초록 ▼

In a flat panel solar collector adapted to be evacuable and vacuum-tight, at least one absorber is provided. At least one conduit is provided which is at least partially thermally associated with the at least one absorber. A holding structure is provided comprising a perimetric frame. At least one f

In a flat panel solar collector adapted to be evacuable and vacuum-tight, at least one absorber is provided. At least one conduit is provided which is at least partially thermally associated with the at least one absorber. A holding structure is provided comprising a perimetric frame. At least one first transparent wall is provided, the first transparent wall and the holding structure having a overlapping area. At least one side of the first transparent wall comprises at least partially at said overlapping area a metal coating forming at least one metallized area on the transparent wall. A first soft metal ribbon is provided sealing the junction between the first transparent wall and the holding structure and which is soldered to the holding structure and to the metallized area of the first transparent wall.

대표청구항 ▼

I claim: 1. A flat panel solar collector adapted to be evacuable and vacuum-tight, comprising: at least one absorber; at least one conduit which is at least partially thermally associated with said at least one absorber; a holding structure comprising a perimetric frame; at least one first transpar

I claim: 1. A flat panel solar collector adapted to be evacuable and vacuum-tight, comprising: at least one absorber; at least one conduit which is at least partially thermally associated with said at least one absorber; a holding structure comprising a perimetric frame; at least one first transparent wall; the first transparent wall and the holding structure having a substantially flat overlapping area, the holding structure overlapping area comprising a metal; at least one side of the first transparent wall comprising at least partially at said overlapping area a metal coating comprising a copper layer and tin cover layer forming at least one metalized area on the transparent wall at an edge of the wall; and a first soft metal ribbon sealing a junction between the first transparent wall and the holding structure, said metal ribbon comprising at least one of the elements selected from the group consisting of copper and lead, and which is soldered to the holding structure overlapping area comprising said metal with a first soft soldered portion at an inside edge of the ribbon and to the metalized area of the first transparent wall at an opposite outside edge of the ribbon with a second soft soldered portion at said edge of the transparent wall. 2. A flat panel solar collector according to claim 1 further comprising a bottom part attached to the holding structure to form a housing which is vacuum-tight. 3. A flat panel solar collector according to claim 1 further comprising at least one second transparent wall spaced apart from the first transparent wall by the holding structure and wherein the second transparent wall and the frame have an overlapping area, wherein at least one side of the second transparent wall comprises at least partially at the overlapping area a metal coating providing at least one metalized area on the second transparent wall; and a second, soft metal ribbon sealing a junction between the second transparent wall and the holding structure, and which is soldered to the holding structure and to the metallized area of the second transparent wall. 4. A flat panel solar collector according to claim 1 wherein said first soft metal ribbon is at least partially aligned substantially parallel to the holding structure. 5. A flat panel solar collector according to claim 1 wherein the holding structure further comprises at least one spacer. 6. A flat panel solar collector according to claim 1 further comprising at least one shielding plate interposed between the absorber and a bottom part attached to the holding structure. 7. A flat panel solar collector according to claim 1 wherein a distance between a bottom part attached to the holding structure and the first transparent wall is about 1 to 10 cm. 8. A flat panel solar collector according to claim 1 wherein the holding structure comprises copper, steel, or aluminum and is coated with a low infrared absorbtivity film. 9. A flat panel solar collector according to claim 1 wherein a material used for the holding structure is resistant to corrosion. 10. A flat panel solar collector according to claim 1 further comprising at least one getter on at least part of the absorber or the holding structure. 11. A flat panel solar collector according to claim 1 further comprising an infrared mirror coating on an internal side of the first transparent wall. 12. A flat panel solar collector according to claim 1 wherein the conduit comprises a vacuum-tight connecting port integrated into the perimetric frame. 13. A flat panel solar collector according to claim 1 further comprising at least one connecting port in the form of a pumping port incorporated into the perimetric frame of the holding structure. 14. A flat panel solar collector according to claim 1 wherein the holding structure frame comprises a lateral wall and a supporting surface connected to said lateral wall adapted to carry the first transparent wall. 15. A flat panel solar collector according to claim 14 wherein at least one first portion of said soft metal ribbon is soldered to the supporting surface of the frame, and wherein a second portion of the soft metal ribbon is soldered to the first transparent wall. 16. A flat panel solar collector according to claim 1 wherein the absorber comprises at least one copper plate coated with a selective absorber film at least on a side which is subjectable to solar radiation. 17. A flat panel solar collector according to claim 1 wherein the conduit is thermally attached to the at least one absorber and the conduit is arranged to not be in direct thermal contact with the holding structure. 