Abstract:
A second protective member has a slit for exposing a lead wiring member from a solar cell panel. A terminal box is connected to the lead wiring member from the slit in the second protective member. A bonding member bonds the terminal box and the second protective member. A peripheral portion around the slit in the second protective member projects farther than a non-peripheral portion other than the peripheral portion. The bonding member is provided in the non-peripheral portion in the second protective member.
Abstract:
This solar-cell module and method is provided with a plurality of solar cells and a connecting member that connects the light-receiving-surface side of one solar cell to the back-surface side of an adjacent solar cell. Said connecting member comprises a conductor that includes the following: a flat section laid out on the light-receiving-surface side of the aforementioned one solar cell, a flat section laid out on the back-surface side of the other solar cell, and a middle section that joins said flat sections to each other. The hardness of a boundary region between one of the flat sections and the middle section is no more than 1.25 times the hardness of that flat section.
Abstract:
This solar-cell module is provided with a plurality of solar cells and a connecting member that connects the light-receiving-surface side of one solar cell to the back-surface side of an adjacent solar cell. Said connecting member comprises a conductor that includes the following: a flat section laid out on the light-receiving-surface side of the aforementioned one solar cell, a flat section laid out on the back-surface side of the other solar cell, and a middle section that joins said flat sections to each other. The hardness of a boundary region between one of the flat sections and the middle section is no more than 1.25 times the hardness of that flat section.
Abstract:
A solar cell module includes solar cells having main surfaces to which inter-cell wiring members are connected, and an insulating member disposed on the main surfaces and the wiring members, and a first lead-out wire provided to the insulating member. The insulating member includes a first insulating layer formed of polyester resin, a second insulating layer formed of polyolefin or EVA and provided between the first insulating layer and the lead-out wires, and a third insulating layer formed of polyolefin or EVA and provided between the first insulating layer and the main surfaces. The third insulating layer has a thickness in a direction perpendicular to the main surfaces larger than a thickness of the second insulating layer.
Abstract:
A solar cell module includes: a solar cell group including a plurality of solar cell strings arranged in a second direction, the plurality of solar cell strings each including a plurality of solar cells arranged in a first direction; a terminal box that outputs power from the solar cell group out of the solar cell module; and an interconnect tab that connects the terminal box to a first end solar cell located at an end in the first direction in one of the plurality of solar cell strings that is located at an end in the second direction, and the interconnect tab does not overlap with the first end solar cell.
Abstract:
Disclosed is a method of manufacturing a solar cell module that comprises a step of obtaining a solar cell module that includes a translucent or transparent substrate including a substrate provided with translucency or transparency, and an antireflection film formed on a surface of the substrate provided with translucency or transparency, and a siloxane coat step of forming a siloxane layer on a surface of the antireflection film.