An integrated preassembled solar panel module includes a solar panel configured for receiving and converting solar radiation to produce electrical power. Multiple mounting feet are coupled to the solar panel at selected locations. One or more sheathing anchors are configured for coupling the mounting feet to roof sheathing at locations not overlapping roof rafters and thereby securing the solar panel to the roof sheathing without accessing an underside of the roof sheathing.

Embodiments of the disclosure provide a method for manufacturing a photovoltaic module, including: providing at least one cell string, an end portion of each cell overlaps with an end portion of an adjacent cell to form a corresponding overlapping welding region; for each overlapping welding region, forming a film insertion opening between stacked end portions of the two adjacent cells forming the each overlapping welding region; providing at least one film strip, and inserting a part of each film strip into a corresponding film insertion opening, such that a width of the part of the each film strip inserted into the corresponding film insertion opening is larger than a width of the remaining part of the each film strip; and closing each film insertion opening.

Disclosed are a conductive member for connecting photovoltaic cells and a manufacturing method for the conductive member, and a photovoltaic module and a manufacturing method therefor. The conductive member comprises a first segment and a second segment in a length direction thereof, wherein the first segment and the second segment both have a planar contact surface; the second segment has a reflective surface facing away from a planar contact surface thereof; the first segment has a first cross section perpendicular to a length direction thereof; the second segment has a second cross section perpendicular to a length direction thereof; and the area of the first cross section is equal to the area of the second cross section.

Photovoltaic devices with very high breakdown voltages are described herein. Typical commercial silicon photovoltaic devices have breakdown voltages below 50-100 volts (V). Even though such devices have bypass diodes to prevent photovoltaic cells from going into breakdown, the bypass diodes have high failure rates, leading to unreliable devices. A high-efficiency silicon photovoltaic cell is provided with very high breakdown voltages. By combining a device architecture with very low surface recombination and silicon wafers with high bulk resistivity (above 10 ohms centimeter (-cm)), embodiments described herein achieve breakdown voltages close to 1000 V. These photovoltaic cells with high breakdown voltages improve the reliability of photovoltaic devices, while reducing their design complexity and cost.

The photovoltaic module includes at least one cell string, including multiple solar cell sheets, and adjacent solar cell sheets in the multiple solar cell sheets are connected to each other by multiple welding strips. In some embodiments, the photovoltaic module further includes multiple welding strips, where each of the multiple welding strips is in electrical contact with a corresponding bus bar, each of the multiple welding strips includes multiple bending portions arranged continuously along a second direction. In addition, along the second direction, an orthographic projection of a central line of each of the multiple welding strips on a back surface of the solar cell sheet coincides with an orthographic projection of a central line of the corresponding bus bar and/or an orthographic projection of a central line of each of the multiple bonding pads on the corresponding bus bar on the back surface of the solar cell sheet.

The photovoltaic module includes at least one cell string, including multiple solar cell sheets, and adjacent solar cell sheets in the multiple solar cell sheets are connected to each other by multiple welding strips. In some embodiments, the photovoltaic module further includes multiple welding strips, where each of the multiple welding strips is in electrical contact with a corresponding bus bar, each of the multiple welding strips includes multiple bending portions arranged continuously along a second direction. In addition, along the second direction, an orthographic projection of a central line of each of the multiple welding strips on a back surface of the solar cell sheet coincides with an orthographic projection of a central line of the corresponding bus bar and/or an orthographic projection of a central line of each of the multiple bonding pads on the corresponding bus bar on the back surface of the solar cell sheet.

The present inventive concept provides a solar cell and a method for manufacturing the solar cell. The solar cell comprises a solar cell layer on a substrate and an encapsulation layer provided on the solar cell layer. The encapsulation layer comprises a metal oxide doped with a dopant material or a metal oxynitride doped with a dopant material; and the metal oxide or the metal oxynitride comprises at least one metal selected from the group consisting of W, Nb, and Sn.

Systems, methods and apparatus related to a multijunction solar cell. The apparatus comprises a first sub-solar cell, a second sub-solar cell in series with the first sub-solar cell and one or more quantum wells. At least some of the quantum wells are disposed in a region of the first sub-solar cell, and have a thickness and a bandgap sized such that a bandgap in selected quantum wells are less than a bandgap of a material of the first sub-solar cell and greater than a bandgap of a material of the second sub-solar cell resulting in radiative coupling between the first sub-solar cell and the second sub-solar cell.

A method of deposition on a substrate used for the manufacture of a solar cell is provided. The method includes depositing a first conductive pattern on a first side of the substrate. The first conductive pattern is one of a plurality of busbars and a plurality of fingers. The method includes providing a screen over the substrate. The screen includes a set of openings. The screen has a bottom side having a varying vertical profile including low portions and high portions. The method includes transferring a printing material from the screen to the substrate through the set of openings to print a second conductive pattern on the first side of the substrate. The second conductive pattern is the other one of the plurality of busbars and the plurality of fingers. During the printing of the second conductive pattern, the first conductive pattern is substantially wet and the screen is disposed over the substrate in a manner such that the high portions are elevated above the first conductive pattern.

A method of deposition on a substrate used for the manufacture of a solar cell is provided. The method includes depositing a first conductive pattern on a first side of the substrate. The first conductive pattern is one of a plurality of busbars and a plurality of fingers. The method includes providing a screen over the substrate. The screen includes a set of openings. The screen has a bottom side having a varying vertical profile including low portions and high portions. The method includes transferring a printing material from the screen to the substrate through the set of openings to print a second conductive pattern on the first side of the substrate. The second conductive pattern is the other one of the plurality of busbars and the plurality of fingers. During the printing of the second conductive pattern, the first conductive pattern is substantially wet and the screen is disposed over the substrate in a manner such that the high portions are elevated above the first conductive pattern.