Provided is a solar cell module and a manufacturing method thereof, and a photovoltaic module. The solar cell module includes a substrate; and conductive layers arranged on a surface of the substrate and separated from each other. Solar sub-cells are provided on a surface of the conductive layer. Grooves are provided between adjacent solar sub-cells to separate the solar sub-cells from each other. Each of the solar sub-cells includes a hole transport layer, a perovskite layer and an electron transport layer that are stacked on the surface of the conductive layer. The hole transport layer of each solar sub-cell includes branch electrodes separated from each other. Each of the branch electrodes contacts an interior of the conductive layer. The solar cell module further includes an electrode. The electrode successively passes through the electron transport layer and the perovskite layer and is connected to the branch electrodes.

A solar battery cell, comprises a substrate; a first electrode provided on the substrate; a photoelectric conversion layer provided on the first electrode; a second electrode provided on the photoelectric conversion layer; and a barrier layer so provided as to cover a side portion of the photoelectric conversion layer, wherein the photoelectric conversion layer has an electron transport layer, a light absorption layer provided on the electron transport layer, and a hole transport layer provided on the light absorption layer, the light absorption layer includes a compound having a perovskite crystal structure, and the barrier layer is a dense inorganic material layer.

A dye-sensitized photoelectric conversion element including a cell is disclosed. The cell includes a conductive substrate and a transparent conductive layer, a counter substrate facing the conductive substrate and including a metal substrate, a semiconductor layer provided on the conductive substrate, a sealing portion bonding the conductive and the counter substrates, a connecting portion connecting one end of a wiring material and the metal substrate, and a portion to be connected which is connected to the other end of the wiring material, the connecting portion contains first conductive particles, a filler, and a binder resin, the wiring material contains second conductive particles and a binder resin, an average particle diameter of the first conductive particles is greater than that of the filler in the connecting portion, and a content rate of the filler in the connecting portion is greater than that of the filler in the wiring material.

A photoelectric conversion element includes a frame-shaped insulating sealing part that is disposed between the plurality of first electrodes and the cover and defines a space inside the photoelectric conversion element, a photoelectric conversion part formed on an upper surface of a first electrode in the space; a second electrode formed in the space, which includes a flat portion and a bent portion, and insulates the photoelectric conversion part from the second electrode, an inter-cell insulating part that insulates the first electrode from the second electrode, a carrier transporting part with which the space is filled, and an insulating bonding part that has at least a portion positioned between the porous insulating part and the cover and is brought into contact with the inter-cell insulating part and with a portion of the flat portion so as to bond the inter-cell insulating part and the second electrode to each other.

A photovoltaic device (1) is provided with plurality of mutually subsequent photovoltaic device cells (1A, . . . , 1F) arranged along a direction of first device axis (D1). Each pair of a photovoltaic device cell and its successor are serially arranged through an interface region (1CD), further having a bypass function, and which extends along a second axis (D2), transverse to the first axis.

A p-n photovoltaic cell (10) comprising a crystalline-silicon structure (11) coated with a conductive film (12) formed using a p-type dopant solution and an n-type dopant solution, the p-type and n-type dopant solutions including carotenoid components. A method for manufacturing an encapsulated p-n photovoltaic cell using the p-n photovoltaic cell (10) and the use of these encapsulated photovoltaic cells (19) forming modules (15) that are used to form, with photovoltaic tiles (20), single parts with electrical energy generation and coverage functions. An electrical connection unit for a photovoltaic tile (20) that is used to simply and safely conduct the electrical energy generated by the photovoltaic tiles (20) to an inverter.

Thin-film solar cell modules and serial cell-to-cell interconnect structures and methods of fabrication are described. In an embodiment, solar cell module and interconnect includes a conformal transport layer over a subcell layer. The conformal transport layer may also laterally surround an outside perimeter the subcell layer.

Thin-film solar cell modules and serial cell-to-cell interconnect structures and methods of fabrication are described. In an embodiment, solar cell module and interconnect includes a conformal transport layer over a subcell layer. The conformal transport layer may also laterally surround an outside perimeter the subcell layer.

A device includes: a substrate; a first cell region including a first lower electrode, a first photoelectric conversion layer containing a perovskite compound, and a first upper electrode; a second cell region including a second lower electrode, a second photoelectric conversion layer containing a perovskite compound, and a second upper electrode; and an inter-cell region including a first groove which separates the lower electrodes from each other, a second groove which separates the photoelectric conversion layers from each other, a conductive part which electrically connects the first upper electrode and the second lower electrode, and a third groove which separates the upper electrodes from each other. At least either the substrate including the first and second lower electrodes, or the first and second upper electrodes are formed of a light transmissive material. A member is disposed on the light transmissive material side.

A photovoltaic device (1) is provided with a first electrode layer (11), a photovoltaic layer (13), a second charge carrier transport layer (14) and a second electrode layer (15). The photovoltaic device (1) has a plurality of mutually subsequent photovoltaic device cells (1A, . . . , 1F) arranged in a first direction (D1). Each pair of a photovoltaic cell (1C) and its successor are serially connected in an interface region (1CD). The interface region comprises an elongate region (R0) between successive first electrode layer portion (11C, 11D), a first elongate region (R1) between successive photovoltaic layer portions (13A, 13B), a second elongate region (R2) between successive second charge carrier transport layer portions (14C, 14D) and a third elongate region (R3) between successive second electrode layer (15) portions (15C, 15D). The second elongate region (R2) extends within the first elongate region (R1), and its lateral boundaries are distinct from those of the first elongate region (R1).