speed of more than 5.7·10−4 K/J if the medium to be heated is air and a response speed of more than 1·10−4 K/J if the medium to be heated is water.

Abstract: A solar energy collection system that can be retrofitted into pavement covered lots, such as macadam covered parking lots has a pump and heat exchanger, and a conduit buried below the pavement surface that contains a heat transfer fluid such as water. The conduit has a hollow unitary, one piece casing with an oval cross section and an internal divider that divides the interior of said casing into two passageways having substantially the same cross sectional area. Heat conducting fins preferably made of copper are mounted on the casing and extend coaxially outwardly in opposite directions therefrom along the major oval axis.

Abstract: The invention relates to a solar compound concentrator of an electric power generation system. A compound parabolic concentrator (CPC) is mounted under an acrylic concentrating fresnel lens that concentrates the intensity of sunlight to five to ten times above normal level. Then the focused sunlight is further concentrated twenty to fifty times by the CPC collector. The intensified sunlight is focused on the bottom of the CPC. The high mirror quality of CPC allows 98% of the reflected rays to be incident on the bottom of the CPC. A cermet coating is spattered onto the top of a stainless steel heat pipe (heat exchanger) allowing for an absorptivity of 96%.

Abstract: A heat storage device comprises a heat storage tank 2 charged with a heat storage material 1 for storing the heat supplied from the outside, and a heat exchanger 3 for executing an injection and an extraction of heat between the inside of the storage tank 2 and the outside by the heat exchange between the heat storage material and a heat transfer medium. The heat exchanger 3 is disposed so as to execute a heat exchange between the central portion 2a in the heat storage tank 2 and the outside, and suppresses the natural convection of the heat storage material 1 of the outer portion 2b by, for example, dispersing a liquid-absorbent material 5 in the outer portion 2b surrounding the central portion in the heat storage tank 2, whereby reduces the influence of external environment on the central portion 2a in the heat storage tank, thereby suppressing the heat loss toward the outside.

Abstract: A heat storage apparatus for a temperature range of about 10 to 95 degrees Celsius, especially for solar installations, heat pumps, boilers or the like and for extraction of heat for the operation of a room heating installation and/or an installation for water for use, consists of a low-temperature latent heat storage device and a downstream water reservoir. In that case, the fresh water feed for the installation for water for use runs, for preheating, through the low-temperature latent heat storage device before entry into the water reservoir and the return of the heat exchanger runs, for further cooling down of the return flow to the lowest possible temperature level, through the low-temperature latent heat storage device after exit from the water reservoir.

Abstract: A solar concentrator for producing usable power as heat and/or electricity uses a self-steering heliostat 1502 to concentrate solar radiation 1509 onto an absorbing surface such as, or including, a solar cell array 1511 capable of absorbing power from the radiation, meanwhile removing heat (such as from long-wave infra-red radiation or resistive losses) from the surface with fluid heat transfer means 1503, 1504, then making effective use of that low-grade heat. Thus the solar cell array is kept relatively cool and a larger proportion of the solar energy incident on the reflector unit is used. The invention uses electricity 1506 from the solar cells to move a transporting fluid through a heat exchanger 1504. Excess electricity may be available for local storage or use 1510, or feeding 1512 to the power distribution grid. Applications include warming swimming pools 1501, heating hot-water supplies using excess electricity, or warming, lighting and ventilating open spaces.

Abstract: A central solar receiver comprising a tubular housing with a central axis, a radiation admitting aperture and an absorber chamber having an outer wall, two oppositely located ends, an inner-wall-forming substantially tubular transparent window co-axial with the tubular housing. The solar receiver further comprises injection means near a first of the oppositely located ends and at least one egress opening means near a second of the oppositely located ends. The injection means are capable of injecting into the absorber chamber a multicomponent fluid mixture comprising at least one radiation absorbing component and are so designed that the fluid mixture is injected into the absorber chamber adjacent and essentially tangentially to the outer wall, whereby contact between the mixture and the window is reduced. The egress opening enables the egress of the fluid mixture from the absorber chamber.

Abstract: A combined thermal-insulation/thermal-collector assembly for the outside walls or roofs of buildings has a heat-insulating layer which is transparent to solar radiation and is designed with a transparent structure. The heat-insulating material including a multiplicity of adjacent channels is disposed in essentially the same direction as the flow of heat. The heat-insulating layer is made up of elements which are thin relative to the thickness of the layer. The channels running across the heat-insulating layer are open, have an essentially uniform diameter, and thus form a transparent structure.

Abstract: A building including high efficiency transparent insulation and optical shutter solar collector (HETIOSSC) to effectively control heat loss and gain in a passively-solar climate control system. HETIOSSC includes a layer of protective glazing, a transparent insulation, an optical shutter, an optional solar radiation absorbing material and optional heat storage elements. When the building and its heat storage are too warm, the optical shutter layer becomes opaque to prevent overheating. During cloudy and cold winter days, HETIOSSC still has a solar transmission and insulation efficiency great enough to collect sufficient sunlight for heating. Location of HETIOSSC on the roof, rather than the walls, does not alter shape and orientation of a building.

Abstract: A system for heating a fluid (5) conveyed or contained in process equipment (7) comprises a layer of transparent thermal insulation (9) which partly covers the process equipment so that a section (13) is exposed to solar radiation and thus is heated by the solar radiation and thereby heats the fluid (5). The "window" defines a form of thermal diode concentrator in that the surface area of the "window" is great than that of the exposed section (13) of the process equipment (7) and thus the "window" in effect concentrates the solar radiation onto the exposed section (13) of the process equipment, and the transparent thermal insulation (9), albeit transparent, minimises heat loss from the fluid (5).

Abstract: A process and apparatus for converting solar energy into heat wherein a solar collector includes a plurality of mutually-coupled solar energy collector elements (1) coupled to a heat transfer fluid circuit, each collector element including a collector channel (3) located on the bottom of a collector chamber (37) delimited by a transparent cover, the collector chamber normally being connected to a high temperature reservoir (12) via connecting lines (10, 11), until a control valve arrangement (18) is reversed and the collector channel is disconnected from the high temperature reservoir and connected to a low temperature reservoir (13) for heat pump (26) operation when the temperature of the circulating heat transfer fluid falls below a predetermined minimum value detected by a temperature sensor (35) associated with the collector channel.