A non-slip roof attachment system for attaching structures to residential and commercial roofs without the use of penetrations to roofing shingles and sealing layers is described. The non-slip attachment system may be used to attach roof mounted systems such as solar panels. The non-slip attachment system also allows for the quick removal of such roof mounted systems rapidly and without the need for repair of penetrations. The non-slip attachment system uses, among other things, an array-stay retainer comprising a vertical member and a horizontal member. The horizontal member comprises a spiral.

There is provided a cladding member (13) formed of a supporting body portion (67) having mounts (54) and a head portion (12), and an absorber surface portion (70) having a peripheral boundary wall (71) defining a recess into which a solar cell array (removed in this view for clarity) is bonded. The supporting (67) and absorber surface (70) body portions are pressure moulded from polyvinyl ester/glassfibre (30%)/fire retardant (40%)/pigment sheet moulding compound. Complementary bonding portions (72) form a glue line in assembly and have complementary water passages (73) defined therebetween. The bonding portions (72) contrive a generally sinusoidal glue space (74) that is longer that the transverse sectional dimension of the boding portions (72), cooperating with the adhesive system to resist water pressure in the passages (73).

There is provided a solar cell module with good weather resistance (moisture resistance) and power generation efficiency. A solar cell module 1 comprises a solar cell panel 10 configured to include a solar cell element 12 and a front surface protective member 14 disposed on a light receiving surface side of the solar cell element 12; a first coating member 22 having moisture resistance that is stuck to the solar cell panel 10 with adhesive such that at least a surface S1 of the front surface protective member 14 and a side end surface S3 of the solar cell panel 10 are covered continuously at a peripheral edge of the solar cell panel 10; and a second coating member 32 covering at least an end A1 of the first coating member 22 on the front surface protective member 14 side while being in contact with the surface S1 of the front surface protective member 14.

A mounting unit for mounting a solar panel on a roof includes a base having a first flange and a second flange that extend laterally from the base and a mounting surface positioned above the base via walls that connect the mounting surface and the base. The mounting surface is couplable with the solar panel to elevate and orient the solar panel above a surface of the roof. The mounting unit also includes a flexible membrane material that is coupled with the first flange of the base and that extends laterally therefrom. The mounting unit further includes an adhesive or tape that is applied to an underside of the second flange so that the second flange is free of the flexible membrane material. The flexible membrane material is couplable with the roof and the adhesive or tape is adherable to the roof to secure the mounting unit to the roof.

A non-slip roof attachment system for attaching structures to residential and commercial roofs without the use of penetrations to roofing shingles and sealing layers is described. The non-slip attachment system may be used to attach roof mounted systems such as solar panels. The non-slip attachment system also allows for the quick removal of such roof mounted systems rapidly and without the need for repair of penetrations.

A light-concentrating lens assembly for a solar energy system, the assembly comprising a primary off-axis quarter-section parabolic reflector for reflecting incident light, a secondary off-axis quarter-section parabolic reflector for receiving light reflected from the primary off-axis quarter-section parabolic reflector, a compound paraboloid concentrator (CPC) for receiving light reflected from the secondary off-axis quarter-section parabolic reflector and a housing for holding the primary and secondary off-axis parabolic reflectors as well as the CPC.

The present specification relates generally to solar roof panels and more specifically to an interlocking solar roof panel, method of installation thereof, and related kit. The interlocking solar roof panel comprises a rectangular frame, configured to hold a photovoltaic panel, wherein the rectangular frame has at least one free edge opposite at least one connecting edge; at least one male component, disposed at a point along the at least one connecting edge; at least one female component, disposed at a point along the at least one free edge and configured to connect with the at least one male component; and a photovoltaic panel. A kit comprising at least one interlocking solar roof panel and at least one bracket is also disclosed. The interlocking solar roof panel may increase the visual appeal of a series of solar roof panels installed on a roof.

Floating element (1) for realizing floating structures for supporting photovoltaic panels and method for producing said floating element (1). The floating element (1) comprises: a first element (2) which can be obtained by injection moulding, which configures a first coupling portion (3); a second element (4) which can be obtained by injection moulding, which configures a second coupling portion (5). The first element (2) and the second element (4) are mutually configured so that the first coupling portion (3) and the second coupling portion (5) can be seal-coupled with respect to each other so that they define a sealed chamber, when coupled.

A solar assembly (200) includes a solar module (100) including a solar laminate (102) mounted within a frame (104) that circumscribes the solar laminate. The solar assembly also includes a mount (202) supporting the solar module including a first end and an opposing second end, wherein the first end is attached to the solar module. The solar assembly further includes a structural adhesive compound (210) and a mounting surface (230). The structural adhesive compound is positioned between the mount second end and the mounting surface to facilitate bonding the mount to the mounting surface.

The invention relates to a new way of stabilizing and mounting solar panels in the form of conventional heat exchangers comprising a trough and a glass cover or of a photovoltaic panel on house walls with the aid of frames made of natural or artificial stones which are made break-resistant using fiber materials and are stabilized in such a way that the panels are also break-resistant on impact and can be mounted as self-supporting structures on a wall; furthermore, the panels in particular satisfy high standards in respect of esthetics and are low-maintenance and thus permanently appealing. Multiple solar panels comprising stone frames can form entire stone-solar panel facades.