Method for joining a ceramic friction element to a piezoceramic element

What is claimed is: 1. A method of joining a ceramic friction element ( 11 ) to an element of piezoceramic material defining a piezoelectric element ( 1 ), said piezoelectric element ( 1 ) comprising at least one excitation electrode ( 2 ) and at least one general electrode ( 3 ) spaced from the at least one excitation electrode ( 2 ), and between said excitation electrode ( 2 ) and said general electrode ( 3 ) at least a portion of the piezoceramic material of said piezoelectric element ( 1 ) is disposed, said method comprising the following process steps: Step 1: Preparation of a low-melting glass mass ( 12 ); Step 2: Disposing the low-melting glass mass ( 12 ) between a joining surface ( 10 ) of the friction element ( 11 ) and a contact surface ( 9 ) of the piezo element ( 1 ); Step 3: Applying a pressing force and pressing the joining surface ( 10 ) of the friction element ( 11 ) and the contact surface ( 9 ) of the piezoelectric element ( 1 ) against one another with the low-melting glass mass ( 12 ) arranged therebetween and maintaining the pressing force for all subsequent process steps; Step 4: Heating the piezoelectric element ( 1 ) and the friction element ( 11 ) to a defined temperature above the Curie point of the piezoceramic material of the piezo element ( 1 ) and above the melting point of the low-melting glass mass ( 12 ); Step 5: After reaching the defined temperature of the piezoelectric element ( 1 ) and the friction element ( 11 ) and while maintaining the defined temperature, applying an electric polarization voltage Up to the electrodes ( 2 , 3 ) of the piezoelectric element ( 1 ) so that an electric field Ep polarizing the piezoceramic material is generated in the piezoceramic material between the electrodes ( 2 , 3 ), and maintaining the electric field Ep for a defined period of time; Step 6: Cooling the piezoelectric element ( 1 ) and the friction element ( 11 ) while maintaining the polarizing electric field Ep below the Curie point, and, after falling below the Curie point, removing the electric polarization voltage Up applied to the electrodes ( 2 , 3 ); Step 7: Cooling the piezoelectric element and the friction element to room temperature without any electric voltage being applied to the electrodes ( 2 , 3 ). 2. The method according to claim 1 , characterized in that the low-melting glass mass ( 12 ) is prepared in the form of a film or a paste consisting of an organic binder and low-melting glass particles. 3. The method according to claim 2 , characterized in that the low-melting glass mass ( 12 ) is applied to the contact surface ( 9 ) of the piezoelectric element ( 1 ) and/or the joining surface ( 10 ) of the friction element ( 11 ) by melting with simultaneous combustion of the organic binder. 4. The method according to claim 1 , characterized in that during the preparation of the low-melting glass mass ( 12 ), grains of calibrated size of a refractory oxide ceramic are added to the low-melting glass mass ( 12 ). 5. The method according to claim 1 , characterized in that a polarization current Ip is stabilized when the electric polarization voltage Up is applied to the electrodes ( 2 , 3 ) of the piezoelectric element ( 1 ). 6. The method according to claim 1 , characterized in that at least process steps 4 to 6 are carried out such that the piezoelectric element ( 1 ) and the friction element ( 11 ) are located in a furnace ( 13 ). 7. The method according to claim 6 , characterized in that the process steps 4 to 6 are carried out under an inert gas atmosphere.