An architectural structure having: a wall of a room of the architectural structure; and a panel integrated into the wall, wherein the panel includes thermoelectric components (TECs) arranged as a TEC grid, thereby defining a radiant panel, wherein: the TECs, of the TEC grid, are thermally coupled to a common heat sink formed in part by an exterior surface of the wall; and the wall defines a wall surface area, the panel defines a panel surface area, and the panel surface area is between 5% and 20% of the wall surface area.

An architectural structure having: a wall of a room of the architectural structure; and a panel integrated into the wall, wherein the panel includes thermoelectric components (TECs) arranged as a TEC grid, thereby defining a radiant panel, wherein: the TECs, of the TEC grid, are thermally coupled to a common heat sink formed in part by an exterior surface of the wall; and the wall defines a wall surface area, the panel defines a panel surface area, and the panel surface area is between 5% and 20% of the wall surface area.

A colored solar module is provided, in which at least one solar cell is embedded in an encapsulation layer, and a transparent plate is disposed on the encapsulation layer. The transparent plate has a single coating layer containing quartz for attaching onto the encapsulation layer so as to reflect the desired color light.

To provide a coating material capable of forming a solar cell module excellent in the weather resistance, the power generation efficiency and the design, a cover glass, a solar cell module comprising the cover glass, and an outer wall material for building. The cover glass of the present invention is a cover glass comprising a glass plate and a layer containing a fluorinated polymer having units based on a fluoroolefin, on at least one surface of the glass plate, which has an average visible reflectance of from 10 to 100%, and an average near infrared transmittance of from 20 to 100%.

To provide a coating material capable of forming a solar cell module excellent in the weather resistance, the power generation efficiency and the design, a cover glass, a solar cell module comprising the cover glass, and an outer wall material for building. The cover glass of the present invention is a cover glass comprising a glass plate and a layer containing a fluorinated polymer having units based on a fluoroolefin, on at least one surface of the glass plate, which has an average visible reflectance of from 10 to 100%, and an average near infrared transmittance of from 20 to 100%.

A solar cell louver assembly includes: a plurality of solar cell module units having a solar cell panel part, with a pair of terminal portions provided on both end parts, a pair of first electrode terminals electrically connected to the respective terminal portions, and a pair of first caps mounted on the solar cell panel part to surround the respective first electrode terminals; second electrode terminals electrically connected to the first electrode terminals, and second caps accommodating the second electrode terminals and having mounted thereon the first caps; a frame unit having an inner frame such that the second caps are mounted rotatably in the length direction, and an outer frame surrounding the inner frame; and a connector unit between the inner and outer frames and having a pair of third electrode terminals electrically connecting the second electrode terminals of adjacent module units when mounted in the frame unit.

A solar panel shade system includes a shade tube, a solar panel shade coupled to the shade tube comprising a solar panel film material, a motor coupled to the shade tube to cause the shade tube to rotate to retract or deploy the solar panel shade, and a processing circuit. The processing circuit includes a processor configured to control operation of the motor and a memory storing instructions for the operation of the motor.

A solar panel shade system includes a shade tube, a solar panel shade coupled to the shade tube comprising a solar panel film material, a motor coupled to the shade tube to cause the shade tube to rotate to retract or deploy the solar panel shade, and a processing circuit. The processing circuit includes a processor configured to control operation of the motor and a memory storing instructions for the operation of the motor.

A structural mount is used for attaching devices to a gutter. The mount includes a gutter engaging portion and a device engaging portion. The gutter engaging portion including two gutter mounts. The gutter mounts include a spiral hook and a stabilizer. The spiral hook extends above a gutter lip and into a gutter channel such that a proximal point of the spiral hook is positioned against an inner surface of a front wall of the gutter, and the stabilizer contacts an outer surface of the front wall of the gutter when the attachment device is engaged with the gutter. The device engaging portion includes a mounting surface and a mounting plate. The mounting plate is capable of receiving a securing clip attached to a device such that the device may engage with the mounting surface via the mounting plate and the securing clip.

A structural mount is used for attaching devices to a gutter. The mount includes a gutter engaging portion and a device engaging portion. The gutter engaging portion including two gutter mounts. The gutter mounts include a spiral hook and a stabilizer. The spiral hook extends above a gutter lip and into a gutter channel such that a proximal point of the spiral hook is positioned against an inner surface of a front wall of the gutter, and the stabilizer contacts an outer surface of the front wall of the gutter when the attachment device is engaged with the gutter. The device engaging portion includes a mounting surface and a mounting plate. The mounting plate is capable of receiving a securing clip attached to a device such that the device may engage with the mounting surface via the mounting plate and the securing clip.