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

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

A solar heat collector (100) is provided which has a plurality of upper air channels (3) arranged adjacently. A first flow control means (20) is provided at a first end of the upper air channels (3) and a second flow control means (20) is provided at a second end of the air channels (3). Each flow control means (20) is movable between a first position in which flow through the upper air channels (3) is substantially prevented and a second position wherein flow though the upper air channels (3) is permitted. Also described are a heat exchanger (100B), a fan (72), and a variety of flow modes.

A solar collector is provided. The collector comprises a monolithic flow control component to direct a flow of the heat transfer fluid between an inlet and outlet; and a solar absorber supported by the monolithic flow control component. The monolithic flow control component is able to support the solar absorber without any additional structural components to lend mechanical strength to the monolithic flow control component.

A heat collector includes a body including a hollow portion extending from a first end to a second end of the body and being a metal-extruded body having a light-receiving surface to receive sunlight, a pair of lids adjacent to the first end and the second end and covering the hollow portion, an inlet located in one of the pair of lids to allow a heating medium to enter the hollow portion, and an outlet located in one of the pair of lids to allow the heating medium to exit the hollow portion.

A heat collector includes a body including a hollow portion extending from a first end to a second end of the body and being a metal-extruded body having a light-receiving surface to receive sunlight, a pair of lids adjacent to the first end and the second end and covering the hollow portion, an inlet located in one of the pair of lids to allow a heating medium to enter the hollow portion, and an outlet located in one of the pair of lids to allow the heating medium to exit the hollow portion.

A solar appliance includes first and second double-wall bowls, each having an outer wall and inner wall spaced inwardly of the outer wall with at least partial vacuum therebetween. The first and the second double-wall bowls each having an opening that provides passage between an interior and an exterior thereof. The outer walls are at least translucent and the inner walls have an opaque solar radiation absorbing material. A gasket detachably mates the first double-wall bowl with the second double-wall bowl at least proximate respective rims thereof in inverted relationship. A vessel with a rim is positionable in the interior of the first double-wall bowl, with the rim of the vessel extending beyond the rim of the first double-wall bowl to help secure the second double-wall bowl to the first double-wall bowl. A vent, for example in the gasket, can vent the interior to the exterior.

A solar appliance includes first and second double-wall bowls, each having an outer wall and inner wall spaced inwardly of the outer wall with at least partial vacuum therebetween. The first and the second double-wall bowls each having an opening that provides passage between an interior and an exterior thereof. The outer walls are at least translucent and the inner walls have an opaque solar radiation absorbing material. A gasket detachably mates the first double-wall bowl with the second double-wall bowl at least proximate respective rims thereof in inverted relationship. A vessel with a rim is positionable in the interior of the first double-wall bowl, with the rim of the vessel extending beyond the rim of the first double-wall bowl to help secure the second double-wall bowl to the first double-wall bowl. A vent, for example in the gasket, can vent the interior to the exterior.

A solar energy collector includes a body, wherein the body has a geometric shape with a hollow interior. The body has multiple openings arranged at intervals around a Y-axis to allow a light ray to enter, and the openings are distributed along a Z-axis at different height positions. This arrangement reduces light exposure and disperses most of the thermal energy to be absorbed within the body. The light ray enters the interior of the body after being concentrated and reflected by a light path mechanism. Once inside the collector body, the light ray will be continuously reflected until it is absorbed, maximizing the utilization rate of the light ray.

The subject of the present application is an arrangement of sandwich panels already used in buildings in a way that makes them capable of collecting solar radiation and ambient heat and transferring the energy out of the roof. The structural elements of the present invention consist of a heat insulating core sandwiched between external and internal sheets with load-bearing capacity, similar to the make-up of the known load-bearing sandwich panels. Whether the sheet profiles are placed in the direction of the ridge beam or of the rafters, with the appropriate set of them, hollow structure is created on the surface and in the core of the panel in the direction of the rafters, in the entire length of the roof, functioning as pathways for gaseous materials (air ducts (1, 4)). If these air ducts, both external and in the core, are connected at the end facing each other, i.e. at the upper air turn chamber (8), the substance in them will start to flow on its own using solely gravitational forces in reaction to heat reaching the panel's external surface, i.e. the external profiled metal sheet (2). If a given point of the panel is cooled by heat exchanger (6), the spontaneous flow will remain continuous. Cooling transports the heat collected in the air ducts (hot air duct (1) and cold air duct (4)) out of the system, and this heat is utilized to provide for our energy needs. The subject of the application is, therefore a sandwich panel which functions as a thermal collector, hereinafter heat collector sandwich panel (3), which serves as the roof structure of a building, or is an integral part of the roof structure and meets without fail all protection requirements set for roof constructions. Due to its special design it is capable of collecting ambient heat, and transferring this heat to heat storage by the use of compatible, known auxiliary appliances.