A solar thermal system is provided. The system comprises at least one solar thermal collector for heating a heat transfer fluid (HTF); and at least one conduit for transporting the HTF into and out of the at least one solar thermal collector; wherein said at least one conduit is of a foam or plastics material.

A solar thermal system is provided. The system comprises at least one solar thermal collector for heating a heat transfer fluid (HTF); and at least one conduit for transporting the HTF into and out of the at least one solar thermal collector; wherein said at least one conduit is of a foam or plastics material.

A solar thermal system is provided. The system comprises at least one solar thermal collector for heating a heat transfer fluid (HTF); and at least one conduit for transporting the HTF into and out of the at least one solar thermal collector; wherein said at least one conduit is of a foam or plastics material.

A solar thermal system is provided. The system comprises at least one solar thermal collector for heating a heat transfer fluid (HTF); and at least one conduit for transporting the HTF into and out of the at least one solar thermal collector; wherein said at least one conduit is of a foam or plastics material.

A greenhouse, for cold weather climates, is configured with a gable that is offset toward the north wall and therefore the south extension of the roof, from the gable to the south wall is longer than the north extension. A greater amount of light can enter through this south extension and the inside surface of the north wall is configured with a reflective surface to allow light to be more uniformly distributed around the plants. The north wall may have no widows and may be thermally insulated to prevent the greenhouse from getting too cold during the night. A ground to air heat transfer (GAHT) system may be configured to produce a flow of greenhouse air under the greenhouse for heat transfer, to moderate the temperature of the greenhouse. A thermal medium may flow to a thermal reservoir for heat exchange with the conduits of the GAHT system.

A wall module used to retrofit any existing building into solar building or construct new solar building is made of a hybrid photovoltaic and solar thermal plate, a heat pipe, a solid thermal energy storage, a glass cover, and a heat-pump system. When the incident sunlight penetrating through the transparent glass cover reaches to the cogeneration plate, portion of it is converted into electricity and the rest becomes into heat; then the heat is transferred back to the solid thermal storage; when it is needed for heating and cooling, the stored heat is retrieved and transported to its destination with heat pump system; during the transportation process, the temperature of the stored heat is boosted up. Any buildings, no matter existing building or new building, can be converted into a large scale solar power generation and storage station using the wall modules of present invention without changing their structures and functions. As the buildings share the insulation with the wall modules, the addition of the wall modules will significantly improve the encapsulation of the buildings. The wall modules change the whole body of building into large scale storage without occupying the interior space of the building.

A curtain wall or roof element, with built in solar panel or heat absorbing layer, and at least one blower for air circulation inside the enclosed device, one or more temperature sensors monitoring the temperature inside and outside the device and a microcontroller activating the blower according to predetermined program to heat or cool the room enclosed by the device. If solar cells or panels are used they will generate electrical power and heat. It is the purpose of this invention to increase the energy harvesting coefficient from the sun's radiation by utilizing the absorbed heat for increasing the temperature in a space enclosed by said device, moreover the smart configuration of the curtain wall will enable to change the system's isolation characteristics by changing its U values. U value of a curtain wall describes the heat isolation characteristics of the device in a numerical form.

A curtain wall or roof element, with built in solar panel or heat absorbing layer, and at least one blower for air circulation inside the enclosed device, one or more temperature sensors monitoring the temperature inside and outside the device and a microcontroller activating the blower according to predetermined program to heat or cool the room enclosed by the device. If solar cells or panels are used they will generate electrical power and heat. It is the purpose of this invention to increase the energy harvesting coefficient from the sun's radiation by utilizing the absorbed heat for increasing the temperature in a space enclosed by said device, moreover the smart configuration of the curtain wall will enable to change the system's isolation characteristics by changing its U values. U value of a curtain wall describes the heat isolation characteristics of the device in a numerical form.

An electromagnetic radiation collecting and directing apparatus is described herein. The electromagnetic radiation collecting and directing apparatus facilitates directing light from an exterior of a structure to an interior of a structure. The directed light is then distributed as necessary within the structure for heating, illumination, or is stored for use at a later time.

An electromagnetic radiation collecting and directing apparatus is described herein. The electromagnetic radiation collecting and directing apparatus facilitates directing light from an exterior of a structure to an interior of a structure. The directed light is then distributed as necessary within the structure for heating, illumination, or is stored for use at a later time.