Method of joining and sealing a vanadium based membrane to a metallic connection section

The invention claimed is: 1. A method of joining and sealing a vanadium based membrane to a metallic connection section comprising: mounting a section of a vanadium based membrane on a connector formation of a connection section, the connection section being formed of a different metal to the vanadium based membrane, the connector formation providing a recess into which a section of the vanadium based membrane is seated and a connection interface in which the end face of the vanadium based membrane is proximate to or substantially abuts an adjoining face of the connector formation; mounting and operating a chiller arrangement in thermal contact with the vanadium based membrane proximate the connection interface; heating a filler metal on the connection section in a brazing process so as to form a bridging section of filler metal between the vanadium based membrane and the connection section over the connection interface, without melting the connection section and the vanadium based membrane, the filler metal being selected from at least one of aluminum-silicon, copper, copper alloy, gold-silver alloy, nickel alloy or silver and the filler metal being heated to at least the liquidus temperature of the filler metal using a laser beam directed onto the filler metal located on the connection section and having a beam edge positioned at an offset location spaced apart from the connection interface at a distance so as to attenuate direct heating of the vanadium based membrane by the laser beam during the brazing process, and on the connection section, such that the filler metal can flow over the connection interface from the offset location onto the un-melted vanadium based membrane, the chiller arrangement operating during the brazing process to cool the vanadium based membrane; and cooling the filler metal to form the bridging section of filler metal between the un-melted vanadium based membrane and the un-melted connection section over the connection interface, and wherein use of the chiller arrangement together with the beam edge being positioned at an offset location spaced apart from the connection interface permits the un-melted vanadium based membrane to have an average grain size proximate to the bridging section that is substantially the same as the average grain size of the vanadium based membrane. 2. A method according to claim 1 , wherein the beam edge is spaced apart at least 0.1 mm offset from the connection interface. 3. A method according to claim 1 , wherein: the connection section is comprised of at least one of: steel, stainless steel, nickel-chromium-iron alloys or a combination thereof; the filler metal comprises at least one of aluminum-silicon, copper, copper alloy, gold-silver alloy, nickel alloy or silver; and the vanadium based membrane comprises a vanadium alloy comprising: vanadium; aluminum having a content of greater than 0 to 10 at %; and Ta content of less than 0.01 at %, having a ductility of greater than 10% elongation. 4. A method according to claim 1 , wherein: the vanadium based membrane has a thickness of from 0.1 to 1 mm; and the connection section has a thickness of from 1 to 5 mm. 5. A method according to claim 1 , wherein the laser beam heats the filler metal to a temperature of the liquidus temperature of the filler metal plus at least 5° C. 6. A method according to claim 1 , wherein the laser beam has a beam width of between 0.4 and 1.5 mm. 7. A method according to claim 1 , wherein the ratio of the distance of the offset location spaced apart from the connection interface to a beam width is from 0.1 to 0.5. 8. A method according to claim 1 , wherein the chiller arrangement comprises a conductive body in contact with an outside section of the vanadium based membrane proximate the connection interface. 9. A method according to claim 1 , wherein the chiller arrangement prevents the vanadium based membrane from reaching a peak temperature of no greater than 800° C. 10. A method according to claim 1 , wherein the step of cooling the filler metal comprises allowing the filler metal to cool via convective cooling and/or conductive cooling through operative association with the chiller arrangement. 11. A method according to claim 1 , wherein the bridging section of filler metal comprises a body having a center at the offset location and extending over the connection interface by at least 0.3 mm. 12. A laser brazing arrangement for joining and sealing a vanadium based membrane to a metallic connection section comprising: a vanadium based membrane mounted on a connector formation of a connection section, the connection section being formed of a different metal to the vanadium based membrane, the connector formation providing a recess into which a section of the vanadium based membrane is seated and a connection interface in which the end face of the vanadium based membrane is proximate to or substantially abuts an adjoining face of the connector formation; a laser welding arrangement including a laser beam which in use is directed at the connection section and has a beam edge positioned on the connection section, at an offset location spaced apart from the connection interface at a distance that attenuates direct heating of the vanadium based membrane by the laser beam; a filler metal feeder configured to feed a filler metal selected from at least one of aluminum-silicon, copper, copper alloy, gold-silver alloy, nickel alloy or silver and the filler metal feeder feeds the filler metal under the laser beam at the offset location on the connection section such that in use the filler metal is melted by the laser beam in a brazing process, without melting the connection section and the vanadium based membrane, such that the filler metal can flow over the connection interface from the offset location onto the un-melted vanadium based membrane; and a chiller arrangement in thermal contact with vanadium based membrane proximate the connection interface configured to cool the vanadium based membrane during operation of the laser welding arrangement in the brazing process, wherein the chiller arrangement is configured to cool the filler metal during the brazing process to form a bridging section of filler metal between the un-melted vanadium based membrane and the un-melted connection section over the connection interface, wherein operation of the chiller arrangement together with the beam edge being positioned at an offset location spaced apart from the connection interface is configured to permit the un-melted vanadium based membrane to have an average grain size proximate to the bridging section that is substantially the same as the average grain size of the vanadium based membrane.