A method for producing an intermediate product for obtaining a photovoltaic module comprising a plurality of solar cells, said method comprising the following steps: (a) localized deposition on a substrate (4) of a layer of metal (8) so as to cover at least one portion (401) of the substrate, (b) deposition on this localized layer (8) of a layer (41) of conductive material, said layer coating the localized layer (8).

The invention concerns a method of manufacturing a photovoltaic module comprising at least two electrically connected photovoltaic cells, each photovoltaic cell (4.sub.i) being multi-layered structure disposed on a substrate (6) having down-web direction (X) and a cross-web direction (Y). The method comprises providing a plurality of spaced-apart first electrode strips (8.sub.i) over the substrate (6), each first electrode strip extending along the cross-web direction (Y), and providing, over the first electrode strips layer, at least one insulating strip (14a, 14b) of an insulator material extending along the down-web direction (X), each insulating strip defining a connecting area and an active area. A functional stack (20) comprising a full web coated layer of photoactive semiconductor material is formed over the first layer and within the active area. A plurality of spaced-apart second electrode strips (28.sub.i) are provided within the active area, each second electrode strip extending along the cross-web direction (Y), so as to form photovoltaic cells and a photovoltaic module is formed by electrically connecting at least two adjacent photovoltaic cells, by extending over the insulating strips (14a, 14b) electrical connection patterns to electrically connect, within the connecting area(s), the second electrode strip of an photovoltaic cell to the first electrode strip of an adjacent photovoltaic cell.

Disclosed are a solar cell and preparing method of the same. The solar cell includes a back electrode layer on a support substrate, a molybdenum oxide layer on the back electrode layer, a light absorbing layer on the molybdenum oxide layer, and a front electrode layer on the light absorbing layer.

Disclosed are a solar cell and preparing method of the same. The solar cell includes a back electrode layer on a support substrate, a molybdenum oxide layer on the back electrode layer, a light absorbing layer on the molybdenum oxide layer, and a front electrode layer on the light absorbing layer.

A thin-film solar module with a substrate and a layer structure applied thereon. The layer structure has a rear electrode layer, a front electrode layer, and an absorber layer arranged between the rear electrode layer and the front electrode layer. The absorber layer has doping of a first conductor type, while the front electrode layer has doping of a second conductor type. Serially connected solar cells are formed in the layer structure by patterning zones having a first patterning trench subdividing the rear electrode layer, a second patterning trench subdividing the absorber layer, and a third patterning trench subdividing the front electrode layer.

A thin-film solar cell contains: a lens material layer, a conductive contact layer, a first n-p semiconductor layer, a second n-p semiconductor layer, an insulation layer, a transparent conducting layer, a substrate, multiple first vias, multiple insulators, and multiple electrical conductors. A respective first via passes through the lens material layer, the conductive contact layer, and the first n-p semiconductor layer. The multiple insulators are accommodated in the respective first via, a top of a respective insulator is connected with the second n-p semiconductor layer, and a bottom of the respective insulator is connected with the insulation layer. The respective insulator includes a respective second via. A respective electrical conductor is formed in the respective second via, a top of the respective electrical conductor is connected with a respective transparent conducting layer, and a bottom of the respective electrical conductor is connected with the substrate.

A thin-film solar cell contains: a lens material layer, a conductive contact layer, a first n-p semiconductor layer, a second n-p semiconductor layer, an insulation layer, a transparent conducting layer, a substrate, multiple first vias, multiple insulators, and multiple electrical conductors. A respective first via passes through the lens material layer, the conductive contact layer, and the first n-p semiconductor layer. The multiple insulators are accommodated in the respective first via, a top of a respective insulator is connected with the second n-p semiconductor layer, and a bottom of the respective insulator is connected with the insulation layer. The respective insulator includes a respective second via. A respective electrical conductor is formed in the respective second via, a top of the respective electrical conductor is connected with a respective transparent conducting layer, and a bottom of the respective electrical conductor is connected with the substrate.

A solar cell module of an embodiment includes: a first solar panel having a plurality of first sub modules each including a plurality of first solar cells; and a second solar panel layered with the first solar panel, the second solar panel having a plurality of second solar cells. The first solar panel exists on the side where light is incident. The first solar panel and the second solar panel are electrically connected in parallel. The first solar cells included in the first submodules are electrically connected in series. The first submodules are electrically connected in parallel.

A solar cell module of an embodiment includes: a first solar panel having a plurality of first sub modules each including a plurality of first solar cells; and a second solar panel layered with the first solar panel, the second solar panel having a plurality of second solar cells. The first solar panel exists on the side where light is incident. The first solar panel and the second solar panel are electrically connected in parallel. The first solar cells included in the first submodules are electrically connected in series. The first submodules are electrically connected in parallel.

[Problem] To provide a method for manufacturing an element which does not lead to the occurrence of a short due to etching, and which suppresses the deterioration of a photoelectric conversion layer. [Solution] An element manufacturing method, wherein the method includes the following steps which are performed on an element material including an electrode formed on a substrate, the electrode having a first electrode and a second electrode which are separated from each other, and a photoelectric conversion layer formed in a region that includes the first electrode and the second electrode: a step in which a first back-side electrode and a second back-side electrode are formed at positions on the photoelectric conversion layer corresponding to a first electrode and a second electrode, wherein the first back-side electrode and the second back-side electrode are not connected; a step in which etching is performed using the first back-side electrode and the second back-side electrode as a mask; and a connection electrode formation step in which a connection electrode for connecting the first back-side electrode and the second back-side electrode is formed.