18. A flat panel solar collector system, comprising: at least one flat panel solar collector adapted to be evacuable and vacuum-tight, said solar collector comprising at least one absorber; at least one conduit which is at least partially thermally associated with said at least one absorber; a holding structure comprising a perimetric frame; at least one first transparent wall; the first transparent wall and the holding structure having a substantially flat overlapping area, the holding structure overlapping area comprising a metal; at least one side of the first transparent wall comprising at least partially at said overlapping area a metal coating comprising a copper layer and tin cover layer forming at least one metallized area on the transparent wall; and a first soft metal ribbon sealing a junction between a first transparent wall and the holding structure, said metal ribbon comprising at least one of the elements selected from the group consisting of copper and lead, and which is soldered to the holding structure overlapping area comprising said metal with a first soft soldered portion at one inside edge of the ribbon and to the metallized area of the first transparent wall at an opposite outside edge of the ribbon with a second soft soldered portion at said edge of the transparent wall; and at least one mirror positioned to reflect light onto said at least one first transparent wall of said flat panel solar collector. 19. A flat panel solar collector system according to claim 18 wherein said solar collector is substantially aligned along an axis of a half-cylindrical mirror. 20. A flat panel solar collector system according to claim 18 wherein a cross-section of the mirror exhibits a shape of at least a portion of a circular arc. 21. A flat panel solar collector system according to claim 18 wherein the solar collector is located above two adjacent mirrors a cross-section of which exhibits a shape of at least a portion of a circular arc. 22. A flat panel solar collector system according to claim 18 wherein at least two of said flat panel solar collectors are provided and said mirror reflecting light onto said at least two flat panel solar collectors at the respective first transparent wall of each. 23. A method for preparation of a flat panel solar collector, comprising the steps of: providing at least one holding structure comprising a perimetric frame with connection ports, said holding structure having a substantially flat overlapping area comprising a metal, at least one absorber, at least one conduit, at least one first transparent wall, at least one bottom part or at least one second transparent wall, and a metal coating comprising a copper layer and tin cover layer on a side of and at a periphery edge of the first transparent wall; providing a soft metal ribbon soldered to said metal coating with a second soft soldered portion at an outside edge of the ribbon at said periphery edge, said metal ribbon comprising at least one of the elements selected from the group consisting of lead and copper; providing a getter; fitting a spacer into the perimetric frame; fitting at least one conduit in thermally associated fashion to the at least one absorber, and into the connection ports of the perimetric frame; connecting ends of the conduit to the connecting ports; fitting the first transparent wall onto the holding structure; soldering said soft metal ribbon to the holding structure overlapping area comprising said metal with a first soft soldered portion at an opposite inside edge of said soft metal ribbon; evacuating the solar panel by use of at least one external pump; and heating the flat panel solar collector for a period of time to provide a sufficient outgassing of the collector and heating the flat panel solar collector in order to activate the getter. 24. A method according to claim 23 further comprising the step of fitting the bottom part to the holding structure in a vacuum-tight manner before evacuating the solar panel. 25. A method according to claim 23 further comprising the step of providing the second transparent wall with a metal coating at one side and at a periphery thereof, and providing a soft metal ribbon soldered to said metal coating, and fitting the second transparent wall onto the holding structure, and soldering said soft metal ribbon to the holding structure. 26. A method according to claim 23 wherein the flat panel solar collector is heated from about 120° C. to about 170° C. to provide said sufficient outgassing of the collector. 27. A method according to claim 23 including the step of heating said flat panel solar collector to a temperature of about 170° C. in order to activate the getter. 28. A flat panel solar collector adapted to be evacuable and vacuum-tight, comprising: at least one absorber; at least one conduit which is at least partially thermally associated with said at least one absorber; a holding structure; at least one transparent wall; the transparent wall and the holding structure having a substantially flat overlapping area, said holding structure overlapping area comprising a metal; a side of the first transparent wall comprising at least partially at said overlapping area a metallized area comprising a plasma spread copper layer and tin cover layer on the transparent wall at an edge of the wall; a metal ribbon sealing a junction between the first transparent wall and the holding structure by soft soldering with a second soft soldered portion at an outside edge of the ribbon to said transparent wall metalized area and to said holding structure overlapping area comprising said metal with a first soft soldered portion at an opposite inside edge of said ribbon, said ribbon comprising at least one of the elements selected from the group consisting of lead and copper; and a wall on said holding structure opposite the transparent wall. 29. A method for preparation of a flat panel solar collector, comprising the steps of: providing at least one holding structure having a substantially flat overlapping area comprising a metal, at least one absorber, at least one conduit, at least one top transparent wall, at least one bottom wall, and a metal coating comprising a plasma spread copper layer and tin cover layer at least at a portion of a periphery edge of the transparent wall; providing a metal ribbon soldered to said metal coating with a second soft soldered portion at an outside edge of the ribbon at said periphery edge of the wall, said metal ribbon comprising at least one of the elements selected from the group consisting of lead and copper; providing a getter; fitting at least one conduit in thermally associated fashion to the at least one absorber, and into connection ports in the holding structure; connecting ends of the conduit to the connecting ports; fitting the transparent wall and bottom wall onto the holding structure; soldering said metal ribbon to the holding structure overlapping area comprising said metal with a first soft soldered portion at an opposite inside edge of said soft metal ribbon; evacuating the solar panel by use of at least one external pump; and heating the flat panel solar collector for a period of time to provide a sufficient outgassing of the collector and heating the flat panel solar collector in order to activate the getter.