Abstract: The present disclosure provides a solar cell and a method for producing same. The solar cell includes: a substrate; a first passivation film, an anti-reflection layer and at least one first electrode formed on a front surface of the substrate; and a tunneling layer, a field passivation layer and at least one second electrode formed on a rear surface. The field passivation layer includes a first field passivation sub-layer and a second field passivation sub-layer; a conductivity of the first field passivation sub-layer is greater than a conductivity of the second field passivation sub-layer, and a thickness of the second field passivation sub-layer is smaller than a thickness of the first field passivation sub-layer; either the at least one first electrode or the at least one second electrode includes a silver electrode, a conductive adhesive and an electrode film that are sequentially formed in a direction away from the substrate.

Abstract: A method for preparing a selective emitter solar cell includes: forming a textured surface with a plurality of protrusions in the first regions and the second regions of the surface of the semiconductor substrate, wherein each protrusion has a cross-sectional shape that is trapezoidal or trapezoid-like in a thickness direction of the semiconductor substrate; performing a diffusion treatment on at least part of protrusions to form a first doped layer, and forming a first oxide layer above the first regions; re-etching the surface of the semiconductor substrate by using the first oxide layer as a mask, to etch each protrusion in the second regions to form a pyramid structure, such that the first doped layer in the second regions is etched to form a second doped layer with a doping concentration lower than a doping concentration of the first doped layer.

Abstract: A photovoltaic cell is provided, which includes a substrate; a first passivation layer and a first anti-reflection layer disposed on a front surface of the substrate; and a second passivation layer, a PPW layer and at least one silicon nitride layer SiuNv (1<u/v<4) disposed on a rear surface of the substrate. The at least one silicon nitride layer has a refractive index and a thickness in respective ranges of 1.9 to 2.5 and 50 nm to 100 nm. The second passivation layer includes at least one aluminum oxide layer AlxOy (0.8<y/x<1.6), a refractive index and a thickness of which are respectively in ranges of 1.4 to 1.6 and 4 nm to 20 nm. The PPW layer includes at least one silicon oxynitride layer SirOsNt (r>s>t), a refractive index and a thickness of which are respectively in ranges of 1.5 to 1.8 and 1 nm to 30 nm.

Abstract: Provided is a method for fabricating a photovoltaic module. The method includes: providing a cell sheet having a predetermined thickness, and cutting the cell sheet along a direction parallel to busbars of the cell sheet, to form cutting lines on a surface of the cell sheet; splitting the cell sheet along the cutting lines, to obtain multiple cell pieces; coating, for each of the cell pieces, a conductive adhesive material on a busbar located at an edge of the cell piece; arranging the multiple cell pieces in a preset overlapping manner; curing the conductive adhesive material among the cell pieces, to form a cell string in which the cell pieces are conductively connected; and encapsulating the cell string to obtain the photovoltaic module.

Abstract: A solar cell and a photovoltaic module including the solar cell. The solar cell includes: a semiconductor substrate including a first surface and a second surface opposite to each other; a first dielectric layer located on the first surface; a first N+ doped layer located on a surface of the first dielectric layer; a first passivation layer located on a surface of the first N+ doped layer; a first electrode located on a surface of the first passivation layer; a second dielectric layer located on the second surface; a first P+ doped layer located on a surface of the second dielectric layer; a second passivation layer located on a surface of the first P+ doped layer; and a second electrode located on a surface of the second passivation layer.

Abstract: The present disclosure provides a back-contact solar cell and a solar cell module. The back-contact solar cell includes: a substrate including a light-receiving surface and a back surface opposite to the light-receiving surface, wherein the substrate includes a center region and connecting regions on opposite sides of the center region; positive electrodes and negative electrodes disposed on the back surface of the substrate; auxiliary positive electrodes, disposed on one or both of the light-receiving surface and a side surface of each of the connecting regions, and configured to be electrically coupled to the plurality of positive electrodes; and auxiliary negative electrodes, disposed on one or both of the light-receiving surface and the side surface of each of the connecting regions, and configured to be electrically coupled to the plurality of negative electrodes.

