Abstract: This invention is directed to a flexible solar cell photovoltaic module with high light transmittance based on modified substrate, which belongs to the field of thin-film solar cell technology. The objective of the present invention to provide a technical solution for a transparent flexible solar cell module and its fabrication method. Technical features include using a stainless steel template to mold a modified polyimide PI substrate (the PI substrate). The PI substrate has light-passing through-holes, including draining holes and convergence holes, through and distributed on the PI substrate, a conductive film layer, and various stacked photoelectric conversion film layers.

Abstract: A discharge electrode array for a silicon-based thin film solar cell deposition chamber is provided, relating to solar cell technologies. The discharge electrode array includes a signal feed component having a rectangular-shaped end, a flat waist corresponding to a feed-in port located in a hallowed rectangular area on a center region of a cathode plate having a shielding cover, connecting a feed-in power supply signal by surface contact. The electrode array includes at least a set of cathode plates and an anode plate, with two cathode plates sharing or surrounding one anode plate. Uniform large area and stable discharge driven by the RF/VHF power supply signal can be achieved, and the standing wave and the skin effect can be effectively removed. The production efficiency can be improved and the cost can be reduced.

Abstract: An integrated photovoltaic modular panel for a curtain wall glass is used for the field of building integrated photovoltaic. The invention provides the standardized photovoltaic units, so that the electrodes in a photovoltaic panel main body can be internally parallel connected. The connector may be a metal piece of stamping or casting, which has a plug 1 and a socket 2 on both ends, a waist b in the middle, an inward concave straight strip 4 on both sides of the waist, an electrode plug-in socket 3 in the waist for firmly clamping solar cell, a plastic injection molding crust 5 for fixing and securing the connector, forming a module. It can combine with different kinds of glass, forming different kinds of photovoltaic curtain wall glass. The solar cell here may be an amorphous silicon solar cell.

Abstract: The present invention discloses a surface feed-in electrode structure for thin film solar cell deposition, relating to solar cell technologies. The surface feed-in electrode structure uses a signal feed-in component with a flat waist and a semicircular feed-in end to connect the signal feed-in port by surface contact. The signal feed-in port is located in a hallowed circular area of a center of the backside of a cathode plate, and feeds in an RF/VHF power supply signal. An anode plate is grounded. The cathode plate is insulated with a shielding cover, and a through-hole is configured on the shielding cover. The effects include that, by using the surface feed-in at the center of the electrode plate, the feeding line loss of single-point or multi-point feed-in configurations can be overcome. Uniform large area and stable discharge driven by the RF/VHF power supply signal can be achieved, and the standing wave and the skin effect can be effectively removed.

Abstract: A discharge electrode array for a silicon-based thin film solar cell deposition chamber is provided, relating to solar cell technologies. The discharge electrode array includes a signal feed component having a rectangular-shaped end, a flat waist corresponding to a feed-in port located in a hallowed rectangular area on a center region of a cathode plate having a shielding cover, connecting a feed-in power supply signal by surface contact. The electrode array includes at least a set of cathode plates and an anode plate, with two cathode plates sharing or surrounding one anode plate. Uniform large area and stable discharge driven by the RF/VHF power supply signal can be achieved, and the standing wave and the skin effect can be effectively removed. The production efficiency can be improved and the cost can be reduced.

Abstract: The present invention discloses a surface feed-in electrode structure for thin film solar cell deposition, relating to solar cell technologies. The surface feed-in electrode structure uses a signal feed-in component with a flat waist and a semicircular feed-in end to connect the signal feed-in port by surface contact. The signal feed-in port is located in a hallowed circular area of a center of the backside of a cathode plate, and feeds in an RF/VHF power supply signal. An anode plate is grounded. The cathode plate is insulated with a shielding cover, and a through-hole is configured on the shielding cover. The effects include that, by using the surface feed-in at the center of the electrode plate, the feeding line loss of single-point or multi-point feed-in configurations can be overcome. Uniform large area and stable discharge driven by the RF/VHF power supply signal can be achieved, and the standing wave and the skin effect can be effectively removed.

