RU2021130633A - SOLAR PANEL MODULE - Google Patents

Claims (93)

1. A solar panel module comprising a flexible printed circuit board, a matrix structure of at least twelve solar cells located on the flexible printed circuit board, a cover glass extending over the entire matrix structure, and a flat surface support panel to which the flexible printed circuit board is attached , and: the flexible printed circuit board comprises a copper circuit layer located between at least two polyimide layers, the flexible printed circuit board has an upper side with an upper surface and a lower side with a lower surface, the flexible printed circuit board also has a solar cell installation area and an elongated section of the connecting printed conductor, extending from the solar cell installation site, wherein the upper side of the solar cell installation site has a base level section with a base level surface and an elevated support section with a raised surface, wherein the copper circuit layer forms a circuit with electrical pads on the base level surface of the upper side of the solar installation section elements for connection with solar cells and with conductors along the elongated section of the connecting printed conductor; the solar cell matrix structure is adhesively attached to the top surface of the flexible printed circuit board, each solar cell has an upper side for receiving solar energy, as well as a back side and a back side connector that is operatively connected to the circuit by a conductive adhesive extending between the electrical terminals. pads of the flexible circuit board solar cell installation area and the rear side of each respective solar cell, each solar cell having a respective return diode disposed on the flexible circuit board and operatively connected to the corresponding solar cell via the flexible circuit board circuit; one or more blocking diodes are operatively connected to the circuit on an elongated section of the connecting printed conductor; wherein the solar cell installation area of the flexible printed circuit board is permanently attached to the flat surface of the support panel, and the cover glass is permanently attached to the matrix structure of the solar cells. 2. The solar cell panel module of claim 1, wherein the adhesive attachment of each of the solar cell panels to the flexible circuit board is performed solely by the conductive adhesive. 3. The solar cell panel module of claim 1, wherein the adhesive attachment of each of the solar cell panels to the flexible circuit board is via a conductive adhesive and a non-conductive adhesive. 4. The solar cell panel module of claim 1, wherein the support panel is part of a busbar assembly and the bonding conductor extension extends through or around the bus assembly and has a bonding region at the end of the bonding conductor extension that is operatively attached to the busbar assembly. bus node. 5. The solar panel module of claim 4, wherein the back side connector is a surface mount adapter attached to the front side of the solar cell and extends around to the back side at the periphery of the solar cell. 6. The solar cell module of claim 1, wherein each return diode is integrated with the flexible circuit board, the diode having a flat rectangular shape and permanently attached to an electrical pad on the top side of the flexible circuit board. 7. The solar cell module of claim 6, wherein each return diode has a height, permanently attached to the base level surface, and extends a height above the base level surface, and said height is less than or equal to the height of the raised surface of the raised leg portion from base level surfaces. 8. The solar cell panel module of claim 6, wherein the support panel is part of the structural outer wall of the spacecraft. 9. The solar cell module of claim 1, wherein there are a plurality of blocking diodes arranged in a cluster proximate the connector end of the elongate portion of the interconnecting printed conductor. 10. A solar panel module comprising a flexible printed circuit board, a matrix structure of a plurality of solar cells located on the flexible printed circuit board, a cover glass extending over the matrix structure, and a flat surface rigid support panel to which the flexible printed circuit is permanently attached. board, wherein the flexible printed circuit board has a conductive layer located between at least two layers of polyimide, and the conductive layer contains copper and forms a circuit, while the flexible printed circuit board has an upper side with an upper surface and a lower side with a lower surface, the flexible printed circuit board has also the solar cell installation section and the connecting printed conductor elongate section extending from the solar cell installation section, the circuit has electrical contact pads on the upper surface of the upper side of the solar cell installation section, electrically connected to the solar cells, and conductors extending along the connecting printed conductor elongated section , wherein: the matrix structures of the solar cells are adhesively attached to the upper surface of the flexible printed circuit board; each solar cell has an upper side for receiving solar energy and a back side with a rear side connection terminal that is electrically and functionally connected, each of the solar cells is electrically connected to the circuit by a conductive adhesive extending between the exposed electrical contact pads of the solar installation section. flex circuit board elements and the back side of each respective solar cell; the cover slip passes over and covers the matrix structure of at least twelve solar cells, the cover slip having a flat inner surface, wherein one or more blocking diodes are operatively connected to the circuit. 