A system includes a plurality of photovoltaic modules installed on a roof deck in an array. Each of the photovoltaic modules includes a wire cover bracket substantially aligned with the wire cover bracket of an adjacent another one of the photovoltaic modules. At least one cover is removably attached to at least one of the wire cover brackets. The cover includes a top portion, a first side portion extending from a first side of the top portion, and a second side portion extending from a second side of the top portion opposite the first side. The top portion of the at least one cover is configured to divert water from entering the wire cover bracket from above the at least one cover. The first and second side portions are configured to divert water from entering the wire cover bracket from a lateral direction relative to the wire cover bracket.

A system includes a plurality of photovoltaic modules installed on a roof deck in an array. Each of the photovoltaic modules includes a wire cover bracket substantially aligned with the wire cover bracket of an adjacent another one of the photovoltaic modules. At least one cover is removably attached to at least one of the wire cover brackets. The cover includes a top portion, a first side portion extending from a first side of the top portion, and a second side portion extending from a second side of the top portion opposite the first side. The top portion of the at least one cover is configured to divert water from entering the wire cover bracket from above the at least one cover. The first and second side portions are configured to divert water from entering the wire cover bracket from a lateral direction relative to the wire cover bracket.

An attachment system for roof-mounted equipment of this disclosure includes a pedestal having rails and corresponding channels at a top and bottom wall surface, the rails and channels located below the bottom wall surface configured to receive an adhesive for mounting the pedestal to a roof structure without penetrating the roof, the rails and channels located below the top wall surface including at least one channel configured to accept a fastener of the piece of equipment to be mounted on the pedestal.

A roof or wall comprising an insulating selective surface (1) for the use of transferring net heat energy into or out of an enclosure, such as a building. The insulating selective surface comprises at least one transparent cover (2) that comprises a chamber (9), and in the chamber is a moveable plate (4) comprising a plurality of surfaces (5, 6). At least one of the surfaces is a selective surface which can be moved to substantially face the sky, or moved to face away from the sky. The device insulates the enclosure from conductive losses, while using the sun to heat the enclosure, or the cold of deep space to cool the enclosure depending on how the plate is moved.

A roof or wall comprising an insulating selective surface (1) for the use of transferring net heat energy into or out of an enclosure, such as a building. The insulating selective surface comprises at least one transparent cover (2) that comprises a chamber (9), and in the chamber is a moveable plate (4) comprising a plurality of surfaces (5, 6). At least one of the surfaces is a selective surface which can be moved to substantially face the sky, or moved to face away from the sky. The device insulates the enclosure from conductive losses, while using the sun to heat the enclosure, or the cold of deep space to cool the enclosure depending on how the plate is moved.

An urban concentrated solar power for mounting on a roof top is provided. The urban concentrated solar power has a heat receiver has a non-circular duct that distinguishes an insulated area with an insulation layer on the outer surface of the non-circular duct and a non-insulated area. The non-circular duct contains a heat transferring fluid which can reach temperatures of at least 500 degrees Celsius. A parabolic trough with an aperture of below 2 meters concentrates sunlight onto the non-insulated area of the non-circular duct of the heat receiver. The heat receiver can be placed in a glass tube. Due to roof top mounting the electricity can be generated in proximity of the user and as a result decrease net congestion. The low-cost heat receiver design will make electricity generated by urban CSP competitive with electricity from fossil fuel plants and PV combined with lithium-ion battery storage.

An urban concentrated solar power for mounting on a roof top is provided. The urban concentrated solar power has a heat receiver has a non-circular duct that distinguishes an insulated area with an insulation layer on the outer surface of the non-circular duct and a non-insulated area. The non-circular duct contains a heat transferring fluid which can reach temperatures of at least 500 degrees Celsius. A parabolic trough with an aperture of below 2 meters concentrates sunlight onto the non-insulated area of the non-circular duct of the heat receiver. The heat receiver can be placed in a glass tube. Due to roof top mounting the electricity can be generated in proximity of the user and as a result decrease net congestion. The low-cost heat receiver design will make electricity generated by urban CSP competitive with electricity from fossil fuel plants and PV combined with lithium-ion battery storage.

A solar roof of a building includes a plurality of solar panels removably coupled to a roof of the building such that a first solar panel of the plurality of solar panels is configured to be removed from the roof without removing an adjacent solar panel.

Generally, the present disclosure of embodiments of Disclosed is a construction element of a null-energy system. Such a construction element can include a body on which the construction element can further include a porous material compartment with porous material to store water and evaporate the stored water outwards from the porous material through a holding layer on the opposite side of the porous material compartment to the body. The disclosure relates also to a null-energy system using a construction element of null-energy system as embodied therein.

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