DE2350914B2 - Electromagnetic contactor - Google Patents

Description

45

The invention relates to an electromagnetic contactor with a housing that surrounds it fixed magnetic core with an exciter arrangement placed on it and one with the magnet armature connected to the contact bridge carrier, which in its tightening position against the force of two wire springs arranged on both sides is movable, which are fixedly supported and a negative one Have their armature return force characteristic.

In the case of the shooters of the aforementioned type known from US Pat in the rest position of the armature relaxed wire springs are each approximately L-shaped and provided with a respective spiral in the transition between the two legs of unequal length, the further have a respective bend at their respective free end, over which the wire springs by means special spring clips on the armature or articulated on the surrounding housing via special support bodies are that they in the movement of the armature relative to the core in the manner of a respective toggle lever works. Especially because of the spring clips and used to fix the wire springs These known contactors are quite difficult to assemble, and there is also that just these components in conjunction with the specially shaped wire springs achieved toggle action greater instabilities in the operation of the contactor and thus easy to Cause operational disruptions.

Furthermore, from "Motor Control Equipment Catalog", edition 1968/69, pages 4 and 5, article no. DIL 4 (a) to 22 electromagnetic contactors of the type also shown in FIG. 1 of the drawing are known, in which for extensive clearance precisely such instabilities the armature 19 connected to the contact bridge carrier 1 is guided by two lateral pairs of rods 42 on the surrounding housing or on a special support structure 40. One ends of the two guide rods 42 of each pair are articulated to form a common support pin 43 for the associated side of the contact bridge carrier 1, while the other ends are arranged to be axially movable in a respective mounting piece 41. One end of a respective spiral spring 44 is supported on these mounting pieces 41, which with a respective pivot pin in a guide groove of the support structure 40 that is parallel to the direction of movement of the contact bridge carrier and thus the armature 19, is supported to pretension the two support pins 43 and thus the contact bridge carrier 1 in pairs in a direction A, which is opposite to the direction of movement of the armature when it is moved into the tightening position on the core. With these contactors, too, a negative characteristic curve of the armature return force is implemented, which, however, still requires quite a lot of installation effort and cannot be maintained unchanged over longer operating times of the contactor because of the still numerous components.

Such a negative characteristic of the armature return force is under for electromagnetic contactors Desirable from the point of view that this results in a reduced overall spring force. So it is on the other hand possible to increase the contact pressure by an amount essentially that of the Transfer of the anchor from its rest position to the tightening position, progressive reduction of this Armature feedback force corresponds, which on the other hand means that the switching capacity or the number of switching cycles such a contactor can be selected to be correspondingly larger. Furthermore, one such is negative Characteristic curve of the armature return force is advantageous in that it is necessary for the closing of the contacts during the last movement phase and for opening it during the initial movement phase there is no delay in the movement of the armature, even if the excitation voltage falls off.

The invention is based on the object of the electromagnetic contactors of the aforementioned Art to be further developed in such a way that, with a simplified installation option, the negative characteristic curve of the armature feedback force Can be maintained undisturbed over longer periods of operation.

According to the invention, this object is achieved in that in such an electromagnetic

Protect the two wire springs are essentially C-shaped and with their two respective ones Ends from two sides into lateral plug-in holes of the anchor arranged between the wire springs or of the contact bridge carrier are inserted or supported on lateral projections of the same and in such a way over the respective middle Federabsdinitt in a respective groove-shaped recess or on one respective projection of the housing or the bobbin of the excitation coil are supported that Both springs are aligned at an angle to the direction of movement of the armature during the entire armature stroke are.

There is thus a contactor provided the easiest because of the simple design of the two wire springs to ¹ S way can be mounted, so that correspondingly short production times are incurred. Due to the simple design of the wire springs and their special arrangement, a reduced susceptibility to failure is obtained, for which the fairly stable support of the armature by the wire springs is decisive, which distribute the support to four separate points while avoiding special holding means.

