A method for forming a solar panel can include attaching one or more tacking pads to one or both of a first surface of a first solar panel subassembly and a second surface of a second solar panel subassembly. The method further includes dispensing an adhesive onto at least one of the first and second surfaces. The first and second surfaces are placed in contact with the one or more tacking pads, thereby tacking the first and second solar panel subassemblies together, during which the first and second surfaces contact the adhesive, thereby decreasing a thickness and increasing a surface area of the adhesive. Subsequently, the adhesive is cured. The tacking pad(s) maintain fixed alignment of the solar panel subassemblies during curing of the adhesive, and establish a bond line of the adhesive.

Disclosed are method and system for treating concrete in mixing drums of delivery vehicles having automated rheology (e.g., slump) monitoring systems programmed to dose fluids into concrete based on the monitored rheology. The present invention takes into account a Revolution-To-Discharge value (RTD) which reflects drum rotations needed to move concrete towards and through the mixing drum opening from which concrete is discharged, and also takes into consideration a Volume-Per-Revolution-Upon-Discharge (VPRUD) value which reflects the relation between the rate of discharge and rheology (e.g., slump) of concrete upon discharge. The invention is especially useful for reclaiming concrete in the drum after delivery and can confirm rheology based upon peak (maximum) discharge pressure. The present inventors found surprisingly that discharge pressure readings are useful for recalibrating automated rheology monitoring systems as well as for reporting and/or treating the remainder concrete.

Embodiments of the present disclosure are related to solar module mounting systems. A system may include an adhesion sheet configured to be secured to a roof of a structure via an adhesive. The system may further include at least one clamp configured for securing at least one solar module to the adhesion sheet. Other embodiments are related to methods of attaching one or more solar modules to a structure.

The present disclosure concerns a panel capable of bending under the effect of a load and having a peripheral surface provided with a plurality of pivoting attachment devices; each attachment device comprises: a metal gripping member adhered to the peripheral surface of the panel; and a metal clip cooperating by interlocking with the gripping member and configured to allow the gripping member to pivot when the panel bends.

Provided is a solar cell module having improved weatherability. A frame body has a groove. A module main body is inserted into the groove. An adhesive material is disposed in the groove. The adhesive material is provided at least on a part of a frame body portion excluding frame body corner portions. Through holes communicating with the groove are provided at the corner portions of the frame body.

A frame system for a solar cell module, the frame system includes: a first frame member including a first body that is configured to be fixed to a substrate of the solar cell module and a male coupling portion that is protruded from the first body; and a second frame member including a second body that is configured to be fixed to an installation object and a female coupling portion that is configured to be coupled to the male coupling portion, wherein at an outer surface of the male coupling portion, a protrusion including an inclined surface having an upper width smaller than a lower width and a separation prevention surface that is positioned at a lower end portion of the inclined surface is formed, and at an inside of the female coupling portion, a protrusion coupling portion that corresponds to the protrusion is formed.

A mounting assembly for securing fixtures to a mounting structure may include a first fastener, a washer, a mounting bracket, and second fastener. The first fastener may be coupled to the mounting structure through a mounting aperture. The washer may be disposed around shaft of the first fastener between a head of the first fastener and the mounting surface. The mounting bracket may be disposed on top of the first fastener. The second fastener may be disposed through the mounting bracket and coupled to head of the first fastener. The washer may be a sealing washer that dispenses liquid sealant under compressive force to moisture-proof the securement of the first fastener to the mounting surface.

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 focusing polymer foil for use in forming an optical element for use in a solar concentrator, and an optical element for use in a solar concentrator, arranged such that the focusing polymer foil is removable in order to renew the function of the optical element following damage and/or wear to the focusing polymer foil due to environmental conditions. A method of repair of such a damaged optical element, and methods of making the focusing polymer foil and optical element.

A method is provided of fabricating a photo voltaic generator panel (15) including a polymer back sheet (24) with at least one attachment feature (21) so as to provide means of attaching the panel to a structural support (25) upon subsequent installation. At least one polymer attachment feature (21) is applied to the outer side of the polymer back sheet of the panel during the manufacturing process for the panel whereby the attachment feature projects with respect to the back sheet. The application may be in conjunction with a lamination process, or subsequent to the lamination process, or as an integral part of the back sheet manufacturing process. The attachment feature is adapted to engage with a corresponding feature (26) or features to be found on a support structure (25) located at a site for the installation of the panel. The said at least one polymer attachment feature and said outer side of the polymer back sheet have a similar thermal expansion coefficient.