Rotary-tool mandrel, unit for converting a flat substrate, and operating method

The invention claimed is: 1. A rotary-tool mandrel for a conversion unit for converting a flat substrate, the mandrel being configured to receive a sleeve thereon, the mandrel comprising: a cylindrical core; a front journal and a rear journal respectively on either end of the cylindrical core; a front bearing of the conversion unit holding the front journal; a rear bearing of the conversion unit holding the rear journal; the front journal and the rear journal forming a rotating shaft of the rotary-tool mandrel; a peripheral wall that is able to take up a rest position and a locking position by exerting a radial pressure on the sleeve in order to lock the sleeve in position on the mandrel; a pressure fluid circuit provided between the peripheral wall and the cylindrical core for exerting the radial pressure on the sleeve; and a cooling fluid circuit for allowing a fluid to flow in the region of the cylindrical core and for cooling the mandrel. 2. The mandrel according to claim 1 , wherein the pressure circuit and the cooling circuit are connected together. 3. The mandrel according to claim 1 , wherein a docking port for the cooling circuit is arranged at a front end of the mandrel, and a docking port for the pressure circuit is arranged at a rear end of the mandrel. 4. The mandrel according to claim 3 , wherein the docking ports are aligned along an axis of rotation the mandrel. 5. The mandrel according to claim 3 , wherein each docking port comprises a connection element of the mandrel configured to engage with a complementary connection element of the conversion unit in order to connect the pressure circuit to the cooling circuit. 6. The mandrel according to claim 5 , wherein the connection elements and the complementary connection elements are of the quick-connector type, taking up a closed-off position when the connection elements and the complementary connection elements are disconnected, and taking up an open position, allowing the passage of a fluid, when the connection elements and the complementary connection elements are connected. 7. The mandrel according to claim 1 , wherein the pressure circuit has a portion in the form of a tube around the cylindrical core and coaxial with the axis of rotation of the mandrel. 8. The mandrel according to claim 1 , wherein the pressure circuit has a respective axial duct portion in at least one of the front journal and the rear journal, each respective axial duct portion linking to a respective docking port to allow a pressure fluid to flow through the pressure circuit from the respective docking port to each respective axial duct portion. 9. The mandrel according to claim 8 , wherein the pressure circuit comprises at least one radial duct portion in the cylindrical core, the at least one radial duct portion linking each respective axial duct portion to a portion in the form of a tube around the cylindrical core and coaxial with the axis of rotation of the mandrel, to allow a pressure fluid to flow through the pressure circuit from each respective axial duct portion to the portion in the form of a tube around the cylindrical core. 10. A unit for converting a flat substrate, comprising at least one mandrel according to claim 1 . 11. The unit according to claim 10 , wherein the cooling circuit is connected to a cooling module for cooling the fluid. 12. The unit according to claim 10 , wherein the pressure circuit connected to the cooling circuit forms a closed circuit. 13. A method for operating a conversion unit for converting a flat substrate, the conversion unit comprising: at least one rotary-tool mandrel for a unit for converting a flat substrate, the mandrel being configured to receive a sleeve thereon; the mandrel comprising: a cylindrical core; a peripheral wall configured to take up a rest position and a locking position by exerting a radial pressure on the sleeve in order to lock the sleeve in position on the mandrel; a pressure fluid circuit provided between the peripheral wall and the cylindrical core for exerting the radial pressure on the sleeve; a cooling fluid circuit for allowing a fluid to flow in the region of the cylindrical core and for cooling the mandrel; and a front docking port for the cooling fluid circuit arranged at a front end of the mandrel, and a rear docking port for the pressure fluid circuit arranged at a rear end of the mandrel; the method comprising the steps of: connecting only one of the front and rear docking ports of the pressure fluid circuit to the cooling circuit; exerting a radial pressure on the sleeve with the peripheral wall by sending a fluid through the pressure circuit to lock the sleeve in position on the mandrel; and connecting the front and rear docking ports of the pressure circuit to the cooling circuit and causing a cooled fluid to flow through the pressure circuit in order to cool the mandrel. 14. The method according to claim 13 , wherein the flow of the fluid through the pressure circuit in order to cool the mandrel is realized in a closed circuit. 15. The method according to claim 13 , wherein the docking port of the pressure circuit connected to the cooling circuit in order to secure the sleeve to the mandrel is the docking port arranged at the rear of the mandrel, on the opposite side from the driver.