Abstract: The present disclosure provides a photovoltaic stringer and a method for manufacturing a photovoltaic ribbon. The photovoltaic stringer includes a first clamping component to pull a ribbon from a ribbon reel, a second clamping component to coordinate with the first clamping component to stretch the ribbon, a cutting component to cut the ribbon, and, at least one first electrode and at least one second electrode to supply power to the ribbon. The method for manufacturing a photovoltaic ribbon comprises acquiring a ribbon reel and pulling a ribbon, stretching the ribbon and cutting the ribbon to obtain a cut ribbon, and performing an annealing process on the cut ribbon.

Abstract: A method for manufacturing a solar cell string includes: providing a first adhesive layer, wherein the first adhesive layer includes N placement regions being used for N solar cells respectively; placing the N solar cells on the placement regions; laying first wires on a surface of at least one solar cell away from the first adhesive layer, and stretching the first wires across adjacent placement regions to electrically connect two adjacent solar cells; disposing a second adhesive layer on the surface of the at least one solar cell of the N solar cells away from the first adhesive layer, wherein the first wires are located between the second adhesive layer and the at least one solar cell; performing a pressing treatment to bond and fix the first adhesive layer, the first wires, the at least one solar cell of the N solar cells and the second adhesive layer.

Abstract: The embodiments of the present disclosure relate to the field of photovoltaic module technology, and provide a photovoltaic frame, a photovoltaic module and a method for manufacturing the photovoltaic frame. The photovoltaic frame comprises: a top support portion, a bottom support portion and a transverse edge portion. The top support portion and the transverse edge portion enclose a holding slot, and the top support portion has a bearing surface facing the holding slot. The bottom support portion is arranged opposite to the top support portion, and the transverse edge portion is located at one side of the top support portion away from the bottom support portion. The photovoltaic frame is molded by a carbon steel sheet material after processing.

Abstract: The embodiments of the present disclosure provide a photovoltaic module including a base plate, a cell string and a cover plate stacked in order; a first packaging layer located between the base plate and the cover plate and surrounding the cell string, the first packaging layer, the base plate and the cover plate defining a sealed space; and a moisture treatment layer located in the sealed space. The moisture treatment layer includes at least one of a functional layer and a moisture detection layer. The functional layer is adaptive to absorb moisture and be converted into a solidified layer, the solidified layer has a degree of cross linking greater than a degree of cross linking of the functional layer. The moisture detection layer is adaptive to detect and determine whether there is moisture in the sealed space through response information of the moisture detection layer.

Abstract: A single crystal furnace is provided, including a main furnace chamber; an auxiliary furnace chamber communicating with the main furnace chamber; and a material chamber provided with a charging inlet and a charging mechanism, wherein the material chamber is communicated with the main furnace chamber through the charging inlet, the charging mechanism is telescopically coupled to the charging inlet for charging materials into a crucible in the main furnace chamber. In the single crystal furnace, the material chamber is provided, so that charging operation may be performed during taking out the monocrystalline silicon rod, thereby effectively shortening the time consumed by taking out the monocrystalline silicon rod and the charging operation, and improving production efficiency.

Abstract: A solar cell and a photovoltaic module including the solar cell. The solar cell includes: a semiconductor substrate including a first surface and a second surface opposite to each other; a first dielectric layer located on the first surface; a first N+ doped layer located on a surface of the first dielectric layer; a first passivation layer located on a surface of the first N+ doped layer; a first electrode located on a surface of the first passivation layer; a second dielectric layer located on the second surface; a first P+ doped layer located on a surface of the second dielectric layer; a second passivation layer located on a surface of the first P+ doped layer; and a second electrode located on a surface of the second passivation layer.

Abstract: Provided is a solar cell and a method for manufacturing the same, the method includes: forming a doped layer on a surface of a semiconductor substrate, the doped layer having a first doping concentration of a doping element in the doped layer; depositing, on a surface of the doped layer, a doped amorphous silicon layer including the doping element; selectively removing at least one region of the doped amorphous silicon layer; performing annealing treatment, for the semiconductor substrate to form a lightly doped region having the first doping concentration and a heavily doped region having a second doping concentration in the doped layer, the second doping concentration is greater than the first doping concentration; and forming a solar cell by post-processing the annealed semiconductor substrate. The solar cell and the method for manufacturing the same simplify the manufacturing process and improve conversion efficiency of the solar cell.