Abstract: A clamping unit for depositing a thin film solar cell and a signal feed-in method are provided. The clamping unit comprises an electrode plate module, a signal feed-in module (201), and a supporting frame. The electrode plate module is set with a shielding cover (204). The signal feed-in module (201) comprises a waist section and a head section, wherein the head section is a rectangular-shaped signal feed-in surface. The head section of the signal feed-in module (201) is surface contacted with and is connected to the feed-in port of the electrode plate module. The feed-in port is set on the concave rectangular surface which is arranged in the central region of the back side of the cathode plate of the electrode plate module. The clamping unit can effectively remove standing wave effect and skin effect, improve the yields and reduce the costs.

Abstract: A movable deposition box (02) for silicon-based thin film solar cell comprises an electrode array composed of at least a group of cathode plates (203) and a piece of anode plate (208) which are set in movable chamber, wherein a feeding socket (203-1) is positioned on a circular or semicircular concave surface in the center area on the backside of the cathode plates (203), a circular or semicircular end face (201-1) of a feeding component (201) which has a flat middle part contacts the signal feeding socket (203-1) and feeds in RF/VHF power signal, the anode plate (208) is grounded, and a shield cover (204) of the cathode plate has through-hole (204-1) and is insulated from the cathode plate (203).

Abstract: A movable jig for a silicon-based thin film solar cell comprises parallel electrode plates (203,208), a supporting frame and a signal feed-in assembly (201). The supporting frame is a movable frame and its side frame (216) is grounded. A shield device is set on the jig or among jig arrays themselves for preventing from being disturbed. The signal feed-in assembly is a conductor and its middle portion and head portion form a ladder cylinder, and one end surface (201-1) of the signal feed-in assembly is triangular and can surface contact and connect with a sunken triangular feed-in port (203-1) in the center area of the back surface of the cathode plate (203) of the electrode plates, so the radio frequency/the very high frequency power supply signal can be fed in.

Abstract: A clamping unit for depositing a thin film solar cell and a signal feed-in method are provided. The clamping unit comprises an electrode plate module, a signal feed-in module (201), and a supporting frame. The electrode plate module is set with a shielding cover (204). The signal feed-in module (201) comprises a waist section and a head section, wherein the head section is a rectangular-shaped signal feed-in surface. The head section of the signal feed-in module (201) is surface contacted with and is connected to the feed-in port of the electrode plate module. The feed-in port is set on the concave rectangular surface which is arranged in the central region of the back side of the cathode plate of the electrode plate module. The clamping unit can effectively remove standing wave effect and skin effect, improve the yields and reduce the costs.

Abstract: A movable jig for a silicon-based thin film solar cell comprises parallel electrode plates (203,208), a supporting frame and a signal feed-in assembly (201). The supporting frame is a movable frame and its side frame (216) is grounded. A shield device is set on the jig or among jig arrays themselves for preventing from being disturbed. The signal feed-in assembly is a conductor and its middle portion and head portion form a ladder cylinder, and one end surface (201-1) of the signal feed-in assembly is triangular and can surface contact and connect with a sunken triangular feed-in port (203-1) in the center area of the back surface of the cathode plate (203) of the electrode plates, so the radio frequency/the very high frequency power supply signal can be fed in.

Abstract: A movable deposition box (02) for silicon-based thin film solar cell comprises an electrode array composed of at least a group of cathode plates (203) and a piece of anode plate (208) which are set in movable chamber, wherein a feeding socket (203-1) is positioned on a circular or semicircular concave surface in the center area on the backside of the cathode plates (203), a circular or semicircular end face (201-1) of a feeding component (201) which has a flat middle part contacts the signal feeding socket (203-1) and feeds in RF/VHF power signal, the anode plate (208) is grounded, and a shield cover (204) of the cathode plate has through-hole (204-1) and is insulated from the cathode plate (203).

Abstract: An image with a desired contrast is obtained while suppressing body motion artifacts caused by both random motion and periodic motion of an object. In order to do so, an imaging sequence using a non-Cartesian sampling method is executed so as to synchronize with a biological signal only at the start time and a repetition time (TR), which is an execution interval between shots within the imaging sequence, is maintained. In addition, a time difference between a delay time and a start time of each shot is calculated, and a shot with a predetermined time difference or more is executed again after the TR time.