EP0014737A1 - Electromagnetic actuator - Google Patents

Abstract

Electromagnetic actuating device in which the actuating element (11), which is clamped on one side, is held against a bias on a magnetic core (10) by a magnetic flux, the flux density of which can be changed cyclically with time. The actuating element (11) can be triggered selectively in that a compensation coil (13) is only excited when the magnetic flux attracting the actuating element (11) has its lowest value that is sufficient for holding. The source of the magnetic flux is a permanent magnet (12) which is moved or rotated to cyclically change the force attracting the actuating element (11) with respect to a pole pair (16, 17) of the magnetic core (10), as a result of which it moves the magnetic resistance between the permanent magnet (12) and the magnetic core (10) of the electromagnetic actuating device changes cyclically.

Description

The invention relates generally to an electromagnetic actuating device of the type in which the actual actuating element or the armature is held tensioned against a prestressing force and can be triggered selectively for a working stroke. In some areas of application, such as. B. line printers, magnetic actuators are used to drive the print hammers and use compensation coils that counteract the excitation of the force attracting the hammer and thus release the hammer to stop. In known actuators, the tripping current for the compensation coil is relatively high, so that additional components are required to control the driver circuits for the windings of the print hammer magnet. These components naturally cause additional effort in comparison to the production of the driver stages in integrated circuit technology, as is the case with most pressure control circuits today.

With the advancing development of printer technology, such actuators, namely the print hammer magnets, have to operate at ever higher speeds, which in turn leads to difficulties in dissipating the heat occurring in the print hammer magnet coil because the on-time of the print hammer magnets increases continuously. Attempts have already been made to counteract these difficulties by reducing the mass of the pressure hammers, adding additional windings and providing return devices for the pressure hammers.

One possibility of changing the size of the readout current is in the applicant's US patent application filed on December 29, 1978 with the Document number 974 297, in which a permanent magnet serves as the middle leg of a three-legged magnetic core and thus forms two parallel flow paths, the actuating element forming part of a flow path and an element with variable magnetic resistance forming part of the second flow path. The cyclic change in the magnetic resistance of the second flux path also affects the flux density in the first flux path, and this enables excitation of the compensation coil at a time when the force pulling the armature or the actuator is less than its maximum value. However, this construction has the disadvantage that because of the flux change in the compensation coil, the oppositely directed magnetomotive force must also be overcome. Another disadvantage arises in the case of multiple cores with a common permanent magnet and a common compensation coil, since the cores are also influenced by the change in the magnetic resistance in the adjacent core, as a result of which the flux passing through the compensation coil is affected.

The object of the invention is therefore to provide an electromagnetic actuating device in which the actuating element is held by a cyclically changing magnetic flux density and is then released or triggered by a compensation coil when the flux density passing through the compensation coils is at a low value. In particular, the compensation coil is to be arranged in a magnetic circuit in such a way that the opposing magnetomotive force lies in series and in phase with the magnetomotive force which is generated by the current pulse at the time the actuating element is triggered.

In particular, the new actuation device is to be equipped with a permanent magnet which is arranged movably with respect to the magnetic core and which generates a cyclically changing flux density at the point at which the actuation element is held by the magnetic attraction force and at which the excitation of the compensation coil is timed to coincide with the time when the flux density at the actuator and the compensation coil is at a low value.

This object on which the invention is based is achieved by a magnetic core structure which has a first and a second pair of poles, the one pair of poles being used to hold a spring-loaded actuating element in a tensioned position and the other pair of poles in the immediate vicinity of a permanent magnet carrying out a relative movement lies, which thus generates a cyclically changing flux density in the first pole pair that holds the actuating element. The magnetic core has a center leg on which a compensation coil is wound, which can be selectively excited when the flux density is at a low value, whereby the holding flux for the actuating element is further reduced, so that it can detach from the pole faces. The permanent magnet can either move back and forth or change to change the air gap and thus cyclically change the magnetic resistance between the permanent magnet and the core to generate a cyclically changing flux density on the pole faces of the pole pair that hold the actuating element. The compensation coil is activated in such a way that it is excited when the magnetic resistance has approximately reached its highest value, so that the compensation coil is therefore always excited when the flux density is at its lowest.