11. The solar cell module of claim 10, wherein the top side of the solar cell installation portion has a base level portion with a base level surface and a plurality of elevated support portions with a raised surface, and the solar cell module comprises a respective return diode for each of the plurality of solar cells and the associated return diodes are mounted on top of the flexible circuit board and do not extend upwards beyond the raised surfaces of the support portions. 12. The solar cell panel module of claim 11, wherein each of the solar cell panels is mounted on raised support surfaces. 13. The solar panel module of claim 10, wherein the circuit connects a plurality of solar cells in series. 14. The solar cell module of claim 13, wherein each of the plurality of solar cells has a respective return diode operatively coupled to a respective solar cell. 15. A solar panel module comprising a flexible printed circuit board, a matrix structure of at least twelve solar cells located on a flexible printed circuit board, a cover glass passing over the matrix structure, and a rigid support panel with a flat surface, moreover: the flexible printed circuit board comprises a circuit layer located between at least two polymer layers, wherein the circuit layer contains copper, the flexible printed circuit board has an upper side with an upper surface and a lower side with a lower surface, the flexible printed circuit board has a solar cell installation area and an elongated a connection printed conductor section extending from the solar cell installation section, the copper circuit layer forming a circuit with exposed electrical pads on the base level surface of the upper side of the solar cell installation section for connection with solar cells and conductors extending along the elongated section of the connecting printed conductor; the matrix structures of the solar cells are adhesively attached to the upper surface of the flexible printed circuit board; each solar cell has an upper side for receiving solar energy, a back side and a connector located on it, which is made with the possibility of electrical and functional connection, and each of the solar cells is electrically connected to the circuit on electrical pads, each solar cell has a return diode integrated with the top side of the flexible circuit board and operatively connected to the respective solar cell; the cover slip passes over and covers the matrix structure of at least twelve solar cells. 16. The solar panel module of claim 15, further comprising one or more blocking diodes operatively coupled to the circuit. 17. A flexible printed circuit board for mounting on a panel and receiving a plurality of solar cells, wherein the flexible printed circuit board includes a copper circuit layer located between at least two polyimide layers, the flexible printed circuit board also has an upper side with an upper surface and a lower side with a lower surface , the flexible printed circuit board also has a solar cell mounting portion and an elongated connection printed conductor portion extending from the solar cell mounting portion, wherein the copper circuit layer forms a circuit with a plurality of open electrical pads on the base level surface of the upper side of the solar cell mounting portion for connection with solar cells and conductors along the elongated section of the connecting printed conductor; the solar cell installation portion of the flexible circuit board is integrally attached to the flat surface of the support panel; And a conductive adhesive is located on each of the plurality of electrical pads. 18. A method for manufacturing a solar cell panel module, including: a) receiving or providing a flexible printed circuit board made of thin layers of insulating polymeric material with a conductive layer located between them, and the flexible printed circuit board has a solar cell attachment area and a connecting printed conductor section extending from it, while the solar cell attachment area has a side solar cell mounting surface with a solar cell mounting surface having a plurality of mounting areas for a plurality of solar cells, said conductive layer forms a circuit with a plurality of contact pads on the solar cell mounting side so that the flexible printed circuit board has alignment areas on it, while the flexible printed circuit board comprises a plurality of raised landing sites for mounting each of the solar cells; b) receiving or providing a matrix tray with a plurality of pockets loaded with a plurality of solar cells, on which alignment areas are located, the pockets corresponding to the plurality of attachment areas of the solar cell attachment surface; c) positioning and aligning the flexible circuit board on the carrier, wherein the carrier has alignment areas corresponding to the alignment areas of the matrix tray and the alignment areas of the flexible circuit board; d) issuing a plurality of drops of a conductive adhesive to a plurality of pads on the mounting side of the solar cells; e) aligning and interfacing the matrix tray with the plurality of solar cells with the flexible printed circuit board on the carrier using appropriate alignment portions, whereby the plurality of solar cells interact with the plurality of droplets, and thus the functional connection of each of the plurality of solar cells with the scheme and installation of each of the solar cells on the corresponding sections of the flexible printed circuit board; f) separating the matrix tray from the plurality of solar cells; g) separating the carrier from the flexible circuit board; h) positioning and permanently attaching the rear side of the flexible printed circuit board to the flat surface of the front side of the rigid support panel; i) pulling a portion of the connecting printed conductor back from the front side of the rigid support panel; And j) selection of return diodes so that their height, when mounted on a flexible printed circuit board, does not exceed the height of the raised footprints. 19. The method of claim 18, further comprising robotically performing steps c-h. 20. The method of claim 18, further comprising robotic execution of any steps a-j. 21. The method of claim 19, further comprising robotically attaching a plurality of one or more blocking diodes to the elongated portion of the connecting printed conductor. 