The present invention provides a zero-emission dialysis clinic including a building envelope, daylight concept, lighting concept, mechanical ventilation (71), a chilled and heated ceiling (61) with capillary tubes (60), heat pump (50), and a photovoltaic system (80). Specifically, the present invention balances the energy consumption with energy generation by a photovoltaic system. The CO.sub.2 emissions are thus balanced and the building produces no net emissions.

A positioning system is attached to radiation collection device such as a solar oven. The positioning system is attached to an outside of a building structure, allowing the collection device to be positioned in a plurality of locations. At least one of the plurality of locations is away from the building structure to allow the radiation collection device to collect solar radiation.

An assembly of units comprised of mirrors assembled along at least one parabolic arc, each mirror having two opposing lateral edges and opposing longitudinal internal and external edges, each of the two mirrors being longitudinally secured to the other mirror along their respective longitudinal internal edges by at least one securing device positioned at the centre of the parabolic arc; and secured at each lateral edge to the wheel supports.

A tile or plate, includes: an upper plate (3) and a lower plate (4); wherein a plurality of heat conducting cavities (6) are uniformly provided between the upper plate (3) and the lower plate (4) via connecting ribs (5). A solar collection layer is provided on an upper surface of the tile or the plate. Two ends of the tile or the plate are connected with each of the plurality of the heat conducting cavities (6) via transverse connecting pipes (23, 37, 42). The transverse connecting pipes (23, 37, 42) of two neighboring tiles are connected by a ferrule (17) or a hose (36) to form an integrated circulation system. The tile or plate has a large day-lighting area and a high energy conversion rate.

An absorber system solves problems of known absorber systems for use in solar fields in that the absorber tube is suspended on a rail below an absorber cover. The design also makes it possible to move measuring and cleaning robots and the like along the absorber tube more and allows the absorber tube and the secondary reflector to be jointly suspended, whereby an exact mutual alignment between the two components is enabled.

An apparatus for heating a working fluid of a gas turbine-solar power generation system, comprising, sequentially connected, a cold air flow channel, a heat collecting cavity, and a hot air passage. The hot air passage is formed by connecting an inner housing on the front side to a supplemental heating section on the rear side. Also comprised is a burner for heating a primary heating air within the supplemental heating section when having insufficient solar power, and the burner is arranged at the supplemental heating section.

In the light-converting device the light-converting elements (11) are arranged at least on two levels. They are placed on the strips (17). The design is supported at least by one pole (23). Because of it in this device light-converting elements may be arranged on many levels and consequently much less place for it is required and new possibilities appear. The device may be installed for instance on a roof of buildings in the best direction at any side of inclined roof. The device may also be installed on slopes of mountains, in rivers, lakes, coastal zones of seas and oceans, on vehicles, and trailers. The device may be installed on ships standing immovably not very far from the coast and connected to the coast by a cable. The device may be used on military bases, and on the moon. The device is used on military bases will decrease dependence on the fuel supply.

The structure (10) of light display for vehicle traffic lane(s) is of the type including at least one vertical support post (7), a substantially horizontal crossbar (3) fixed high to said at least one support post (7) and a variable-message light display panel (2) fixed to said crossbar, said display panel (2) having a front face on which the light messages are broadcast, and a rear face, said display panel being elongated along the crossbar (3), parallel and fixed to the latter, said structure including an autonomous electric power supply source comprising at least one photovoltaic panel (1). The photovoltaic panel(s) (1) are arranged towards the top and the rear of the display panel (2), in a plane that is horizontal or, preferably, inclined but not vertical, carried by a horizontal line parallel to the crossbar (3) and to the display panel (2), the front end(s) of the photovoltaic panels (1) being placed substantially against the upper end of the display panel (2), the front end(s) of the photovoltaic panels (1) being higher than the rear end(s) (12) of said photovoltaic panel(s) in the case of inclined photovoltaic panels.

The invention relates to a hybrid solar collector that generates thermal and electrical energy while maintaining a comfortable indoor climate. The hybrid solar collector comprises a thermal energy collector for time-delayed transfer of thermal energy resulting from incident solar energy into building walls having a rear-vented cover arranged so that an air gap is formed between the solid collector portion and the cover, said cover comprising photovoltaic (PV) elements and being at least partially transparent and/or partially translucent so as to allow solar radiation to impinge on the solid thermal collector, wherein the air in the gap between the cover and the collector is sucked by a heat pump preferably for use in heating water or thermal storage The hybrid solar collector of the invention stores thermal energy in and releases thermal energy from the thermal collector portion, while also generating electricity using the PV elements and utilizing thermal energy from the heated air in the air gap. Operating procedures include targeted air flow and heat recuperation. The system may be used to retrofit existing thermal solar cells with incident-angle-selective structure.

A solar energy attic air heat reservoir system including methods for selecting, installing and operating air movers coupled with HVAC components, air filters, and thermostatic control devices operating systematically for space heating. Solar insolation conducted through building roof materials heats the large volume of attic airspace sealed from normal ventilation during heating season to preserve heat energy, with heat transfer coefficient of convection contributing to and sustaining heating of attic air. Thermostatic digital temperature control devices communicate in series between the building attic and interior for optimum used of heated air supply for environmental control. Methods include computer program applications for feasibility, apparatus selection, operation, and energy cost accountability to enable optimizing space heating using the limited daily solar induced heat. Methods include advantageous containment of thermal energy stored in building interior materials as gathered from attic-heated air for later release through diurnal temperature variation to augment space heating.