DE1035771B - Actuating electromagnet, especially for direct current, with automatic locking of the armature - Google Patents

Description

Actuating electromagnet, in particular for direct current, with automatic locking of the armature The invention relates to an actuating electromagnet, in particular for direct current, with automatic locking of the armature or the tie rod connected to it in the tightened position by a locking device and with simultaneous interruption of the circuit feeding the magnetic coil according to the patent 960562. According to this main patent, the tie rod is locked by means of balls, which are pushed into the recesses of the tie rod by turning a correspondingly designed ring. This type of locking has the disadvantage of being position-dependent.

Ball catches are also known in electromagnets, which in contrast to magnets designed according to the main patent are position-independent, However, when the locking position is reached, there is no automatic interruption of the carry out the current flow feeding the solenoid coils, which after locking has been carried out is no longer required. Position-independent rotary and lever switches are also known, which are held in the switched-on position when a magnet is weakly attracted. In these known devices, however, the armature of the magnet remains only so long in the attracted position, when a certain current flow is present in the magnet.

The aim of the invention is to provide a position-independent direct current actuating magnet with automatic locking of the anchor and simultaneous interruption of the to create the magnetic coil feeding circuit. This is done according to the invention achieved in that a displaceable in the direction of the tie rod axis, the tie rod ring-shaped surrounding locking device is provided, which consists of at least consists of two concentric ring parts, the between them and the pull rod or the locking body on at least one surface inclined to the axial direction of the ring parts under compressive stress and hold that slide when passing a locking groove located in the tie rod or the locking body into this groove from the inclined surface or the one acting in the radial direction Compressive force component are pushed in, and that: one on the inclined surface one of the ring parts of the locking device adjoining the tie rod surface parallel surface the or the locking body in the radial direction on re-emergence from the groove.

In preferred embodiments, the locking device actuated by a spring and / or by an auxiliary magnet which, if necessary for unlocking and also for temporarily parking the given by the spring Automatic locking can serve. There are several blocking bodies used, which may have a spherical or a cylindrical shape. in the the latter case, the roller-shaped locking body can be tangential or radial to Be arranged tie rod.

The blocking bodies are preferably located in chambers, the walls of which in the axial direction of the tie rod from the ring parts of the locking device, in the peripheral direction of correspondingly arranged connecting webs between these ring parts and in the radial direction on the one hand by the tie rod itself and on the other hand are formed by the locking body.

Several of these locking devices designed according to the invention can be used with recesses arranged at different points on the pull rod and with a or several auxiliary magnets cooperate in such a way that one or more automatic Locks of the drawbar on one or more parts of the stroke occur.

The position independence of the magnets is contrary to the main patent achieved by moving the locking element in the direction of the pull rod, and that the lock can be either at, depending on the position of the inclined surface the back or forth movement of the with this Area provided annular locking body made.

Instead of an annular locking device with several Locking bodies can of course also have a different locking device with only one locking bodies engaging in the pull rod are provided, the locking device in this case need not have an annular shape.

According to a further embodiment, the pull rod has several recesses, whereby the total stroke z. B. can be covered in several sections. the Recesses can be either recesses or holes. With another Embodiment are the recesses while avoiding a reduction in cross section the pull rod by pulling pipe sections onto the pull rod. These Pipe pieces either have slots or bores themselves or they form between them slits.

The automatic locking device can be used for both simple as well as with double magnets.

Four exemplary embodiments of the invention are shown in the drawing.

1 and 2 are longitudinal sections through two locking devices which are identical per se for actuating magnets, half of which are locked, the other half are shown in the unlocked position and are only in the direction of movement distinguish the locking elements during the locking process; Fig.3 is a Another embodiment of the locking device in the same manner of representation; 4 is a longitudinal section through a double magnet with a locking device according to the invention; Fig.5 is a broken longitudinal section through the Pull rod according to Fig. 4 with locking balls.

The automatic locking device of FIG. 1 consists of the recess 3 in the pull rod 1, which receives the balls 4 in the locking position of the pull rod designated by 2. The locking ring 5, which is stepped in its bore 9 by an insert ring 24 with an inclined surface 11, is also the armature of the auxiliary magnet 6. The balls 4 are located between the annular projection 8 of the core of the auxiliary magnet 6 and the ring 7, which is also connected to the magnetic core connected is. Both rings 7 and 8 surround the tie rod with play. Before locking, the balls 4 are located between the pull rod 1 and the cylindrical bore surface 9 of the ring 5. In the locking position, the balls are located between the recess 3 and the protruding inner surface 10 of the insert ring 24.

The locking process works as follows. The spring 12 seeks the anchor or to lift the ring 5 from the core of the auxiliary magnet 6. However, the ring 5 is through the balls 4 prevented from lifting because the upper inclined surface 11 of the insert ring 24 rests against the balls. The pull rod is now activated by actuating the main magnet advanced, the balls 4 are pushed by the radially directed pressure component pressed into the recess 3 and thereby locks the pull rod. The unlocking takes place by switching on the circuit in the auxiliary magnet 6. This causes the Armature 5 is tightened and the balls 4 are released. These are then used by the Pull rod pushed aside so that they slide back into the starting position.

