DE4209757C1 - Operating magnet for EM switch, e.g. for motor protection - has two=part outer yoke fitted to coil carrier - Google Patents

Abstract

The switch operating magnet has an armature (11) contained in a bore of a coil former and displaced along a switch axis relative to an inner two-part yoke and an outer two-part yoke. The latter comprises two identical U-shaped parts (10A,10B) with curved notches (106A,106B) for receiving a magnetic sleeve (12) enclosing the armature (11). The centre of curvature (M) of each notch (106A,106B) is rotated by an angle of less than 90 degrees relative to the 2 perpendicular centre planes (X,Y) extending through the switch axis (Z). Both parts (10A,10B) of the outer yoke lie parallel to the assembly direction (F) for fitting to the coil former, at their sides. ADVANTAGES - Simple assembly and subsequent disassembly. Form-fitting of yoke to socket ensuring bridging of magnetic flux without having to pass any air gap.

Description

The invention relates to an electromagnetic switching device a switching magnet, in which a plunger anchor in a hole of a bobbin carrying a winding along one Switch axis is movable and between an inner yoke that composed of two equal parts and the winding is adjacent, and an outer yoke, which is made of two of the same U-shaped angled parts to form a closed frame is composed of permanent magnets that are between the inner and outer yokes are arranged, the inner and outer yoke for the implementation of the diving anchor recesses in the area of dividing joints formed by the composite yoke parts have and one side of a magnetic socket in the bore of the bobbin and in on one side of the outer Yoke parts are used as semicircular recesses, through which the plunger can also be moved.

An electromagnetic switching device with a switching magnet the generic type is for example from the DE 39 08 319 A1 known.

Magnetic drives are used in remote-controlled switching devices, such as Protect, used for example for switching motors.

The two yoke parts forming the outer yoke, however, are made of two parts that are identical to each other are used during assembly usually along an axis from the right or left in the Inserted bobbin. Then they have to be mechanically like this  be connected that the yokes in normal switching operation Form-fit on the inside of the socket. The air gap between the yoke parts and the socket because of the transition of the magnetic flux should be as zero as possible. Furthermore should the switching magnet during assembly during assembly hold together as a unit. A previously practiced option the mechanical connection of the outer yoke parts in that they are caulked together. Here can however, due to the large forces involved in caulking, deform the socket, and there is the disadvantage that the Thereafter, the switching magnet can no longer be dismantled.

The invention is based, with permanent magnets the task supported magnetic drives with an outer split yoke and an inner split yoke a simple mechanical Connection of the outer yoke parts to create a simple Assembly and disassembly, also a subsequent assembly of the Anchor allows, with a positive connection of the yokes to the socket while avoiding an air gap for one perfect transition of the magnetic flux can be achieved should. This task is done with a generic Switching magnets by training according to the characteristic Features of claim 1 achieved.

The invention solves the problem of mechanical Connection of the outer yoke parts so by forming one Undercut of the outer yoke parts in assembly or Dismantling direction for positive locking around the socket. Hereby the yoke parts are automatically in the assembled position held. However, a prerequisite is lateral support in the Bobbin, d. H. appropriate guidance and support. The inventive design of the outer yoke parts for enables a mechanical connection by positive locking regardless of the extent and design of the backhandedness Assembly sequence in such a way that the yoke parts in the The bobbin is inserted and positioned and the Socket is mounted. The yokes are centered in the bobbin by inserting the bushing.  

The rear grip of the outer yoke parts for grasping the Socket in the mounting direction is achieved in that the the circular recess on both sides Subsequent dividing lines with respect to the middle planes of the outer yoke, the center of which falls in the switching axis Z, are formed mirror-symmetrically rotated by 180 °. The means that the two semicircular recesses of the outer yoke parts are assembled into a circle, however the divisions to the outer edges of the Yokes twisted through an angle with respect to the median plane are. The division joints can be axially parallel to each other be staggered. It is also possible to use any parting line still in itself, for example angled, to continue. In particular, the rear grip of the yoke parts is thereby achieved that the semicircular recesses on webs of outer yoke parts, each with respect to the Overlying the middle level by an equal amount or withdrawn are trained.

The measure of the engagement of the recesses of the outer Yoke parts are based on the assembly process. The Backlash is to be chosen so that the yoke parts on Plunger anchors are pushed past into the coil body can. When retrofitting the submersible anchor, d. H. at previous assembly of the outer yoke parts, the trained backhandedness may be greater.

With appropriate elasticity of the coil body, the Attacking can be chosen so that the yokes on the Socket can be assembled.

In a further embodiment of the invention it is proposed that at the undercut end of the semicircular Recesses the transition to the yoke part or that over the Middle plane projecting web is rounded. Is the bobbin is sufficiently flexible, resilient, so can be equipped with roundings on the recess  Yoke parts pressed onto the coil during assembly - to be clipped on. According to this proposal of the invention an assembly sequence in such a way that the socket is pre-assembled and finally the yokes over the compliant bobbin are snapped.