The invention will now be described in more detail with reference to exemplary embodiments in conjunction with the accompanying drawings.

• Fig. 1 schematisch eine magnetische Betätigungsvorrichtung gemäß der Erfindung,
• Fig. 2a,b
• und c den Verlauf der magnetischen Flußdichte, des Auslösestroms und des Arbeitshubs der Vorrichtung in Figur 1 und
• Fig. 3 schematisch eine weitere Ausführungsform der in Fig. 1 dargestellten Betätigungsvorrichtung, bei der ein rotierender Magnet zur Erzeugung der Änderungen in der Flußdichte verwendet wird.

In the drawings:

• 1 schematically shows a magnetic actuation device according to the invention,
• 2a, b
• and c the course of the magnetic flux density, the tripping current and the working stroke of the device in FIGS. 1 and
• Fig. 3 schematically shows another embodiment of the actuator shown in Fig. 1, in which a rotating magnet is used to generate the changes in flux density.

The magnetic actuation device according to the invention consists of a core 10, and an armature or actuation element 11, a reciprocating permanent magnet 12 and a compensation coil 13. The core 10 is made of a magnetically permeable material and has a first pair of poles 14, 15 second pole pair 16, 17 and a middle leg 18. The actuating element 11 is preferably made of magnetically permeable material and can consist, for example, of spring steel, although this is not absolutely necessary. The actuating element must in any case have a magnetically permeable plate 20 which can be attracted by the pole faces of the pole pair 14, 15. The actuating element 11 is clamped at its lower end and either shaped or arranged in such a way that it is biased relative to a rest position shown in broken lines. In the drawing the actuator 11 carries a print hammer 21 for use in a printer.

The permanent magnet 12 is U-shaped and has two pole faces 24, 25, which correspond to and oppose the pole pair 16, 17 of the magnetic core 10, and is slidably arranged on a pair of rails 26 for a reciprocating movement with respect to the magnetic core . The permanent magnet 12 can be moved approximately in the manner shown by a push rod 27, which is articulated eccentrically on a rotating disc, which in turn is fastened on a shaft 29 which can be driven by a motor (not shown). The shaft 29 also carries a disk 30 provided with slits 31, the slits 31 being sensed, for example, by a photodetector 32. This photodetector supplies a gate switching signal to a control circuit 33 which, in conjunction with a trigger command, causes the compensation coil 13 to be energized.

In operation, the rotation of the shaft 29 and the disk 28 mounted thereon cause the permanent magnet 12 to move back and forth with respect to the magnetic core 10. The magnetic flux passing through the magnetic core provides the attractive force for the actuating element 11 on the pole faces of the pole pair 14, 15, thereby the actuator 11 is held in the position shown in solid lines. The limit of the reciprocating movement or the greatest expansion of the air gap D between the permanent magnet and the magnetic core is determined by the flux density of the magnetic flux that is required to hold the actuating element in the position shown. The maximum allowable air gap width is that which is required to keep the actuator just in the position shown by solid lines. The smallest air gap is again the one that is required is to attract the actuator from a free-standing position. When the permanent magnet is moved back and forth, the flux density changes cyclically in the first pole pair as well as in the middle leg between a first high value 35 and a second low value 36 in FIG. 2a. If the actuating element is to be triggered, then a trigger command is supplied to the control circuit 33 to excite the compensation coil 18. This triggering command is controlled in such a way that it takes effect simultaneously with the point in time at which the magnetic flux at the pole faces of the pole pair 14, 15 opposite the actuating element 11 is at a low value. This coincidence is determined by the position of the slots 31 of the clock disk and by the photodetector 32. At this time, only a small current flowing through the compensation coil 13 is required so that the actuating element can be triggered. It is assumed that the direction of flow from the north pole of the permanent magnet runs through the middle leg 18 of the magnetic core and through the parallel flow path from pole 14, block 20 and pole 15 and from there to the south pole of the permanent magnet.