In the example of FIG. 2, the ring 13 is designed such that its formed on an insert ring inclined step surface 14 opposite to that in the Example of FIG. 1 corresponding surface 11 is directed. The locking process is in progress modified here accordingly. The auxiliary magnet already flows through the locking mechanism 6 current, so that the armature or ring 13 is subjected to a tightening force. The anchor or ring 13 can not follow this tensile moment because the balls 4 it prevent. Only after the pull rod has lifted and the balls 4 have moved into the Turning 3 can the armature or ring 13 with compression of the spring 12 the Perform locking movement. Unlocking takes place by switching off the power, after which the compressed spring 12 takes effect and the armature 13 in the starting position drives back. The balls 4 slide out of the recess 3, and the pull rod goes back to the starting position.

In the embodiment according to FIG. 3, the locking ring is designed as a movable cap 15 which engages over the end of the pull rod 2. An auxiliary magnet is missing here. The unlocking takes place mechanically by axial pressure on the cover 16 of the cap 15. The further process corresponds to that according to the examples in FIG. 1 or 2.

The exemplary embodiment according to FIG. 4 shows a double magnet, the pull rod 17 of which has a plurality of drawn-up pipe pieces 18 , between which the annular grooves 19 are formed. The unlocking takes place by briefly switching on the auxiliary magnet 20. As a result, the ring 21 is attracted as an anchor, and the balls 22 are released. The ring 21 is immediately released from the core of the auxiliary magnet 20 by the spring action, and the pull rod 17 can be locked again in the next annular groove 19 as it continues to move. In this way, the stroke of the armature 23 can be carried out in sections. If several stroke sections are to be passed through at the same time, this can be achieved by means of an electrical control of the auxiliary magnet. If locking is to take place on the way back, the other end 24 of the pull rod must be provided with a corresponding locking device.

If two of the three pipe sections 18 are omitted on the pull rod after Fig. 5, e.g. B. the lower two results in place of the upper slot 19 a locking stage, which as such is only effective in one direction.

The examples shown in the figures are not restrictive of the subject matter of the application to these embodiments. By combining various locking bodies and locking elements with magnetic and mechanical Locking operations as well as with electrical control gears it is possible to do a multitude of of variations of locking magnets for different purposes.

Claims (1)

PATENT CLAIMS: 1. Actuating electromagnet, especially for direct current, with automatic locking of the armature or the tie rod connected to it in the tightened position by a locking device and with simultaneous interruption of the circuit feeding the magnet coil according to patent 960562, characterized in that one in the direction of the tie rod axis Slidable, the pull rod ring-shaped surrounding locking device is provided, which consists of at least two concentric ring parts that lead and hold the locking body or the locking body on at least one inclined to the axial direction of the surface of one of the ring parts under compressive stress between them and the pull rod so that when sliding past one in the pull rod located locking groove or the locking body are pushed into this groove by the inclined surface or the pressure force component acting in the radial direction, and that one of the inclined surface of one of the ring parts de The surface parallel to the surface of the tie rod connected to the locking device prevents the locking body (s) from emerging again from the groove in the radial direction. z. Actuating magnet according to Claim 1, characterized in that the locking device is actuated by a spring and / or by an auxiliary magnet which can optionally be used to unlock and also temporarily switch off the automatic locking mechanism provided by the spring. 3. Actuating magnet according to claims 1 and 2, characterized in that several locking devices with recesses arranged at different points on the pull rod and with one or more auxiliary magnets cooperate in such a way that one or more automatic locks take place on one or more arbitrary parts of the stroke. 4. actuating magnet according to claim 1, characterized in that the locking body z. B. are designed as balls or as cylindrical rollers. 5. Actuating magnet according to claims 1 and 4, characterized in that the locking bodies are limitedly movable in chambers, the walls of which in the axial direction of the pull rod from the ring parts of the locking device serving to guide them, in the peripheral direction of correspondingly arranged connecting webs between these ring parts and are formed in the radial direction on the one hand by the pull rod itself and on the other hand by the locking body. 6. Actuating magnet according to one or more of claims 1 to 5, characterized in that the pull rod has several recesses so that the total stroke can be covered in several sections. 7. Actuating magnet according to one or more of claims 1 to 6, characterized in that the recesses of the pull rod are recesses or bores. B. actuating magnet according to one or more of claims 1 to 7, characterized in that the recesses of the pull rod are formed by one or more drawn pipe pieces which either themselves contain corresponding bores or transverse slots or form one or more slots with one another, or that when using a single drawn-up pipe section, the edge of which with the pull rod only forms a locking step for the locking body instead of a locking slot. 9. Actuating magnet according to one or more of claims 1 to 8, characterized in that the automatic locking device is arranged on single or double magnets. Considered publications: German Patent Nos. 441 715, 472 065, 531497, 632371; German patent application I \ 2 8656 VIII c / 21 g (published on June 18, 1953); U.S. Patent No. 2,446,855.