MAGNETIC ACTUATOR FOR DIRECT GENERATION OF A ROTARY ACTUATION OF A SHAFT WITH CURRENTLESS FIXATION OF THE STOP POSITION

Abstract

A magnetic actuator for the direct generation of a rotary actuation of a shaft (1) with currentless stop position fixation is proposed, which comprises at least one permanent magnetic anchor (2) configured as an annular segment and torque-proof connected to the shaft (1) and at least two electromagnet systems (7, 8), which each have a coil (5, 6) wound around a ferromagnetic core (3, 4), wherein the at least two electromagnet systems (7, 8) and the at least one permanent magnetic anchor (2) are arranged in a non-magnetic pole conduit (10) or on a circular path configured as an annular segment or as a ring co-axially with respect to the rotating shaft (1), the at least one permanent magnetic anchor (2) is arranged between two electromagnet systems (7, 8), and the length of the circular segment between the electromagnet systems (7, 8) is greater than the length of the anchor (2) arranged between the electromagnet systems (7, 8) in peripheral direction in order to make possible a motion of the anchor (2) along a circular path segment between the electromagnet systems (7, 8) corresponding to their current feed.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will now be described, by way of example, with reference to the accompanying drawings in which.

FIG. 1 shows a schematic representation of an actuator according to a first embodiment of the invention;

FIG. 2 shows a schematic representation of the force acting on the magnetic anchor of the actuator with a current feeding of the coils from alternating directions; and

FIG. 3 shows a schematic representation of a further embodiment of an actuator according to the invention.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 shows an actuator for making a direct rotary actuation of a shaft 1 possible. It comprises a permanent magnetic anchor 2 enclosed by a flow guiding plate 9 for the magnetic flow, which is configured as an annular segment and is fixedly connected to the shaft 1. The actuator also includes two electromagnet systems 7, 8, each having a coil 5, 6 wound around a ferromagnetic core 3, 4.

As can be seen in FIG. 1, the electromagnet systems 7, 8 and the permanent magnetic anchor 2 are arranged in a magnetically conducting pole conduit 10 configured as an annular segment or are arranged on a circular path co-axially with regard to the shaft 1, while the permanent magnetic anchor 2 is arranged between the two electromagnet systems 7, 8. The length of the circular segment between the two electromagnet systems 7, 8 is greater herein than the length of the anchor 2 in the peripheral direction in order to make a motion of the anchor 2 possible along a circular path segment between the electromagnet systems 7, 8 corresponding to their current feed.

A magnetic field is built up by way of a corresponding current feed of the coils 5, 6 of the electromagnet systems 7, 8, which results in motion of the anchor 2 and, consequently, of the shaft 1 that is connected in a rotationally fixed manner along a circular segment. At the corresponding stop position, the permanent magnetic anchor 2 is attracted by the ferromagnetic core 3 or 4 of the currentless coil 5 or 6 on which the anchor 2 rests, whereby currentless retention of each stop position is possible.

This arrangement makes delivering a current to the coils 5 and 6 from alternating directions possible, where the force actions of both coils 5, 6 are added. This fundamental principle is illustrated in FIG. 2.

FIG. 2 shows a permanent magnetic anchor 2, which can be moved axially between the coils by way of magnetic forces F depending on the current delivered to the coils 5, 6. The force acting on the anchor 2, is doubled through the current delivered to the coils 5, 6 from different directions. In the shown example, both coils are provided with current from alternating directions so that the north pole N of the anchor 2, which faces toward the coil 5, is attracted by the south pole S of the coil 5 while, at the same time, the south pole S of the anchor 2, which faces toward the coil 6, is repelled by the south pole S of the coil 5.

It is also possible to provide the actuator with several permanent magnetic anchors, which are configured as an annular segment and are connected in a rotationally fixed manner to the rotational shaft. An example of such an arrangement is shown in FIG. 3.

The actuator comprises two mutually diametrically opposite lying permanent magnetic anchors 2, 2′, which are connected in a rotationally fixed manner to the shaft 1, and are respectively located in a circular-shaped, pole conduit 10 arranged co-axially with regard to the shaft 1, between two mutually diametrically opposite lying electromagnet systems 7, 8. The electromagnet systems 7, 8 each have a coil 5, 6 wound around a ferromagnetic core 3,4. (In the peripheral direction of the circular-shaped pole conduit 10, an anchor and an electromagnet system are alternatively arranged). Permanent magnetic anchors 2, 2′ are provided with an antipodal magnetization.

Similarly as in the embodiment of FIG. 1, the length of the circular segment, between the two electromagnet systems 7, 8, is greater than the length of the anchors 2, 2′ in the peripheral direction, in order to make motion of the anchor 2, 2′ possible, along a circular path between the electromagnet systems 7, 8.

A further increase of the rotary force, in comparison with the embodiment of FIG. 1, is achieved by way of the arrangement shown in FIG. 3, since the magnetic forces act simultaneously on two anchors 2, 2′ without increasing the number of electromagnet systems.

Within the scope of further embodiments of the invention, which are not depicted, the actuator is provided with an even number (2*n, n=1, 2, 3, . . . , etc.) of annular segments and magnetic anchors, which are connected in a rotationally fixed manner to the shaft that is to be rotated and comprises the same even number of electromagnet systems, while the anchors are arranged in the peripheral direction of a circular-shaped pole conduit, which is co-axially arranged between two electromagnet systems with regard to the shaft that is to be rotated. Two anchors, which are arranged mutually consecutively in the peripheral direction, are provided with an antipodal magnetization.

