A double line focusing solar energy collection apparatus of the present invention includes a heat collector, a secondary concentrator, and a bracket. The heat collector includes a primary concentrator and a heat collection tube, in which the primary concentrator has a focus line. The secondary concentrator has a focus line. The bracket supports the primary concentrator, the heat collection tube, and the secondary concentrator. The heat collection tube is located between the primary and secondary concentrators and located on the focus lines of the secondary and primary concentrators. The primary concentrator is a paraboloid reflector or Fresnel reflector. The secondary concentrator is a paraboloid reflector or Fresnel reflector. By adding the secondary concentrator, it achieves low light loss and high heat collection efficiency, and erosion of the heat collection tube by sand, rain, and snow can be effectively prevented, thereby extending the lifetime of the heat collection tube effectively.

A double line focusing solar energy collection apparatus of the present invention includes a heat collector, a secondary concentrator, and a bracket. The heat collector includes a primary concentrator and a heat collection tube, in which the primary concentrator has a focus line. The secondary concentrator has a focus line. The bracket supports the primary concentrator, the heat collection tube, and the secondary concentrator. The heat collection tube is located between the primary and secondary concentrators and located on the focus lines of the secondary and primary concentrators. The primary concentrator is a paraboloid reflector or Fresnel reflector. The secondary concentrator is a paraboloid reflector or Fresnel reflector. By adding the secondary concentrator, it achieves low light loss and high heat collection efficiency, and erosion of the heat collection tube by sand, rain, and snow can be effectively prevented, thereby extending the lifetime of the heat collection tube effectively.

Thermally-conductive ceramic and ceramic composite components suitable for high temperature applications, systems having such components, and methods of manufacturing such components. The thermally-conductive components are formed by a displacive compensation of porosity (DCP) process and are suitable for use at operating temperatures above 600° C. without a significant reduction in thermal and mechanical properties.

Thermally-conductive ceramic and ceramic composite components suitable for high temperature applications, systems having such components, and methods of manufacturing such components. The thermally-conductive components are formed by a displacive compensation of porosity (DCP) process and are suitable for use at operating temperatures above 600° C. without a significant reduction in thermal and mechanical properties.

A thermal cell panel system for heating and cooling using a refrigerant includes a plurality of solar thermal cell chambers, and a piping network for a flow of the refrigerant through the plurality of solar thermal cell chambers. In addition, the system includes a compressor having a motor coupled to a variable frequency drive (“VFD”), where the compressor is coupled to the piping network upstream of the plurality of solar thermal cell chambers and the VFD is configured to adjust a speed of the motor in response to the pressure of the refrigerant within the plurality of solar thermal cell chambers. The piping network includes an inlet manifold coupled to the inlet of each solar thermal cell chamber, and an outlet manifold coupled to the outlet of each solar thermal cell chamber.

A double-line focusing solar energy collection apparatus, comprising: a heat collector (1) which comprises a primary concentrator (11) and a heat collection tube (12), the primary concentrator (11) having a focus line; a secondary concentrator (3), having a focus line; and a support (2), for supporting the primary concentrator (11), the heat collection tube (12), and the secondary concentrator (3). The heat collection tube (12) is located between the secondary concentrator (3) and the primary concentrator (11), and is located on the focus lines of the primary concentrator (11) and the secondary concentrator (3).

A double-line focusing solar energy collection apparatus, comprising: a heat collector (1) which comprises a primary concentrator (11) and a heat collection tube (12), the primary concentrator (11) having a focus line; a secondary concentrator (3), having a focus line; and a support (2), for supporting the primary concentrator (11), the heat collection tube (12), and the secondary concentrator (3). The heat collection tube (12) is located between the secondary concentrator (3) and the primary concentrator (11), and is located on the focus lines of the primary concentrator (11) and the secondary concentrator (3).

An improved modular, removable system of building-integrated solar panel photovoltaics for easy residential and commercial roof installation for generating electrical and thermal energy.

An improved modular, removable system of building-integrated solar panel photovoltaics for easy residential and commercial roof installation for generating electrical and thermal energy.

Technologies are disclosed herein for a thin heat exchanger through which coolant may be pumped. The heat exchanger may include an envelope and a heat conduction layer provided over the envelope. The envelope may include one or more channels formed therein. The channels formed between the envelope and the conduction layer may extend the length of the heat exchange layer and be configured to carry coolant therethrough. The heat exchange layer may include an inlet manifold on a first end and an outlet manifold on another end opposing the first end. The inlet manifold may allow the flow of coolant into the heat exchange layer and the outlet manifold may allow the removal of the coolant from the heat exchange layer. Coolant flow may be controlled by a suction pump operating under computer control based at least in part on sensor data.