To ensure that the yoke parts always fit into the socket To achieve, it is intended to drill the hole in the coil body larger than the diameter of the semicircle of the recesses to form outer yoke parts. This can make the springy Fit the formed beech on the yokes. The inventive design of the yoke parts enables positive connection and assembly of the yoke parts in the Coil body without the need for additional parts. Also caulking the outer yoke parts against each other is not required so that all parts after disassembly can be used because they have no deformations. Manufacturing reliability is also ensured by the form-fitting Assembly of the yoke parts increased. At the same time, it enables Disassembly of the switching magnet, so that the individual parts can be reused. As with the mechanical Fixation of the outer yoke parts by positive locking and lateral Guide in the coil body no deformations on the outer Yoke parts or parts adjacent to it occur also no change in the magnetic properties of the exterior Yokes.

The invention is illustrated below in the drawing explained.

Show it

Fig. 1 shows two outer yoke members for an outer yoke in a perspective view;

Fig. 2, 3, 4 the solenoid in a schematic bottom view, side view and plan view with the outer yoke,

Fig. 5 shows the view in part of FIG. 2 to the outer yoke members with inserted bushing in an enlarged scale;

Fig. 6 is an exploded perspective view of components of the switching magnet with the yoke parts,

Fig. 7 is a schematic representation of a further possible joint division of the outer yokes in the view according to Fig. 2,

Fig. 8 is a schematic representation of a joint division with rounded portions for snapping the yoke parts onto the coil former.

In FIG. 6 is a switching magnet as a permanent magnet supported drive exploded perspective view of its essential parts, namely a bobbin 16 with coil terminals and winding 13, each two inner yoke members 14 A and 14 B, the permanent magnet 15 A and 15 B, the outer yoke members 10 A and 10 B and a submersible anchor 11 or its anchor piston and a socket 12 , shown. The armature 11 is moved through the axial through bore 17 of a coil former 16 . The bushing 12 is inserted into the bore 17 on the side of the coil former 16 from which the armature 11 can be brought out during switching. On the other hand, the anchor 11 is guided in the anchor plate 30 with adhesive plate 31 , if necessary.

In Fig. 1, the outer yoke parts 10 A, 10 B, which are of identical design and which are joined together to form the outer yoke 10 , see FIG. 3, are shown in perspective. Each outer yoke part 10 A, 10 B has a U-shaped angled shape with a central part 101 A or 101 B and side legs 102 A or 102 B and 103 A or 103 B. At the leg ends to the center plane Y of the outer yoke parts 10 A, 10 B recesses 105 A and 105 B, 106 A and 106 B are formed for the implementation of the plunger anchor 11 and its mobility. On one side of the yoke parts 10 A, 10 B, the recesses 105 A, 105 B are arranged centrally to the axis Z of the armature 11 and symmetrically to the center planes X and Y of the yoke 10 . On the opposite side of the yoke parts 10 A, 10 B, the legs 102 A, 102 B are formed at the ends with a semicircular recess 106 A, 106 B. The center point M of the semicircles also lies on the central planes X, Y and the switching axis Z. However, the semicircular recess 106 A or 106 B is rotated about the axis Z, so that at the leg end 102 A or 102 B on one side of the recess 106 A or 106 B protrudes a web 108 A or 108 B over the X plane, by the amount d. The remaining web 107 A or 107 B of the leg 102 A or 102 B opposite to the central plane X is withdrawn by the same amount d.

The two identical yoke parts 10 A, 10 B are then brought together as shown in FIGS. 2, 3, 4. On the underside of the outer yoke 10 shown in FIG. 2, the dividing joint 21 runs between the two outer yoke parts 10 A, 10 B outside the central planes X, Y, the intersecting line of which runs through the center M of the recess 106 and the bush 12 and coincides with the switching axis Z. The dividing joint 21 is in this case rotated about the switching axis Z in the same extent upon rotation of 180 °. The recess 106 is formed by the semicircular recesses 106 A, 106 B of the outer yoke parts 10 A, 10 B.

On the top of the yoke 10 (see FIG. 4), the dividing joint 22 runs between the two yoke parts 10 A, 10 B in the central plane X and symmetrically to the central plane Y. In FIG. 3, the assignment of the outer yoke 10 is shown schematically in a side view Shown with the yoke parts 10 A, 10 B to the coil 13 inserted in the center of the switching axis Z and the plunger armature 11 and the socket 12 inserted into the coil 13 and the outer yoke 10 on one side.