22. The method of claim 18, wherein the height of each of the raised landing portions is about 0.012 inches. 23. The method of claim 18, wherein the height of the return diodes is 0.008 inches or less. 24. The method of claim 23, further comprising dispensing conductive adhesive droplets that are higher than the height of the raised landing portions. 25. The method according to any one of paragraphs. 20-24, further comprising attaching a plurality of return diodes to the solar cell mounting surface of the flexible printed circuit board. 26. The method of claim 25, wherein the height of each of the return diodes is less than the height of the raised surface. 27. The method according to any one of paragraphs. 20-24, wherein receiving or providing a flexible circuit board includes receiving a flexible circuit board with a plurality of return diodes attached to a solar cell attachment side for each of the solar cells. 28. The method according to any one of paragraphs. 20-24 further comprising dispensing a non-conductive adhesive onto the solar cell mounting surface. 29. The method according to any one of paragraphs. 20-28, further comprising placing a single cover slip over each of the plurality of solar cells. 30. The method of claim 28, further comprising robotic dispensing of the non-conductive adhesive. 31. The method of claim 29, further comprising robotic placement of a coverslip. 32. A method for manufacturing a solar cell panel module, including: a) receiving or providing a flexible printed circuit board on a carrier having a plurality of alignment areas, wherein the flexible carrier is made of thin layers of insulating polymeric material with a conductive layer disposed therebetween, the flexible printed circuit board having a solar cell attachment portion and a connecting printed circuit portion extending therefrom. of the conductor, wherein the solar cell attachment portion has a solar cell attachment side with a solar cell attachment surface having a plurality of attachment areas for a plurality of solar cells, wherein the solar cell attachment surface is on top of the raised support portion and separated from the base level portion of the solar cell attachment portion, wherein therein, the conductive layer forms a circuit with a plurality of pads on the solar cell mounting side, and the flexible printed circuit board is disposed on a carrier which has alignment portions; b) receiving or providing a matrix tray with a plurality of solar cell pockets loaded with a plurality of solar cells, on which alignment areas are located, the pockets corresponding to a plurality of attachment areas of the solar cell attachment surface of the flexible printed circuit board; c) robotically dispensing a plurality of conductive adhesive drops onto a plurality of contact pads on the mounting side of the solar cells; e) robotically interfacing a matrix tray with a plurality of solar cells with a flexible printed circuit board on a carrier using appropriate alignment areas, resulting in a plurality of solar cells interacting with a plurality of droplets, and thus a functional connection of a plurality of solar cells with a circuit is provided; f) separating the matrix tray from the plurality of solar cells; g) separating the carrier from the flexible circuit board; h) positioning and permanently attaching the rear side of the flexible printed circuit board to the flat surface of the front side of the rigid support panel; And i) pulling a section of the connecting printed conductor back from the front side of the rigid support panel. 33. The method of claim 32, further comprising robotically performing steps c-h. 34. The method of claim 32, further comprising robotically performing any steps a-i. 35. A method for manufacturing a solar cell panel module, including: receiving or providing a flexible printed circuit board made of thin layers of an insulating polymeric material with a conductive layer located between them, wherein the flexible printed circuit board has a solar cell attachment section and a connecting printed conductor section extending from it, wherein the solar cell attachment section has a solar cell attachment side with a solar cell attachment surface having a plurality of attachment areas for a plurality of solar cells, the conductive layer forms a plurality pad pattern on the solar cell attachment side; receiving or providing a matrix tray with at least twelve solar cell pockets loaded with at least twelve solar cells, on which alignment areas are located, the pockets corresponding to a plurality of attachment areas of the solar cell attachment surface; placing a flexible printed circuit board on the media, and the media has areas of alignment corresponding to areas of alignment of the matrix tray; dispensing a plurality of pieces of solder to a plurality of pads on the solar cell attachment side; interacting the matrix tray with a plurality of solar cells with a flexible printed circuit board on a carrier using appropriate alignment sections, resulting in a plurality of solar cells interacting with a plurality of solder parts; heating the flexible printed circuit board and the solar cells, and thereby melting the solder portions and functionally connecting the plurality of solar cells to the circuit, the solder portions creating an electrical connection extending between the exposed pads of the solar cell mounting side and the rear side of each of the solar cells; separating the matrix tray from the plurality of solar cells; separating the carrier from the flexible printed circuit board; positioning and permanently attaching the rear side of the flexible printed circuit board to a flat surface of the front side of the rigid support panel; And pulling a section of the connecting printed conductor back from the front side of the support panel. 36. The method of claim 35, wherein at least one of the processes is performed in a robotic manner. 