Johnston coupling with additional vacuum enclosure

The invention claimed is: 1. A plug-in coupling for connecting a first to a second double-walled, vacuum-insulated cryogenic line, each cryogenic line having media-conducting inner pipe wherein the plug-in coupling comprises: a coupling plug and a coupling socket, wherein the coupling plug has an inner and an outer pipe piece and a first connecting flange and is connected to the first cryogenic line, wherein the coupling socket has an inner and an outer pipe piece and a second connecting flange and is connected to the second cryogenic line, wherein between the inner and the outer pipe piece of the coupling socket, there is formed an annular gap which is open in the region of the second connecting flange and which is surrounded both at its inner circumference and at its outer circumference by an insulating vacuum, wherein the outer pipe piece of the coupling socket is welded to the second connecting flange and the end of the outer pipe piece remote from the second connecting flange is connected to one end of the inner pipe piece of the coupling socket in a vacuum-tight manner by means of a connecting ring, wherein the other end of the inner pipe piece of the second connecting flange is welded to a seal holder, wherein the media-carrying inner pipe of the second cryogenic line is welded to the seal holder, and wherein the seal holder bears a seal, which in the assembled state of the plug-in coupling is in contact with the coupling plug and seals the media-carrying inner pipes of the first and second cryogenic lines, respectively. 2. The plug-in coupling according to claim 1 , wherein, when the plug-in coupling has been assembled, the coupling plug has been plugged into the open annular gap. 3. The plug-in coupling according to claim 1 , wherein the outer and the inner pipe piece of the coupling plug are connected in each case by way of a first end to the first connecting flange and by way of the in each case second end to a connecting ring, wherein, between the inner and the outer pipe piece, there is formed an annular gap in which an insulating vacuum prevails. 4. The plug-in coupling according to claim 3 , wherein the annular gap is connected via at least one flow channel to an insulating vacuum in the first cryogenic line. 5. The plug-in coupling according to claim 1 , wherein the second connecting flange is connected to an outer pipe of the second cryogenic line. 6. The plug-in coupling according to claim 1 , wherein the inner pipe piece is connected to the outer pipe piece of the coupling socket by means of a connecting ring. 7. The plug-in coupling according to claim 1 , wherein the coupling socket and the coupling plug have mutually complementary centring means. 8. The plug-in coupling according to claim 1 , wherein the inner pipes of the first and second cryogenic lines are, in the region of the plug-in connection, thermally insulated with respect to the exterior space by three insulating vacuums layered adjacent to one another. 9. A loading facility for cryogenic fluids having a plug-in coupling according to claim 1 .