Piezoelectric pressure sensor and process of manufacturing same

What is claimed is: 1. A piezoelectric pressure sensor comprising: a membrane that captures a pressure profile; a piezoelectric sensor on which polarization charges are generated, the piezoelectric sensor being disposed with respect to the membrane so as to generate polarization charges by the pressure profile captured by the membrane; an electrode arrangement having a charge output connected to the piezoelectric sensor for receiving and transmitting the polarization charges as signals generated from the piezoelectric sensor; an electrical signal conductor; and an electrical connecting element electrically and mechanically connected to the electrical signal conductor and the charge output; and wherein the charge output is connected in certain areas by material bonding to the electrical connecting element for transmitting signals through the electrical connecting element into the electrical signal conductor. 2. The piezoelectric pressure sensor according to claim 1 , wherein: a rear end of the charge output protrudes into the electrical connecting element ( 43 , 53 ); and an external surface of the rear end of the charge output that protrudes into the electrical connecting element is connected to an internal surface of the electrical connecting element by material bonding. 3. The piezoelectric pressure sensor according to claim 1 , wherein: the piezoelectric pressure sensor includes a pre-stressing body that mechanically pre-stresses the piezoelectric sensor; the electrode arrangement includes a charge pick-off and; the pre-stressing body is arranged on a side of the charge pick-off that faces away from the membrane. 4. The piezoelectric pressure sensor according to claim 3 , further comprising a first electric insulation body arranged between the charge pick-off and the pre-stressing body and electrically insulating the charge pick-off from the pre-stressing body. 5. The piezoelectric pressure sensor according to claim 4 , further comprising an electric feedthrough arrangement mechanically connected to the pre-stressing body; wherein: the charge output is mechanically supported on the electric feedthrough arrangement on the side of the pre-stressing body that faces away from the membrane; the charge output is electrically and mechanically connected to the charge pick-off; the charge output is arranged on the side of the charge pick-off that faces away from the membrane; and the charge output extends through the first electric insulation body and the pre-stressing body and is spaced apart from the first electric insulation body and the pre-stressing body by a gap. 6. The piezoelectric pressure sensor according to claim 5 , further comprising a compensation element wherein: the first electric insulation body is mechanically contacting the charge pick-off and the compensation element, which is mechanically contacting the pre-stressing body; in a first supporting area the electrode arrangement is mechanically supported via the charge pick-off; the electric feedthrough arrangement is mechanically connected to the pre-stressing body and the charge output; and in a second supporting area the electrode arrangement is supported via the charge output. 7. The piezoelectric pressure sensor according to claim 5 , wherein: the electric feedthrough arrangement has a first adapter element, a second electric insulation body and a second adapter element; the charge output is electrically and mechanically connected to the second adapter element; and the second electric insulation body is arranged between the charge output and the pre-stressing body and electrically insulates the charge output from the pre-stressing body. 8. The piezoelectric pressure sensor according to claim 3 , further comprising a first electric insulation body and a compensation element; wherein: in a first supporting area the electrode arrangement is mechanically supported via the charge pick-off; and the first electric insulation body is mechanically connected to the charge pick-off and the compensation element, which is mechanically connected to the pre-stressing body. 9. The piezoelectric pressure sensor according to claim 8 , further comprising a pre-stressing sleeve wherein: the charge pick-off, the piezoelectric sensor, the pre-stressing sleeve and the pre-stressing body are mechanically connected to each other; and in a third supporting area the electrode arrangement is supported via the charge pick-off. 10. The piezoelectric pressure sensor according to claim 9 , wherein: the piezoelectric sensor includes a piezoelectric element and a second support element that is disposed between the piezoelectric element and the charge pick-off; the second support element is arranged on a side of the piezoelectric element that faces away from the membrane; and material bonding connects the second support element to the piezoelectric element and to the charge pick-off. 11. The piezoelectric pressure sensor according to claim 10 , wherein: the piezoelectric sensor includes a first support element that is arranged on a side of the piezoelectric element that faces away from the membrane; and material bonding connects the piezoelectric element to the first support element and to the pre-stressing sleeve. 12. The piezoelectric pressure sensor according to claim 1 , further comprising an electric insulation element defining an inner surface having a second locking element, wherein: the electrical connecting element includes an outer surface that defines a first locking element which protrudes into the second locking element on the inner surface of the electric insulation element; and the first locking element ( 43 . 00 ) and the second locking element are formed matching each other with play and form one of a form closure and a contact closure. 13. A process for manufacturing a piezoelectric pressure sensor, comprising the steps of: providing a sensor assembly as a semi-finished product that includes a membrane, a piezoelectric sensor and an electrode arrangement with a charge output; and using a material bond to connect certain areas of the charge output to an electrical connecting element of one of a sensor cable assembly and an evaluation unit. 14. The process according to claim 13 , wherein the charge output is connected to an electrical connecting element of a signal cable assembly that includes a supporting body having a supporting body frame in which is arranged the electrical connecting element, which is accessible from the outside through at least one window in the supporting body frame, the process further comprising the steps of: passing a joint tool through the window in the supporting body frame and using the joint tool to produce the material bond between the charge output and the electrical connecting element. 15. The process according to claim 14 , wherein the sensor assembly includes a sensor housing in which is arranged wherein the charge output that is connected to an electrical connecting element of a signal cable assembly that includes a connection element casing having a supporting body frame in which is arranged the electrical connecting element, which is accessible from the outside through at least one window in the supporting body frame, the process further comprising the step of: after the material bond has been made between the charge output and the electrical connecting element, then displacing the connection element casing with respect to the sensor housing so that the connection element casing is pushed over the supporting body so that the supporting body frame is no longer accessible from