Shape-adapted electrochemical storage device for uniform temperature distribution

The invention claimed is: 1. An electrochemical storage device, comprising: when in ordinary operation, an anode compartment filled with an anode material and a cathode compartment filled with a cathode material, wherein the anode compartment is separated from the cathode compartment by an ion-conductive solid electrolyte, and wherein the anode compartment is delimited on one side at least in part by the solid electrolyte and on another side at least in part by a wall which surrounds the solid electrolyte at least in part, wherein the electrochemical storage device has a top part, at which electrical energy may be fed in or out, a bottom part arranged opposite the top part, and at least one side part which comprises the at least one wall and is arranged between the top part and bottom part, wherein there are provided between the wall and solid electrolyte at least one first region and one second region, which two regions differ by the respective spacing of the wall from the solid electrolyte, wherein the first region is arranged closer to the bottom part and the second region is arranged closer to the top part and in the second region the wall is spaced further from the solid electrolyte than the wall is spaced from the solid electrolyte in the first region, and in that the first region has a substantially uniform spacing between the wall and the solid electrolyte, wherein the solid electrolyte has a change in shape which separates the first region and the second region from one another and wherein a longitudinal axis of the electrochemical storage device is an axis of symmetry of the solid electrolyte and an axis of symmetry of the wall and wherein the axis of symmetry is an axis of rotational symmetry such that surface symmetry is present in a plane that bisects the axis of rotational symmetry at a right angle. 2. The electrochemical storage device as claimed in claim 1 , wherein a transition from the first region to the second region has a taper of the spacing between the wall and the solid electrolyte. 3. The electrochemical storage device as claimed in claim 1 , wherein the first region and the second region are in each case differently spaced from the top part and the bottom part. 4. The electrochemical storage device as claimed in claim 1 , wherein the second region has a plurality of tapers of the spacing between the wall and the solid electrolyte. 5. The electrochemical storage device as claimed in claim 1 , wherein the wall is comprised of a can which at least in part surrounds the solid electrolyte. 6. The electrochemical storage device as claimed in claim 1 , wherein the wall is spaced from the solid electrolyte in the first region by at most 3 mm. 7. The electrochemical storage device as claimed in claim 1 , wherein the wall is spaced from the solid electrolyte in the second region by on average at least 4 mm. 8. The electrochemical storage device as claimed in claim 1 , wherein a ratio of a spatial volume which is determined by the first region between the wall and solid electrolyte to a spatial volume which is determined by the second region between the wall and solid electrolyte is at most 60%. 9. The electrochemical storage device as claimed in claim 1 , wherein a space which is determined by the first region between the wall and solid electrolyte is completely filled by anode material when the electrochemical storage device is at full charge, wherein a space which is determined by the second region between the wall and solid electrolyte is filled only in part by anode material. 10. The electrochemical storage device as claimed in claim 1 , wherein a space which is determined by the first region between the wall and solid electrolyte is completely filled by anode material at just 60% of a full charge of the electrochemical storage device. 11. The electrochemical storage device as claimed in claim 1 , wherein the wall is spaced from the solid electrolyte in the first region by at most 1.5 mm. 12. The electrochemical storage device as claimed in claim 1 , wherein a ratio of a spatial volume which is determined by the first region between the wall and solid electrolyte to a spatial volume which is determined by the second region between the wall and solid electrolyte is at most 30%. 13. The electrochemical storage device as claimed in claim 1 , wherein the second region extends from the change in shape to the top part. 14. The electrochemical storage device as claimed in claim 1 , wherein the electrode and the one second region extend to the top part of the electrochemical storage device. 15. A method for producing the electrochemical storage device of claim 1 , the method comprising: providing the solid electrolyte which has the change in shape and is also ion-conductive; providing the wall; surrounding the solid electrolyte with the wall such that, on completion of the electrochemical storage device, there are provided between the wall and solid electrolyte the at least one first region of the anode compartment and the second region of the anode compartment, which two regions in each case differ by the spacing of the wall from the solid electrolyte in such a manner that the first region is arranged closer to the bottom part and the second region is arranged closer to the top part and in the second region the wall is spaced further from the solid electrolyte than in the first region, and that the first region has a substantially uniform spacing between the wall and the solid electrolyte.