When excited, the compensation coil 13 supplies an additional magnetic flux in the same direction as the flux generated by the permanent magnet in the middle leg. However, the newly generated magnetic flux is distributed over two flux paths, one running over the south and north poles of the permanent magnet and back, while the greater part of the additional magnetic flux is directed in the opposite direction and the original flux through the first pole pair 14, 15 the actuating element is entge- gengerichtet. ¹ This creates a compensation flow in this leg, so that at point 37 (Fig. 2a) the holding flow is reduced so far that the actuating element 11 moves to the position shown in dashed lines.

It can be seen from FIG. 2 that the optimal time for the excitation of the compensation coil is at point 37, where the tripping current 38 then coincides with the lowest value of the flux density through the pole shoes of the pole pair 14, 15. This effect therefore requires the smallest compensation current for actuating the actuating element. The movement of the actuator from its biased position is shown at 39 (Fig. 2c). The current is only briefly applied to the compensation coil, so that the magnetic flux passing through the permanent magnet exerts an attractive force on the actuating element rebounding after the impact and brings it back again from the release position. Although the permanent magnet can be used to retighten the actuator, other devices such as an additional coil or a mechanical reset device can be used to reset the actuator.

The magnetic actuation device can also be constructed as shown in FIG. 3. Here, a rotating permanent magnet is used, which causes a cyclical change in the magnetic flux flowing through the actuating element that is attracted. The magnetic core 40 is shown here in a different plane than in FIG. 1, but also has a central leg 41, a first pair of poles 42, 43 and a second pair of poles 44, 45. The compensation coil 46 is in turn mounted on the central leg 41.

The actuating element 47 has a magnetically permeable block 48 which is attracted by the magnetic flux occurring at the first pole pair 42, 43 against the bias of the spring 49. The exciting magnetic flux is generated by a permanent magnet 50 which is arranged on a rotatable shaft 51 which also carries the clock disk, not shown. The permanent magnet is provided with grooves 52 and changes the density during its rotation of the magnetic flux passing through the core, the pole faces and thus also the middle leg and the pole faces holding the actuating element. The compensation winding can be excited in connection with the clock arrangement in FIG. 1 and releases the actuating element at the time of the lowest flux density. As a result, the compensation coil can be driven with a relatively low current.

Of course, the actuating device can still be modified somewhat in terms of construction, and other arrangements for a relative movement between a permanent magnet and the magnetic core are conceivable, or additional reset windings could be provided. The various pole faces may also be coated with a non-magnetic material to prevent the relatively moving parts from sticking. In the embodiment using a rotating permanent magnet, a plurality of magnets can also be used.

Claims (4)

1. Electromagnetic actuator with a magnetic core with a first pair of pole pieces, in which a magnetic flux is generated with the help of a permanent magnet, which holds a cantilevered, spring-loaded armature as an actuating element, and with a mounted on a cross leg to trigger the actuating element controllable compensation coil,
characterized, that the magnetic core (10) has a second pair of poles (16, 17), which are opposed by the two poles (24, 25) of the permanent magnet, forming an air gap (D), that for the cyclical change in the size of the air gap and thus the magnetic resistance in this flow path, the permanent magnet (12; 50, 52) can be moved cyclically relative to the magnetic core, as a result of which the magnetic flux passing through the magnetic core (10) cyclically between a first higher and a second lower value fluctuates, but both are sufficient to keep the actuating element (11, 47) on the first pole pair (14, 15; 42, 43), and that to trigger the actuating element, the compensation coil (13, 46) can be controlled at the time of the lower value of the magnetic flux. 2. Device according to claim 1, characterized in that the permanent magnet (12) by a drive device (26, 27, 28) is cyclically movable back and forth. 3. Device according to claim 1, characterized in that the permanent magnet (50, 51) between the pole shoes of the second pole pair (44, 45) is rotatably arranged. 4. The device according to claim 1, characterized in that a clock pulse generator (30, 31, 32) is coupled to the drive device, and so that the compensation coil (13, 46) can be briefly controlled in the presence of a trigger command at the time of the minimum of the magnetic flux is.

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