Device for locking a piston rod of a piston of an actuator which is pressurizable in order to disengage a parking lock and is spring-loaded in order to engage the parking lock

The invention claimed is: 1. A device ( 2 ; 204 ) for locking a piston rod ( 7 ) of a piston ( 4 ) of an actuator, which is pressurizable in order to disengage a parking lock ( 3 ), the device ( 2 ; 204 ) comprising: a latching mechanism ( 50 ) with interlocking elements ( 51 ) accommodated in an axially fixed manner in a housing-affixed component ( 30 ), the interlocking elements ( 51 ) being radially movable; an actuating element ( 53 ) configured for actuating the latching mechanism ( 50 ), the actuating element ( 53 ) fixedly arranged on an axially displaceable armature rod ( 20 ) of an electromagnet ( 19 ), the actuating element ( 53 ) clamped between two preloading springs ( 55 , 56 ) resting against a housing ( 54 ), the actuating element ( 53 ) comprising two actuating contours ( 22 , 23 ) that face each other and at which the interlocking elements ( 51 ) move and are radially displaced upon actuation of the latching mechanism ( 50 ); and a permanent magnet ( 62 ) configured such that the armature rod ( 20 ) is holdable in a first position when the electromagnet ( 19 ) is in a non-energized condition of the electromagnet ( 19 ), one of the actuating contours ( 23 ) of the actuating element ( 53 ) fixing the interlocking elements ( 51 ) of the latching mechanism ( 50 ) in a first groove ( 45 ) of the piston ( 4 ) in the first position, the parking lock ( 3 ) being in an engaged condition of the parking lock ( 3 ) when the armature rod ( 20 ) is in the first position of the armature rod ( 20 ), wherein the armature rod ( 20 ) is transferable out of the first position into a second position when the electromagnet ( 19 ) is in an energized condition of the electromagnet ( 19 ), the other of the actuating contours ( 22 ) of the actuating element ( 53 ) fixing the interlocking elements ( 51 ) of the latching mechanism ( 50 ) in a second groove ( 46 ) of the piston ( 4 ) in the second position, the parking lock ( 3 ) being in a disengaged condition of the parking lock ( 3 ) when the armature rod ( 20 ) is in the second position of the armature rod ( 20 ), wherein the armature rod ( 20 ) is transferable into an intermediate position of the armature rod ( 20 ) situated axially between the first position and the second position, the interlocking elements ( 51 ) of the latching mechanism ( 50 ) positioned radially out of the first groove ( 45 ) and the second groove ( 46 ) of the piston ( 4 ) and positioned within an intermediate section ( 61 ) of the actuating element ( 53 ) situated axially between the two actuating contours ( 22 , 23 ), the latching mechanism ( 50 ) releasable in the intermediate position, wherein a force directed towards the second position of the armature rod ( 20 ) acts upon the actuating element ( 53 ) in the first position of the armature rod ( 20 ), a force directed towards the first position of the armature rod ( 20 ) acts upon the actuating element ( 53 ) in the second position of the armature rod ( 20 ), and the armature rod ( 20 ) is in a force-compensated condition in the intermediate position of the armature rod ( 20 ), wherein components of the device ( 2 ; 204 ) are coordinated with regard to geometry and with regard to forces acting upon the components of the device ( 2 ; 204 ) such that the permanent magnet ( 62 ) holds the armature rod ( 20 ) in the first position when the electromagnet ( 19 ) is in the non-energized condition of the electromagnet ( 19 ) and the parking lock ( 3 ) is in the engaged condition of the parking lock ( 3 ), the electromagnet ( 19 ) holds the armature rod ( 20 ) in the second position when the electromagnet ( 19 ) is in the energized condition of the electromagnet ( 19 ) and the parking lock ( 3 ) is in the disengaged condition of the parking lock ( 3 ), the parking lock ( 3 ) is disengageable in a pressurized condition of the piston ( 4 ) and in the energized condition of the electromagnet ( 19 ), and the parking lock ( 3 ) is engageable in a non-pressurized condition of the piston ( 4 ) and in the non-energized condition of the electromagnet ( 19 ). 2. The device of claim 1 , wherein the components of the device ( 2 ; 204 ) are coordinated with regard to the geometry and with regard to the forces acting upon the components of the device ( 2 ; 204 ) such that the permanent magnet ( 62 ) holds the armature rod ( 20 ) in the first position when the electromagnet ( 19 ) is in the non-energized condition of the electromagnet ( 19 ), the parking lock ( 3 ) is in the engaged condition of the parking lock ( 3 ), and the piston ( 3 ) is in either the pressurized condition or the non-pressurized condition of the piston ( 4 ). 3. The device of claim 1 , wherein the components of the device ( 2 ; 204 ) are coordinated with regard to the geometry and with regard to the forces acting upon the components of the device ( 2 ; 204 ) such that the electromagnet ( 19 ) holds the armature rod ( 20 ) in the second position when the electromagnet ( 19 ) is in the energized condition of the electromagnet ( 19 ), the parking lock ( 3 ) is in the disengaged condition of the parking lock ( 3 ), and the piston ( 3 ) is in the non-pressurized condition of the piston ( 4 ). 4. The device of claim 1 , wherein the latching mechanism ( 50 ) is centrally arranged within the piston ( 4 ). 5. The device of claim 1 , wherein the components of the device ( 2 ; 204 ) are coordinated with regard to the geometry and with regard to the forces acting upon the components of the device ( 2 ; 204 ) such that: the armature rod ( 20 ) is transferable out of the first position into the intermediate position when the piston ( 3 ) is in the pressurized condition of the piston ( 4 ) and the electromagnet ( 19 ) is in the energized condition of the electromagnet ( 19 ); when the latching mechanism ( 50 ) is released, the piston rod ( 7 ) is transferable by pressure applied at the piston ( 4 ) in the direction of an end position of the piston ( 4 ) associated with the disengaged condition of the parking lock ( 3 ); when the latching mechanism ( 50 ) is released, the armature rod ( 20 ) is transferable into the second position by the energized electromagnet ( 19 ); and the parking lock ( 3 ) transitions out of the engaged condition into the disengaged condition when the armature rod ( 20 ) is transferred into the second position by the energized electromagnet ( 19 ). 6. The device of claim 1 , wherein the components of the device ( 2 ; 204 ) are coordinated with regard to the geometry and with regard to the forces acting upon the components of the device ( 2 ; 204 ) such that: when the parking lock ( 3 ) is in the disengaged condition of the parking lock ( 3 ), the piston ( 4 ) is in the non-pressurized condition of the piston ( 4 ), and the electromagnet ( 19 ) is in the non-energized condition of the electromagnet ( 19 ), the armature rod ( 20 ) is transferable into the intermediate position due to a preload force applied at the actuating element ( 53 ) in the second position of the armature rod ( 20 ) such that the latching mechanism ( 50 ) transitions into the released condition; the piston rod ( 7 ) is transferable into a position associated with the engaged condition of the parking lock ( 3 ) due to a spring force of a spring unit ( 5 ) such that the armature rod ( 20 ) transitions from the intermediate position into the first position, in which the permanent magnet ( 62 ) holds the armature rod ( 20 ). 7. The device of claim 1 , wherein the grooves ( 45 , 46 ) of the piston ( 4 ) are configured as radial inner grooves. 8. The device of claim 1 , wherein the latching mechanism ( 50 ) is configured as a ball stop, and the ball stop comprises a plurality of balls as the interlocking elements ( 51 ). 9. The