Differential pressure sensor

The invention claimed is: 1. A differential pressure sensor, comprising: a measuring diaphragm; a first mating body; a second mating body; and at least one capacitive transducer, wherein: said measuring diaphragm comprises an electrically conductive material and is connected to said first mating body and said second mating body in a pressure-tight manner by the formation of a measuring chamber between said first and said second mating bodies, along a circumferential edge; said first mating body and said second mating body comprise an electrically insulating material; the mating bodies each comprise a diaphragm bed which is concave in the center and which can support said measuring diaphragm in case of a unilateral overload; the mating bodies comprise a first and a second pressure channels, which extend from a rear side of the mating bodies facing away from said measuring diaphragm through the mating bodies into the respective measuring chamber; said capacitive transducer comprises at least one mating body electrode, which is formed by a metallic coating on the surface of the mating body facing toward said measuring diaphragm; said mating body electrode can be contacted from the rear side of the mating body by means of a metallic coating of the wall of the pressure chamber; said metallic coating of the surface, which faces the measuring diaphragm, comprises an inner region, which forms the mating body electrode, and an outer region which annularly encloses said inner region and is separated from said inner region by an annular insulation region; and said outer region of said coating is electrically conductively connected to said measuring diaphragm. 2. The differential pressure sensor according to claim 1 , wherein: each of said mating bodies comprises a planar edge region, which encloses said diaphragm bed; said diaphragm bed comprises a convex transition region towards the edge region; and said outer region of said metal coating is arranged at least in part in said convex transition region. 3. The differential pressure sensor according to claim 1 , wherein: said insulation region has a width of no more than 200 μm—in particular, no more than 150 μm, preferably no more than 100 μm, and particularly preferably no more than 80 μm. 4. The differential pressure sensor according to claim 1 , wherein: said inner region of said metallic coating has a larger layer thickness than said outer region of said metallic coating; and said inner region in particular has a thickness that is no less than 1.5 times—preferably, no less than double—the layer thickness of the outer region of the metallic coating. 5. The differential pressure sensor according to claim 1 , wherein: the layer thickness of said inner region of said metal coating is at least 150 nm—preferably, at least 200 nm. 6. The differential pressure sensor according to claim 1 , wherein: said mating bodies comprise glass. 7. The differential pressure sensor according to claim 1 , wherein: said measuring diaphragm is fixed between said outer region of said metallic coating of said first mating body and said outer region of said metallic coating of said second mating body. 8. A differential pressure sensor comprising: a measuring diaphragm; a first mating body; a second mating body; and at least one capacitive transducer, wherein: said measuring diaphragm comprises an electrically conductive material and is connected to said first mating body and said second mating body in a pressure-tight manner by the formation of a measuring chamber between said first and said second mating bodies, along a circumferential edge; said first mating body and said second mating body comprise an electrically insulating material; the mating bodies each comprise a diaphragm bed which is concave in the center and which can support said measuring diaphragm in case of a unilateral overload; the mating bodies comprise a first and a second pressure channels, which extend from a rear side of the mating bodies facing away from said measuring diaphragm through the mating bodies into the respective measuring chamber; said capacitive transducer comprises at least one mating body electrode, which is formed by a metallic coating on the surface of the mating body facing toward said measuring diaphragm; said mating body electrode can be contacted from the rear side of the mating body by means of a metallic coating of the wall of the pressure chamber; said metallic coating of the surface, which faces the measuring diaphragm, comprises an inner region, which forms the mating body electrode, and an outer region which annularly encloses said inner region and is separated from said inner region by an annular insulation region; and said metallic coating comprises at least one metallic adhesion promoter—in particular, chromium—and one metal conductive layer—in particular, copper. 9. The differential pressure sensor according to claim 8 , wherein: said inner region of said metallic coating comprises an additional passivation layer, which comprises nickel, in particular; and said outer region of said metallic coating is terminated by said metallic conductive layer. 10. A method for preparing a mating body for a capacitive differential pressure sensor, wherein the mating body comprises: an electrically insulating material, such as glass, wherein the mating body comprises a diaphragm bed which is concave in the center and which is lowered with respect to a planar region of the mating body, and wherein a pressure channel extends from a rear side of the mating body through the mating body and ends in the area of the diaphragm bed, the method comprises the following steps: preparing a first metallic partial coating, which comprises an inner region, an outer region, and a through-connection, wherein the inner region covers a central region of the diaphragm bed, the outer region annularly encloses the inner region and is separated from the inner region by an annular insulation region which runs between the inner region and the outer region, and the through-connection is arranged on one wall of the pressure channel and comprises an electrically conductive connection to the inner region; and preparing a second metallic partial coating, which covers the through-connection and the inner region and leaves the outer region and the insulation region uncovered. 11. The method according to claim 10 , wherein: said preparation of the first partial coating comprises a sputtering process, wherein the first partial coating in particular comprises initially an adhesion promoter layer, which contains chromium, and a conductive layer, which contains copper. 12. The method according to claim 10 , wherein: a lift-off lacquer is deposited in the area of the insulation region prior to preparing said first partial coating; the first partial coating of the inner region and the outer region is prepared initially in a continuous manner; and the insulation region is formed prior to preparing the second partial coating by means of a lift-off process, in which the lift-off lacquer and the metal deposited on it are removed. 13. The method according to claim 10 , wherein: said preparation of the second partial coating comprises a galvanic process. 14. The method according to claim 13 , wherein: the first partial coating comprises copper, the second partial coating comprises nickel, nucleation of nickel on the first partial coating is initiated by a metallic contact, in particular, a temporary metallic contact—between the first partial coating and a metal which is less noble than nickel; the less noble metal compris