Abstract: Provided is a method for passivating a silicon-based semiconductor device and a silicon-based semiconductor device. The method includes the following steps: cutting, by using a cutting process, a preset region of the silicon-based semiconductor device, to form a first surface associated with the preset region; smoothing the first surface to adjust a surface appearance of the first surface, so that a height difference between a protrusion and a recess of a non-marginal region on the first surface is less than 20 nm; and passivating the smoothed first surface to form a first passivation layer on the first surface. The present application can reduce or avoid the problem of efficiency reduction caused by cutting a silicon-based semiconductor device and help to obtain a more efficient silicon-based semiconductor device.

Abstract: A photovoltaic cell array and a photovoltaic module are provided. The photovoltaic cell array includes multiple solar cells and a flexible metal conductive strip. Each of an upper surface and a lower surface of each solar cell is arranged with a segment electrode. In adjacent two solar cells which are respectively referred to as a first solar cell and a second solar cell, the segment electrode on the lower surface of the first solar cell is connected with the segment electrode on the upper surface of the second solar cell by the flexible metal conductive strip. The photovoltaic cell array has a stack structure in a normal direction of the upper surface of the solar cell, and a connection region at which the segment electrode is connected with the flexible metal conductive strip is located outside an overlapped region of the stack structure.

Abstract: Provided is a solar cell, a shingled photovoltaic module, and a method for manufacturing solar cell, the solar cell includes a body portion, a first extending portion and a second extending portion provided at two ends of the body portion; a thickness of the body portion is greater than a thickness of the first extending portion and a thickness of the second extending portion. In the shingled photovoltaic module, adjacent solar cells can be electrically connected through the first extending portion and the second extending portion, and the adjacent solar cells do not need to be stacked in a thickness direction to achieve electrical connection, so that space in the thickness direction occupied by the stacked solar cells is reduced, and light-receiving area of the solar cell is not decreased, thereby improving photoelectric conversion efficiency of the solar cell, reducing the number of solar cells required, and saving cost.

Abstract: The present disclosure provide a solar cell, including: a substrate, an interface passivation layer covering a rear surface of the substrate, and an electrode disposed at a side of the interface passivation layer facing away from the substrate, the interface passivation layer including a first interface passivation sub-layer corresponding to a portion of the interface passivation layer between adjacent electrodes, and a second interface passivation sub-layer corresponding to a portion of the interface passivation layer where disposed between the substrate and the electrode; a field passivation layer, at least partially disposed between the interface passivation layer and the electrode; and a conductive enhancement layer, at least partially disposed at a side of the first interface passivation sub-layer away from the substrate to enable carriers in the first interface passivation sub-layer to flow to the electrode, where a resistivity of the conductive enhancement layer is smaller than a resistivity of the fie

Abstract: A series-connected solar cell module is provided, which includes multiple solar cell units. each of the multiple solar cell units comprises multiple solar cells. In each of the multiple solar cell units, a back surface of one of two adjacent solar cells is electrically connected to a front surface of the other of the two adjacent solar cells through a conductive material. A first insulating layer and a second insulating layer are provided at positions where the conductive material is in close contact with the two adjacent solar cells. Therefore, adjacent solar cells can be arranged in close contact with each other, to achieve a seamless contact, thereby increasing the effective area of the series-connected solar cell module.

Abstract: Disclosed is a solar cell, including: a substrate; an emitter, a first passivation film, an antireflection film and a first electrode sequentially disposed on an upper surface of the substrate; a tunneling layer, a retardation layer, a field passivation layer, a second passivation film and a second electrode sequentially disposed on a lower surface of the substrate. The retardation layer is configured to retard a migration of a doped ion in the field passivation layer to the substrate. The retardation layer includes a first retardation sub-layer overlapping with a projection of the second electrode and a second retardation sub-layer misaligning with a projection of the second electrode, and at least the second retardation sub-layer is an intrinsic semiconductor. A thickness of the first retardation sub-layer is smaller than a thickness of the second retardation sub-layer in a direction perpendicular to the surface of the substrate.

Abstract: The present disclosure relates to a method and apparatus for manufacturing a semiconductor sheet assembly. The method for manufacturing a semiconductor sheet assembly includes positioning a semiconductor sheet, and determining a first region to be grooved and a defect position in the first region; cutting and grooving the semiconductor sheet along the defect position in the first region; and splitting the semiconductor sheet that is cut and grooved.