37. Solar panel module comprising a flexible printed circuit board, a matrix structure of at least twelve solar cells located on the flexible printed circuit board, a cover glass extending over the entire matrix structure, and a flat surface support panel to which the flexible printed circuit board is attached , and: the flexible printed circuit board comprises a copper circuit layer located between at least two polyimide layers, wherein one of the at least two layers defines the uppermost polyimide layer, while the flexible printed circuit board has an upper side with an upper surface and a lower side with a lower surface, the flexible printed circuit board also has a solar cell mounting portion and an elongated printed lead portion extending from the solar cell mounting portion, wherein the top side of the solar cell mounting portion is at least partially defined by an uppermost polyimide layer that is a base layer with a base layer surface and one or more raised polyimide poles protruding from and integral with the topmost polyimide layer, wherein the one or more raised poles have a raised solar cell landing surface, and the copper circuit layer is located below the topmost polyimide layer and forms a circuit whose copper layer extends through the topmost polyimide layer defining the electrical pads on the base layer surface, which are separated and spaced from the raised supports on the base layer surface, which extends between the raised supports and the electrical pads for connection to the solar cells and conductors running along the elongated section of the connection printed conductor; the solar cell matrix structure is adhesively attached to the upper surface of the flexible printed circuit board; each solar cell has a solar receiving top side and a back side, as well as a back side connector that is operably connected to the circuit by a conductive adhesive placed between the electrical pads of the flexible circuit board solar cell installation area and the back side of each respective solar a cell, each solar cell having a respective return diode positioned on the flexible printed circuit board and operatively connected to the respective solar cell via the flexible printed circuit board circuitry; with the circuit on the elongated section of the connecting printed conductor, one or more blocking diodes are operatively connected; the solar cell installation section of the flexible printed circuit board is permanently attached to the flat surface of the support panel, and the cover glass is permanently attached to the solar cell matrix structure. 38. The solar cell panel module of claim 37, wherein the adhesive bonding of each of the solar cell panels to the flexible circuit board is performed solely by a conductive adhesive. 39. The solar cell panel module of claim 37, wherein the adhesive attachment of each of the solar cell panels to the flexible circuit board is by a conductive adhesive and a non-conductive adhesive. 40. The solar cell panel module of claim 37, wherein the support panel is part of a busbar assembly, wherein the connecting printed conductor elongate portion extends through or around the busbar assembly and has a connector portion at the end of the interconnecting printed conductor elongate portion that is functionally attached to the busbar node. 41. The solar cell module of claim 40, wherein the back side connector is a surface mount adapter attached to the front side of the solar cell and extends around to the back side at the periphery of the solar cell. 42. The solar cell module of claim 37, wherein each return diode is integrated with the flexible circuit board, the diode having a flat rectangular shape and permanently attached to an electrical pad on the top side of the flexible circuit board. 43. The solar cell module of claim 42, wherein each return diode has a height and is permanently attached to the base level surface, rising above it to a height that is less than or equal to the height of the raised surface of the raised support above the base level surface. 44. The solar cell panel module of claim 42, wherein the support panel is part of the structural outer wall of the spacecraft. 45. The solar cell module of claim 37, wherein a plurality of blocking diodes are provided that are arranged in a cluster proximate the connector end of the elongate portion of the connecting printed conductor. 46. The solar cell panel module of claim 37, wherein at least twelve solar cells are seated on one or more raised supports on respective raised surfaces. 47. The solar cell panel module of claim 46, wherein the one or more raised supports extend from one of the at least two polyimide layers. 48. A flexible printed circuit board for panel mounting and receiving a plurality of solar cells, the flexible printed circuit board comprising a copper circuit layer sandwiched between at least two polyimide layers including an uppermost polyimide layer, the flexible printed circuit board having an upper side with an upper surface and a lower side with a lower surface, and also has a solar cell installation area, wherein the copper circuit layer contains a copper layer passing through the uppermost polyimide layer and forming a plurality of open electrical pads on the base layer surface defined on the upper surface of the uppermost polyimide layer of the upper side of the solar cell installation area, wherein the electrical pads serve for electrical connection with the solar cells, and the base level surface faces upward and is in the plane of the electrical pads, while the solar cell installation area further has a plurality of solar cells for landing a plurality of polyimide supports protruding upwardly from the polyimide layer and integral with the topmost polyimide layer, wherein the plurality of supports form a gap between the landing position of the plurality of solar cells and the base level surface, and each of the electrical pads is exposed on the upwardly facing base level surface so that the upward facing surface of the base level extends transversely to each of the electrical pads.