Electromagnetic actuator and circuit breaker comprising such an actuator

The invention claimed is: 1. An electromagnetic actuator configured to be disposed in a circuit breaker, comprising: a magnetic field frame, a coil secured to the field frame and which is configured to connect to a power line of an electrical circuit, a magnetic core arranged in the coil and that can move, along a central axis defined by the coil as a function of the intensity of the current flowing in the coil, wherein the magnetic core is configured to be coupled to a movable structure which is configured to open and close the electric circuit; and a shunt device arranged in the coil and comprising a magnetocaloric material, the magnetization of which is a function of the temperature, wherein the shunt device is arranged in the coil for a length, along the central axis, in such a way as to form an air gap between the shunt device and the magnetic core, the actuator further comprising means for fixing the shunt device to the field frame, designed to set this length, wherein a reluctance of the shunt device is dependent on the length such that the trigger threshold of the circuit breaker is dependent upon the length. 2. The actuator as claimed in claim 1 , wherein the actuator further comprises a heat conducting sheath placed in the coil and wherein the magnetic core and the shunt device are arranged in the sheath. 3. The actuator as claimed in claim 2 , wherein the shunt device is in contact with the heat conducting sheath. 4. The actuator as claimed in claim 2 , wherein the heat conducting sheath has a solid wall. 5. The actuator as claimed in claim 2 , wherein the heat conducting sheath comprises a slot that extends parallel to its central axis. 6. The actuator as claimed in claim 1 , wherein a spring is interposed between the shunt device and the magnetic core. 7. The actuator as claimed in claim 6 , wherein the shunt device is provided with a polar part, arranged between the spring and a part of the shunt device, consisting of the magnetocaloric material. 8. The actuator as claimed in claim 1 , wherein the fixing means include a laser weld or a mechanical locking device. 9. The actuator as claimed in claim 1 , wherein the magnetocaloric material is an alloy of nickel, cobalt, manganese and a fourth element chosen among aluminum, indium, antimony and tin. 10. A circuit breaker comprising a box accommodating an actuator as claimed in claim 1 , the coil of the actuator being connected to a power line, and a pair of contacts that can move relative to each other, a first one of the contacts being mechanically linked with the magnetic core of the actuator. 11. An electromagnetic actuator, comprising: a magnetic field frame, a coil secured to the field frame and which can be linked to an electrical circuit, a magnetic core arranged in the coil and that can move, along a central axis defined by the coil as a function of the intensity of the current flowing in the coil; and a shunt device arranged in the coil and comprising a magnetocaloric material, the magnetization of which is a function of the temperature, wherein the shunt device is arranged in the coil for a length, along the central axis, in such a way as to form an air gap between the shunt device and the magnetic core, the actuator further comprising means for fixing the shunt device to the field frame, designed to set this length, wherein a spring is interposed between the shunt device and the magnetic core, and the shunt device is provided with a polar part, arranged between the spring and a part of the shunt device, consisting of the magnetocaloric material. 12. An electromagnetic actuator, comprising: a magnetic field frame, a coil secured to the field frame and which can be linked to an electrical circuit, a magnetic core arranged in the coil and that can move, along a central axis defined by the coil as a function of the intensity of the current flowing in the coil; and a shunt device arranged in the coil and comprising a magnetocaloric material, the magnetization of which is a function of the temperature, wherein the shunt device is arranged in the coil for a length, along the central axis, in such a way as to form an air gap between the shunt device and the magnetic core, the actuator further comprising means for fixing the shunt device to the field frame, designed to set this length, wherein the magnetocaloric material is an alloy of nickel, cobalt, manganese and a fourth element chosen among aluminum, indium, antimony and tin.