With an equal odd number (2*n+1, n=1, 2, 3, . . . ) of anchors and electromagnet systems, a device for shielding the magnetic field must be arranged between an anchor and an electromagnet system.

It is understood that also any other constructive configuration, especially any arrangement in space of the components of the actuator, alone or in combination as long as it is technically practical, is included within the scope of the claims, without influencing the function of the actuator as it is disclosed in the claims, even if these configurations are not explicitly represented in the Figures or described in the specification.

REFERENCE NUMERALS

• 1 shaft
• 2 permanent magnetic anchor
• 2′ permanent magnetic anchor
• 3 ferromagnetic core
• 4 ferromagnetic core
• 5 coil
• 6 coil
• 7 electromagnet system
• 8 electromagnet system
• 9 flow guiding plate
• 10 pole conduit
• F magnetic force
• N north pole
• S south pole

Claims

1-6. (canceled)

7. A magnetic actuator for directly generating rotary actuation of a shaft (1) with currentless stop position fixation, the magnetic actuator comprising: at least one permanent magnetic anchor (2) being connected to the shaft (1) in a rotationally fixed manner, and the permanent magnetic anchor (2) being an annular segment; andat least two electromagnet systems (7, 8) each having a coil (5, 6) wound around a ferromagnetic core (3, 4), the two electromagnet systems (7, 8) and the permanent magnetic anchor (2) are one of configured within a non-magnetic pole conduit (10), about a circular path as an annular segment, and as a ring co-axial with respect to the rotating shaft (1);the permanent magnetic anchor (2) is arranged between the two electromagnet systems (7, 8); and a length of the annular segment of the circular path, between the two electromagnet systems (7, 8), is greater than a length of the permanent magnetic anchor (2), arranged between the electromagnet systems (7, 8), in a peripheral direction, to enable the permanent magnetic anchor (2) to travel about the circular path segment between the electromagnet systems (7, 8) depending on a flow electrical current.

8. The magnetic actuator according to claim 7, wherein the ferromagnetic core (3, 4) of the currentless coil (5, 6) attracts the permanent magnetic anchor (2), which is connected to the shaft (1) in a rotationally fixed manner, to currentlessly retain the magnetic anchor (2) in the respective stop position.

9. The magnetic actuator according to claim 7, wherein the magnetic actuator comprises two mutually diametrically opposite permanent magnetic anchors (2, 2′) which are each connected to the shaft (1) in a rotationally fixed manner, are respectively arranged in the circular-shaped pole conduit (10), and are arranged co-axially with respect to the shaft (1) between the electromagnet systems (7, 8) which are diametrically opposite, while the two permanent magnetic anchors (2, 2)′ are provided with an antipodal magnetization.

10. The magnetic actuator according to claim 7, further comprises an even number (2*n, n=1, 2, 3, . . . , etc.) of annular segments and magnetic anchors (2, 2′) which are connected to the shaft (1), in a rotationally fixed manner, that is to be rotated, and the same even number of electromagnet systems (7, 8), in which the magnetic anchors (2, 2′) are arranged in the peripheral direction of the circular-shaped pole conduit (10), which is co-axially arranged between electromagnet systems (7, 8) with regard to the shaft that is to be rotated, and in which the magnet anchors (2, 2′), which are arranged mutually consecutively in the peripheral direction, are provided with an antipodal magnetization.

11. The magnetic actuator according to claim 7, further comprising an equal odd number (2*n+1, n=1, 2, 3, . . . ) of annular segments and magnetic anchors (2, 2′), which are connected to the shaft (1), in a rotationally fixed manner, that is to be rotated, and the same even number of electromagnet systems (7, 8), in which the magnetic anchors (2, 2′) are arranged in the peripheral direction of the circular-shaped pole conduit (10), which is co-axially arranged between electromagnet systems (7, 8) with regard to the shaft (1) that is to be rotated, and a device for shielding the magnetic field is located between an anchor and an electromagnet system.

12. The magnetic actuator according to claim 7, wherein the coils (5, 6) of each of the electromagnet systems (7, 8) receive current from different directions, such that a force action of the coils (5, 6) is added to a rotary force of the actuator.

13. A magnetic actuator for directly actuating rotational movement of a shaft (1) between at least two positions, at which the rotational movement of the shaft (1) stops, the magnetic actuator comprising: at least one permanent magnetic anchor (2) being rotationally fixed to the shaft (1) and being formed as segment of a ring;at least two electromagnet systems (7, 8), each of the at least two electromagnet system (7,8) having a coil (5, 6) wound around a ferromagnetic core (3, 4), the electromagnet systems (7, 8) and the anchor (2) extend in a circular path about the shaft (1) within a non-magnetic pole conduit (10), and the circular path of the conduit (10) and the shaft (1) are co-axial with one another;the magnetic anchor (2) is located within the circular conduit (10) between the two electromagnet systems (7, 8), and has a radial length shorter than a radial distance between the two electromagnet systems (7, 8) such that the magnetic anchor (2) and the shaft (1) fixed thereto travels about the circular path of the conduit (10) between the two electromagnet systems (7, 8); andthe magnetic anchor (2) has at least one stop position in which rotational movement of the anchor (2) ceases, and when electrical current to the coils (5, 6) is turned off, the magnet of the magnetic anchor (2) is magnetically attracted to the ferromagnetic core (3, 4) of the two electromagnet systems (7, 8) to thus prevent rotation of the magnetic anchor (2).