An embodiment of the present disclosure provides an encapsulant film and a manufacturing method thereof, and a solar cell module and a manufacturing method thereof. the encapsulant film is configured for a solar cell module, the solar cell module includes a plurality of welding strips, the encapsulant film includes a first region, an orthogonal projection of the first region on a surface where the solar cell module is located overlaps at least partially an orthogonal projection of at least one of the plurality of welding strips, and a film thickness of the first region is different from a film thickness of an other region of the encapsulant film. The solar cell module using the encapsulant film can reduce the amount of encapsulant used and fully protect the welding strip.

Embodiments of the present disclosure provide a solar cell module and a manufacturing method thereof. The manufacturing method includes: providing a solar cell string; arranging welding strips on a back surface of the solar cell string; arranging a first encapsulant material on a back surface of the welding strip, to form a first encapsulant material layer; on the back surface of the solar cell string, arranging a second encapsulant material in a local region corresponding to at least one welding strip, to form a second encapsulant material layer; and laminating to form a laminate member. The manufacturing method can reduce the thickness of the encapsulant film on the back surface of the solar cell, and reduce the distance between the back plate material and the solar cell string, and is capable to fully protect the welding strip.

A process for the preparation of colored solar cells or colored solar cell modules containing a colored polymer film with oriented effect pigments, and colored solar cells or colored solar cell modules prepared by this process.

The present invention relates to a glass powder and a silver-aluminum paste for use on a front of an N-type double-sided solar cell comprising a conductive silver powder, a silicon-aluminum alloy powder, the glass powder and an organic vehicle. The glass powder comprises the following components by weight: 0-50% of PbO, 0-50% of BiO, 5-15% of B.sub.2O.sub.3, 8-9% of SiO.sub.2, 2-3% of Al.sub.2O.sub.3 and 5-15% of ZnO; silicon and aluminum in the glass powder have a mass ratio of 4:1-5:1; the conductive silver powder has a content of 80-90 wt %; the conductive silver powder comprises a nano-silver powder and a silver alloy powder, and the nano-silver powder to the silver alloy powder have a mass ratio of 1:18-1:90.

One embodiment can provide a photovoltaic roof tile module. The photovoltaic roof tile module can include a front encapsulant layer and a back encapsulant layer where both the front and back encapsulant layers include different pigments. The front encapsulant layer can include a small amount of pigment that absorbs and scatters particular frequencies of visible light to give the photovoltaic roof tile a desired color. The small amount of pigment does not absorb or scatter a significant amount of infrared light. Two or more photovoltaic roof tiles can be combined to form a photovoltaic module. The two or more photovoltaic roof tiles can have different concentrations of pigment in the front encapsulant layer to give the photovoltaic module a small amount of color variation.

In accordance with one or more embodiments herein, a method of manufacturing a photovoltaic (PV) top module, to be used together with a PV bottom module, e.g an SI-based PV bottom module, is provided. The method may include monolithically interconnecting a plurality of thin film based PV sub-cells, manufactured using a perovskite material and/or a CIGS material as solar absorbing material, in series on a substrate in order to create a PV top module including at least one first PV top sub-module, and arranging metal grid lines on top and bottom contact layers of the PV top module. The metal grid lines may be arranged either above or below the top and bottom contact layers of the PV top module.

The present invention relates to a photovoltaic element comprising: i. a light transmissive, coloured multilayer top sheet having an appearance that exhibits a colouration change depending on the viewing angle, the top sheet comprising: a. a textured transparent front cover sheet, and b. a pigmented top coating layer disposed on the backside of the top sheet with respect to the direction of the incandescent light; ii. a first encapsulant layer; iii. one or more photovoltaic cells, each comprising at least one photovoltaically active surface, and comprising two electrically-conductive electrode layers with a photovoltaic material disposed between them; iv. a second encapsulant layer, and v. a back cover sheet.

A solar panel comprises a double-glass photovoltaic module mounted in a frame. The double-glass photovoltaic module comprises a plurality of solar cells embedded between a front glass sheet and a rear glass sheet. The rear glass sheet exhibits a larger extension than the front glass sheet, in at least two spatial directions, as measured in the rear glass sheet plane. The frame comprises a clamping element clamping only the rear glass sheet and not the front glass sheet of the double-glass photovoltaic module. The front glass sheet is either flush with a plane defined by inner edges of a front face of the frame or protrudes beyond the front face of the frame.

The invention relates to improved methods and implementation of reliably manufacturing laminated solar panel products having one or more axis of curvature, wherein at least one solar cell also has one or more axis of curvature, in a manufacturing plant, the manufacturing plant being capable of continuous, optimized operation. A substrate and a superstrate having a doubly-curved geometry may be assembled with a core disposed therebetween, the core comprising a solar cell array including at least one solar cell. During the lamination process, the plant substantially eliminates cracking of the at least one solar cell of the solar array through controlled and uniform application of lamination pressure and temperature that applies uniform local pressure simultaneously to each cell, resulting in a durable and reliable product. The invention further relates to a plant and/or facility having efficient, effective, and repeatable results relating to such methods.

The invention relates to an apparatus, system and method for a two-axis of curvature solar panel with doubly-curved solar cells. The solar panel comprises substrate and superstrate preforms having two-axis of curvature geometry and at least one rigid layer. The preforms may comprise one or more strengthened glass and/or polymer layers. A core comprising lower and upper encapsulant layers sandwiching a solar cell array is disposed between substrate and superstrate preforms forming a lamination stack. The solar cells may be tacked to the lower encapsulant layer. The preforms may be formed by flat lamination followed by thermoforming. The curved solar panel may comprise a flange suitable for assisting the assembly process and be made of materials with disparate mechanical and thermal properties. A method is provided wherein preforms and core layers are assembled and laminated, and post-processing that may include trimming and edge sealing.