Micro value comprising an electrodynamic actuator having stationary magnet arrangement and a moveable air-core coil

The invention claimed is: 1. A microvalve, comprising: a fluid housing; a valve seat arranged in the fluid housing; a diaphragm clamped in the fluid housing and disposed on the valve seat; and an electrodynamic actuator placed on the fluid housing and configured to control a movement of the diaphragm in order to open or close the valve seat, wherein the electrodynamic actuator comprises: an immovable actuator structure including a magnet arrangement consisting of a plurality of permanent magnets, and configured to generate magnetic fields; a movable actuator structure including a control element having an air-core coil comprising a multitude of windings around a magnetically non-soft core, the air-core coil being arranged in the magnetic field and firmly coupled to a coil carrier made from a nonmagnetic material, the air-core coil being received in or wound on the coil carrier, and the control element configured to move relative to the magnet arrangement; and an extension part extended from the coil carrier and coupled with the diaphragm, and configured to open or close the valve seat by cooperating with the coupled diaphragm in response to a movement of the control element, wherein the magnetic fields include a first magnetic field having a first principal direction and a second magnetic field having a second principal direction opposed to the first principal direction, wherein the control element is mounted for swiveling movement about an axis of rotation that is parallel to the first and second principal directions of the magnetic fields, and wherein the extension part is formed integrally with the coil carrier or is attached to the coil carrier. 2. The microvalve according to claim 1 , wherein a first half of the air-core coil is arranged in the first magnetic field, and a second half of the air-core coil is arranged in the second magnetic field. 3. The microvalve according to claim 2 , wherein the air-core coil has a shape of an oval with a longitudinal axis, wherein the shape of the oval is a shape of a pair of complementary semicircles spaced from each other and having a linear middle piece connecting the semicircles, and wherein the longitudinal axis of the air-core coil divides the air-core coil into the first and second halves of the air-core coil. 4. The microvalve according to claim 1 , wherein the magnet arrangement includes a plurality of permanent magnets, wherein, when the control element is located in a first switching position, the longitudinal axis of the air-core coil is extended parallel to a longitudinal axis of the permanent magnets. 5. The microvalve according to claim 4 , wherein the permanent magnets are arranged such that permanent magnets facing each other face opposite poles. 6. The microvalve according to claim 1 , wherein the electrodynamic actuator further comprises an actuator housing configured to shield the magnetic fields of the magnet arrangement, and wherein the magnet arrangement and the control element are accommodated in the actuator housing. 7. The microvalve according to claim 6 , wherein the electrical connector is connected to the restoring element, is extended outward along the longitudinal direction of the actuator housing, and is attached to the actuator housing so that one end of the electrical connector is protruded from the actuator housing. 8. The microvalve according to claim 1 , wherein the electrodynamic actuator further comprises: at least one yoke plate made of a magnetically soft material, configured to strengthen the magnetic fields of the magnet arrangement and shield the magnetic fields of the magnet arrangement to the outside. 9. The microvalve according to claim 8 , wherein the yoke plate is part of an actuator housing. 10. The microvalve according to claim 9 , wherein the permanent magnets are attached directly to the inner wall of the actuator housing to constitute a preassembled unit. 11. The microvalve according to claim 1 , wherein the air-core coil is wound on the coil carrier, and the coil carrier includes a support surface for the winding that is limited by lateral walls. 12. The microvalve according to claim 1 , wherein the valve seat comprising first and second valve seats next to each other, the extension part includes a two-armed actuating lever coupled with the diaphragm, and the first and second valve seats are alternately opened and closed each other by the two-armed actuating lever. 13. A microvalve, comprising: a fluid housing; a valve seat arranged in the fluid housing; a diaphragm clamped in the fluid housing and disposed on the valve seat; and an electrodynamic actuator placed on the fluid housing and configured to control a movement of the diaphragm in order to open or close the valve seat, wherein the electrodynamic actuator comprises: an immovable actuator structure including a magnet arrangement consisting of a plurality of permanent magnets, and configured to generate magnetic fields; a movable actuator structure including a control element having an air-core coil comprising a multitude of windings around a magnetically non-soft core, the air-core coil being arranged in the magnetic field and firmly coupled to a coil carrier made from a nonmagnetic material, the air-core coil being received in or wound on the coil carrier, and the control element configured to move relative to the magnet arrangement; an extension part extended from the coil carrier, coupled with the diaphragm, and configured to open or close the valve seat by cooperating with the coupled diaphragm in response to a movement of the control element; and a restoring element forming at least part of an electrically conducting connection between a winding end of the air-core coil and an electrical connector, and configured to exert a preload on the control element, and wherein the extension part is formed integrally with the coil carrier or is attached to the coil carrier. 14. The microvalve according to claim 13 , wherein the restoring element includes at least one leaf spring or helical spring. 15. The microvalve according to claim 13 , wherein, when the control element is located in a first switching position, the longitudinal axis of the air-core coil is extended parallel to a longitudinal axis of the permanent magnets, and wherein the restoring element is configured to exert the preload on the control element away from the first switching position towards a second switching position. 16. A microvalve, comprising: a fluid housing; a valve seat arranged in the fluid housing; a diaphragm clamped in the fluid housing and disposed on the valve seat; and an electrodynamic actuator placed on the fluid housing and configured to control a movement of the diaphragm in order to open or close the valve seat, wherein the electrodynamic actuator comprises: an immovable actuator structure including a magnet arrangement consisting of a plurality of permanent magnets, and configured to generate magnetic fields; a movable actuator structure including a control element having an air-core coil comprising a multitude of windings around a magnetically non-soft core, the air-core coil being arranged in the magnetic field and firmly coupled to a coil carrier made from a nonmagnetic material, the air-core coil being received in or wound on the coil carrier, and the control element configured to move relative to the magnet arrangement; an extension part extended from the coil carrier, coupled with the diaphragm, and configured to open or close the valve seat by cooperating with the coupled di