A solar energy roof tile, thermally and/or electrically conductively connected to an adjacent solar energy roof tile, includes a lower face for placing on at least some regions of a roof construction, an upper face opposite the lower face formed at least in some regions by a solar energy utilisation module, two opposite lateral walls, a rear face connecting the two lateral walls, and a front face opposite the rear face that connects the lateral walls. The two lateral walls, the rear face and front face together connect the lower and upper faces, such that a cavity is formed between the two lateral walls, the rear face, front face, and lower and upper faces. The lower face has, in the region of the front face, a lower opening for providing access. The upper face has, in the region of the rear face, an upper opening for providing access into the cavity.

A pre-formed solar panel (1) to be mounted on a support plane (SP) is disclosed. In a direction from a first end (E1) to a second opposing end (E2), the panel has at least a first planar section (S1), a plastically deformed section (P) and a second planar section (S2), wherein the plastically deformed section maintains the first and the second planar section relative to each other at an enclosed angle (A1) in a range between 30° and 170°, and wherein an area of at least one of the planar sections is provided with a photovoltaic layer (3).

A pre-formed solar panel (1) to be mounted on a support plane (SP) is disclosed. In a direction from a first end (E1) to a second opposing end (E2), the panel has at least a first planar section (S1), a plastically deformed section (P) and a second planar section (S2), wherein the plastically deformed section maintains the first and the second planar section relative to each other at an enclosed angle (A1) in a range between 30° and 170°, and wherein an area of at least one of the planar sections is provided with a photovoltaic layer (3).

A solar tracking carport comprises a supporting structure including a foundation and at least two columns connected or connectable to the foundation; a three-dimensionally rigid canopy deck having a length from a first edge to a second edge of at least one car, the three-dimensionally rigid canopy deck including one or more upper blocks, each of the upper blocks being rigid at least in its longitudinal direction, each of the upper blocks including at least one solar panel; a deck frame configured to support the one or more upper blocks, the deck frame including a torque transmitting member; a rotation enabling connection configured to rotatably connect at least the torque transmitting member of the three-dimensionally rigid canopy deck to the at least two columns of the supporting structure; and a drive system configured to control tilting of the three-dimensionally rigid canopy deck about the supporting structure over one axis of rotation to a first maximum angle in a first direction and to a second maximum angle in a second direction, the first maximum angle preventing the first edge of the three-dimensionally rigid canopy deck from going below a first minimum threshold height, the second maximum angle preventing the second edge of the three-dimensionally rigid canopy deck from going below a second minimum threshold height.

A solar tracking carport comprises a supporting structure including a foundation and at least two columns connected or connectable to the foundation; a three-dimensionally rigid canopy deck having a length from a first edge to a second edge of at least one car, the three-dimensionally rigid canopy deck including one or more upper blocks, each of the upper blocks being rigid at least in its longitudinal direction, each of the upper blocks including at least one solar panel; a deck frame configured to support the one or more upper blocks, the deck frame including a torque transmitting member; a rotation enabling connection configured to rotatably connect at least the torque transmitting member of the three-dimensionally rigid canopy deck to the at least two columns of the supporting structure; and a drive system configured to control tilting of the three-dimensionally rigid canopy deck about the supporting structure over one axis of rotation to a first maximum angle in a first direction and to a second maximum angle in a second direction, the first maximum angle preventing the first edge of the three-dimensionally rigid canopy deck from going below a first minimum threshold height, the second maximum angle preventing the second edge of the three-dimensionally rigid canopy deck from going below a second minimum threshold height.

A support assembly for mounting photovoltaic modules on a support surface and a mounting system including the same are disclosed herein. The support assembly may comprise a the body portion including a base portion and at least one upright support member coupled to the base portion, the at least one upright support member comprising an integrally formed ballast tray slot in one side thereof for receiving an upturned edge of a ballast tray; and at least one clamp subassembly coupled to the at least one upright support member of the body portion, the at least one clamp subassembly configured to be coupled to one or more photovoltaic modules. In addition to a plurality of support assemblies, the mounting system may further comprise at least one ballast tray support bracket, the ballast tray support bracket supporting a portion of a ballast tray on the support surface.

A support assembly for mounting photovoltaic modules on a support surface and a mounting system including the same are disclosed herein. The support assembly may comprise a the body portion including a base portion and at least one upright support member coupled to the base portion, the at least one upright support member comprising an integrally formed ballast tray slot in one side thereof for receiving an upturned edge of a ballast tray; and at least one clamp subassembly coupled to the at least one upright support member of the body portion, the at least one clamp subassembly configured to be coupled to one or more photovoltaic modules. In addition to a plurality of support assemblies, the mounting system may further comprise at least one ballast tray support bracket, the ballast tray support bracket supporting a portion of a ballast tray on the support surface.

Watertight anchoring (2) for securely fastening elements (3, 4) to a building (1), comprising abase or support {6) anchored in a supporting structure (7) of the building (1); a heat-insulating layer (17}; a first watertight layer (25) applied over the heat-insulating layer (17} and the base or support (6); a bearing structure (28) fixed to the base or support (6) and a second watertight layer (38) applied over parts of the aforementioned bearing profiles (29) and over parts (39) of the first watertight layer (25) that, are adjacent to the respective bearing profiles (29).

A solar array includes a solar module and a support structure for the solar module. The support structure includes a support member. The solar module is mounted on the support structure such that the solar module is positioned at least partially above the support member. The solar array also includes a wire receiver for securing wires to the solar module or the support member. The wire receiver includes a wire insert slot sized for receiving wires, a wire transition slot connected to the wire insert slot, and a catch adapted to inhibit movement of the wires. The wire insert slot and the wire transition slot are sized and arranged for the wires to be inserted into the wire insert slot and positioned around the catch.

An energy storage canopy having solar panels and an energy storage cartridge to charge electric vehicles or the like is provided. The energy storage cartridge includes a power connector that has a power cord with a plug assembly configured to electrically could the battery of an electric vehicle to the energy storage cartridge.