In FIG. 5 is represented by the asymmetrical design of an end of the outer yoke members 10 A, 10 B recoverable form-locking connection with the sleeve 12 in the bottom view of FIG. 2 is shown enlarged. By displacing the dividing joints 21 A, 21 B of the outer yoke parts 10 A, 10 B outside the central planes X, Y, an engagement of the yoke parts 10 A, 10 B with in the assembly or disassembly direction F (perpendicular to the X plane) reached their recesses 106 A, 106 B with respect to the socket 12 to be inserted therein. As a result, the yoke parts 10 A, 10 B are automatically held in position after assembly, the lateral support in the coil former 16 being necessary for the non-removal. The lateral parallel guidance to the center plane Y, in which the mounting direction Z lies, is achieved by appropriately designing the coil former 16 in an area 16 A (see FIG. 6). In this area 16 A, the coil body 16 has flange-like projections for the coil connections with lateral guide walls, into which the outer yoke parts 10 A, 10 B with their legs 102 A, 102 B are inserted and held. The usual assembly sequence is that first the inner and outer yoke parts 10 A, 10 B, 14 A, 14 B and the permanent magnets 15 A, 15 B are mounted on the bobbin 16 , and then the socket 12 is inserted, whereby the Yokes 10 , 14 with the bushing 12 are centered in the coil body 16 . The armature 11 can be mounted in advance, so that the yoke parts 10 A, 10 B, 14 A, 14 B can be inserted past the armature 11 into the coil body 16 . It is also possible to retrofit the anchor 11 . The outer dimensions of the bushing 12 and the dimensions of the semicircular recesses 106 A, 106 B of the outer yoke parts 10 A, 10 B are to be selected such that the bushing 12 is always form-fitting on the outer yoke parts 10 A, 10 B in the recesses 106 A, 106 B is present.

From FIG. 7 it can be seen that the dividing joints 21 A, 21 B of the outer yoke 10 in the region of the circular recess 106 (see FIG. 2) for inserting the bushing 12 also have a course different from that shown in FIG. 5 can.

In FIG. 8, as a modification of FIG. 5, the engagement of the recesses 106 A, 106 B of the outer yoke parts 10 A, 10 B at their ends 40 , 41 is in transition to the web of the outer yoke parts 10 A projecting beyond the central plane X. , 10 B shown rounded. This makes it possible to snap the yoke parts onto the coil body with the preassembled bushing, the coil body having to be approximately elastic in order to yield accordingly. For the lateral guiding and conditioning of the outer yoke members 10 A, 10 B on the bobbin 16 elevations or projections 161, 162 formed to effect a secure system.

Claims (6)

1. Switching magnet for an electromagnetic switching device, in which a plunger armature is movable in a bore of a coil body carrying a winding along a switching axis and between an inner yoke composed of two identical parts, which is adjacent to the winding, and an outer, made of two identical U -shaped angled parts are arranged to form a closed frame, permanent magnets and inner and outer yokes for the implementation of the plunger have recesses in the area of the dividing joints formed by the assembled yoke parts and one side a magnetic socket in the bore of the coil former and in one side of the outer yoke parts is used as a semicircle formed recesses through which the plunger is also movable, characterized in that on the outer yoke parts ( 10 A, 10 B) the recesses ( 106 A, 106 B) designed for receiving the socket ( 12 ) ) with your The center of the circle (M) in the switching axis (Z) is rotated by an angle of less than 90 ° with respect to the center planes (X, Y) of the outer yoke ( 10 ) running through the switching axis (Z), so that in relation to the center planes (X , Y), one of which is directed perpendicular to the assembly and disassembly direction (F), recesses ( 106 A, 106 B) which are undercut on one side and the outer yoke parts ( 10 A, 10 B) by means of the recess formed by them ( 106 ) positioned bushing ( 12 ) are supported, the outer yoke parts ( 10 A, 10 B) are laterally supported axially parallel to the mounting direction (F) on the coil body ( 16 ). 2. Switching magnet according to claim 1, characterized in that the adjoining the circular recess ( 106 ) dividing joints ( 21 A, 21 B) of the outer from the assembled yoke parts ( 10 A, 10 B) formed yoke ( 10 ) with respect to the Center planes (X, Y) of the outer yoke ( 10 ) are mirror-symmetrical and rotated by 180 °. 3. Switching magnet according to claim 1, characterized in that the outer yoke parts ( 10 A, 10 B) by means of the inserted bushing ( 12 ) in the coil body ( 16 ) centered and held by the coil body and bush. 4. Switching magnet according to one of claims 1 to 3, characterized in that the diameter of the bore ( 17 ) in the coil body ( 16 ) larger than the diameter of the semicircles of the recesses ( 106 A, 106 B) of the outer yoke parts ( 10 A, 10 B) is. 5. Switching magnet according to one of claims 1 to 4, characterized in that the semicircular recesses ( 106 A, 106 B) on webs ( 107 A, 108 A; 107 B, 108 B) of the outer yoke parts ( 10 A, 10 B) ends, which are formed with respect to the central plane H by an equal amount d protruding or withdrawn. 6. Switching magnet according to one of claims 1 to 5, characterized in that at the undercut end ( 40 , 41 ) of the semicircular recesses ( 106 A, 106 B) the transition to the yoke part or the web projecting above the central plane X ( 108 A , 108 B) is rounded.