Further advantageous developments of the invention ^a 5 are covered in the subclaims. The exemplary embodiments described in more detail below are shown schematically in the drawing. It shows

1 shows the exploded perspective view of a known one, already described in the introduction Arrangement with spiral springs for constant pre-tensioning of the armature of an electromagnetic one Contactor of the present genre,

2A shows an exploded view of an electromagnetic contactor according to a first embodiment the invention,

Fig. 2B shows a partially enlarged scale sectional side view of the contactor according to FIG. 2A,

FIG. 2C shows a cross section of this contactor along the line YY in FIG. 2B,

Fig. 3A in an exploded perspective view of the contactor according to the invention according to a further execution form,

3B shows a partially enlarged scale sectional side view of the contactor according to FIG. 3A,

4 shows a partially sectioned side view of a contactor according to a further embodiment the invention,

Fig. 5 A in an exploded perspective view another alternative of the contactor according to the invention,

Figure 5B is a detail of that shown in Figure 5A Contactor,

6 shows a plan view of the contactor according to a further embodiment of the invention,

7A to 7C show various diagrams for clarification the operation of the contactor according to the invention and

7D shows the diagram corresponding to FIG. 7C for a contactor of known embodiment.

The electromagnetic contactor according to FIGS. 2A to 2C consists of an outer protective housing, the two parts of which are molded parts A and also made of synthetic resin. In a cavity of the upper housing part A there is arranged a contact bridge carrier 1 which is displaceable in the vertical direction and which is integrally connected to an actuating button 2. The actuating button 2 is arranged in a through hole 3 and protrudes beyond the upper housing part A when the contactor is assembled. The same has several partition walls 4, between which three different types of contact pieces 5, 6 and 7 are arranged, which in cooperation with corresponding contact pieces on the contact bridge carrier 1 result in the opening and closing contacts of the contactor. On the side walls of the upper housing part A , pedestals 8 for attaching a contact piece 5 by means of a respective screw terminal 9 and pedestals 10 for attaching a contact piece 6 by means of a respective screw terminal 11 are formed at one point at the top. The contact pieces 5 are parts of the normally open contacts, while the contact pieces 6 are parts of the normally open contacts. In the other departments of the upper housing part / 4sindnui lower pedestals 13 for fastening a contact piece 7 together with a fitting 12 medium; of a respective screw terminal 14. The contact pieces 7 are also parts of opening contacts.

The contact bridge carrier 1 is provided with a number of openings 15 lying parallel to one another, corresponding to the number of compartments of the upper housing part A , in which two different types of contact pieces 16 and 1 * are arranged. These contact pieces 16, 17, which interact with the contact pieces 5, (and 7, are supported in an elastically resilient manner by a respective spring 37 and 38, respectively which are symmetrical to the bridge carrier in the middle on the two sides of the Kontaktbrückenträ gers. A magnet armature 19 is attached to the Kontaktbrückenträgei by means of a pin 20, which is arranged in aligned holes 21, 21 'de; the contact bridge carrier and the armature.

In the lower housing part B an excitation coil 22 and a magnetic core 23 are arranged. The one held together by plug-in screws 24! Housing parts A and B have a mutually coordinated shape that when tightened screws 24 of the bobbin 25 of the coil 22 by the upper housing part A against the bottom of the lower housing part B is braced. In the two side walls 26 of the lower housing part B , groove-shaped recesses 27 'are formed, in which, when the contactor is assembled, wire springs 18, 18' with their central section 29 29 'sit.

The two C-shaped wire springs 18, 18 'replace zendieinFig. 1 shown arrangement with spiral spring! and guide rods. So that they result in a constantly effective feedback force with a negative characteristic curve on the armature, i.e. an armature return force ^{that gradually decreases during the movement of the armature 1 (} in its tightening position on the core 23, the condition must be met that the point of attack the wire springs on the contact bridge carrier 1 is constantly higher than the support in the groove-shaped recesses 27 'of the lower housing part B. During the movement of the armature 19 au

the wire springs 18, 18 'must therefore constantly be in its rest position in its tightening position and back be aligned obliquely upwards, as shown in the partially sectioned side view according to FIG. 2B is shown.

The embodiment of a contactor shown in FIG. 3 differs from that described above Embodiment only in that here the two C-shaped wire springs 18, 18 'with their middle Section 29, 29 'are supported on a respective projection 30, 30' of the winding body 25 of the coil 22. So that an armature return force with a negative characteristic is also obtained here, the corresponding Plug-in openings 28, 28 'for the ends of the two wire springs 18, 18' compared to the one described above Embodiment further offset to the outside, so that instead of an oblique upward and inward aligned arrangement results in an obliquely upward and outward arrangement. The same is in particular can be seen from the partially sectioned side view according to FIG. 3B.

