Method for manufacturing a sensorized braking element, in particular a brake pad and a sensorized brake pad obtained thereby

The invention claimed is: 1. A method for making sensorized brake elements for vehicles, comprising the steps of integrating directly on a first surface of a supporting metal element of the brake element intended in use to be facing an element to be braked, including a disk or drum, of a vehicle: at least one piezoceramic sensor adapted to emit an electric signal when subjected to a mechanical stress, the at least one piezoceramic sensor being made from a piezoceramic material having a Curie temperature that is higher than 200° C.; and an electric circuit configured for capturing the electric signal and processing the captured electric signal; wherein the electric circuit is made as an electrically insulated unit including at least one branching ending with respective electric contacts for the at least one piezoceramic sensor; the at least one piezoceramic sensor being electrically and mechanically connected to the electric contacts arranged at an end of the at least one branching; in which the electric circuit and the at least one piezoceramic sensor are mechanically and integrally fixed to the first surface of the supporting metal element; and the branching being configured for positioning the at least one piezoceramic sensor at a predetermined point of the first surface of the supporting metal element and in such a manner that the at least one piezoceramic sensor is directly and completely imbedded within a friction material block arranged onto and supported by the first surface, and wherein the at least one piezoceramic sensor has an operating temperature equal to or higher than 200° C., and in which the at least one piezoceramic sensor self-generates said electric signal in response to mechanical stress without the need for electric power. 2. A method according to claim 1 , wherein the first surface of the supporting metal element is provided with at least one seat for the at least one piezoceramic sensor, the seat having a first recess having a depth of substantially an order of magnitude smaller than a thickness of the at least one piezoceramic sensor measured perpendicular to the first surface, the seat further having at least one groove-shaped second recess for housing the electric circuit and the at least one branching thereof substantially flush with the first surface, the first and second recesses being made by one of a machining tool, laser or fine blanking of the supporting metal element. 3. A method according to claim 2 , wherein the at least one piezoceramic sensor is integrally fixed to the first surface of the supporting metal element in an electrically insulated manner by gluing and electrically connected to at least one of the contacts by wire bonding. 4. A method according to claim 2 , in which the electric circuit is made from respective conductor cables electrically insulated from each other and from the supporting metal element in which the conductor cables are electrically connected with the contacts, and in which the conductor cables are arranged within respective grooves of the supporting metal element identified by the at least one second recess. 5. A method according to claim 1 , in which the electric circuit is defined by a plurality of electrically conductive tracks that are electrically insulated from each other and with respect to the supporting metal element, each of the conductive tracks ending towards the at least one piezoceramic sensor with at least one electric contact electrically and mechanically connected with the sensor, at least one pair of the tracks defining one said branching. 6. A method according to claim 5 , wherein the electric circuit with the electrically conductive tracks, the contacts and respective electrically insulating layers over and below the tracks are directly obtained by screen printing over the first surface of the supporting metal element, inside the at least one second recess if present; in which a first contact of a first said conductive track is directly electrically and mechanically connected to a first face of the at least one piezoceramic sensor, and a second contact of a second said conductive track and obtained in a position immediately adjacent to and coplanar with the first contact is connected to a second face of the at least one sensor, opposite the first face, by wire-bonding, or to a different portion of the first face of the piezoceramic sensor, if the latter is of the type with built up electrodes. 7. A method according to claim 5 , in which the electric circuit with the conductive tracks, and the contacts are obtained by screen printing, over a first electrically insulating polymeric layer, said first polymeric layer being made of a polyimide and subsequently at least the conductive tracks are covered with a second electrically insulating polymeric layer, said second polymeric layer being made of a polyimide, so as to form an electrically insulated self-supporting unit; the self-supporting unit being subsequently glued directly over the first surface of the supporting metal element and finally the at least one piezoceramic sensor being mechanically and electrically connected with a first contact of a first said conductive track and with a second contact of a second said conductive track obtained in a position immediately adjacent to and coplanar with the first contact, arranging a first face of the at least one piezoceramic sensor against the first contact and folding the second contact onto the first contact and against a second face of the at least one sensor opposite the first face, with the at least one piezoceramic sensor being sandwiched between the first and the second contact; or connecting the second contact with the second face of the at least one piezoceramic sensor by means of wire bonding; the at least one piezoceramic sensor being finally coated with an electrically insulating layer. 8. A method according to claim 1 , further comprising a friction layer or block over the electric circuit and the at least one piezoceramic sensor, the at least one piezoceramic sensor being electrically connected with the electric circuit and the friction layer or block being formed on the first surface of the supporting metal element, which incorporates at least part of the at the least one piezoceramic sensor within the thickness of the friction layer. 9. A method according to claim 1 , in which a shallow recess is provided on an edge of the supporting metal element arranged on the opposite side of the at least one branching of the electric circuit, the shallow recess being configured for the receipt of an electric connector which is electrically connected to the electric circuit to capture the signals thereof. 10. The method according to claim 1 , in which the at least one piezoceramic sensor includes opposing electrodes and wherein the piezoceramic material of the at least one piezoceramic sensor is not naturally piezoelectric until the at least one sensor is subjected to a polarization treatment by applying an appropriate voltage to the electrodes. 11. A sensorized brake element comprising: a supporting metal element, a damping and a thermally insulating layer arranged on the supporting metal element on the side of a first surface of the supporting metal element intended in use to face an element to be braked, including a disk or a drum of a vehicle, and a friction material block integrally supported by the supporting metal element on the side of the first surface and above the damping and thermally insulating layer; at least one piezoceramic sensor below the damping and electrically insulating layer and fixed directly over the first surface of the supporting metal element, the at least one piezoceramic sensor designed to e