In the further embodiment according to FIG. 4, there is also one which is oriented obliquely upwards and inwards Arrangement of the two wire springs 18, 18 'before. The ends of the same are not here, however inserted into corresponding plug-in openings of the contact bridge carrier, rather they attack angular ones Projections 31, which are attached to the respectively assigned end face of the contact bridge carrier are molded.

The embodiment of a contactor shown in FIG. 5 differs from the one described above Embodiments with other equality only in that here the outer protective housing with the two Housing parts 32 and 33 has a vertical parting plane, that is to say a parting plane which is aligned in the same way is like the direction of movement of the anchor. In the other Ausfühningsformen is the parting plane of the outer protective housing aligned transversely to the direction of movement of the armature. The two C-shaped wire springs 18 are also here with their respective ends in plug-in openings 35 of the contact bridge carrier 1 inserted, while its middle section on projections 34 of the associated housing part 32 or 33 is supported, there on both sides of an opening each serving as an assembly aid 36 are formed. When assembling a contactor this training, the two wire springs 18 only after the two housing parts 32, 33 have been screwed together from the solid shown in FIG. 5B Lines shown position brought into the dash-dotted position, in which its middle section to the Projections 34 of the respectively assigned housing part rests. To get the wire springs in this position too only need to insert a screwdriver through the relevant opening 36 and then together with the spring are moved upwards until the middle section of the spring has the relevant projections 34 reaches behind.

In the embodiment shown in FIG. 6, the groove-shaped recesses 27 'are for support of the middle section 29, 29 'of the two C-shaped wire springs 18, 18' compared to that in FIG. 2 embodiment shown designed so that when the armature 19 moves into its tightening position at the core 23 also results in a slight rotation about a vertical axis. Through this additional Rotational movement, the impact of the armature on the core is softened and at the same time a Obtain self-cleaning effect of the contact pieces. This additional rotational movement of the armature during its Transfer to the tightening position on the core

S can of course also in the embodiments according to FIGS. 3, 4 and 5 by appropriate adaptation the respective supports are realized.

In Figs. 7A and 7B it is also shown schematically that in all the above-described embodiments of the contactor according to the invention, the wire springs 18, 18 'acting on the armature 19 are constantly oriented obliquely to its direction of movement, so that even in the tightening position of the armature there is still one in it The return force of the magnitude 2 F = 2 · P- sin α, which biases it into its rest position, acts. Here, α is the angle that is formed between the connecting line between the two support points A and B or A ' and B' of each of the two wire springs 18 and 18 'and the connecting line between the one support points A and A' of both wire springs. This angle always has a value greater than zero, so that in the rest position of the armature 19 the aforementioned return force has the value IF − 2 · P · sin α. So if the anchor 19 from its

"5 rest position according to FIG. 7 A in its tightening position 7B is converted, then there is a progressive reduction in the through the two Wire springs 18, 18 'applied armature return force, such that in the armature tightening position a force still acts on the armature 19 which tries to push the armature away from the core 23. Such a negative characteristic curve of the armature return force results in comparison with a positive one Characteristic curve includes the advantages already described in the introduction, and the two for a more detailed explanation Figures 7C and 7D serve

In Fig. 7C, the dependency of the total spring force on the mutual distance between armature and core in a contactor is shown graphically, in which the springs acting on the armature have a negative characteristic curve of the armature return force, while Fig. 7D shows the same relationships in a contactor that The armature return force has a positive characteristic curve. In this case, the rest position of the armature at location C and the tightening position of the armature at location D are assumed, with an identical magnetic attraction force either along characteristic curve E or along characteristic curve F to prevail.

If it is initially assumed that the contact pressure Pc is the same in both cases, then as a result of the different spring characteristics for the tightening position of the armature, the relevant return force Pl for the negative spring characteristic is smaller than the return force Pl for the positive spring characteristic, so that the corresponding total spring force PTl is smaller than the corresponding total spring force PTi by the difference between these two return forces. In the case of the shooters with a negative characteristic of the armature return force, a separation force between armature and core occurs in the armature's pulling position, which is smaller by the difference between these two total spring forces PTl by PTl , so that in comparison with the contactors] with a positive characteristic of the armature feedback force closer contact between the armature and the core takes place. Everyone between the mutual

Dust or other dust that has come into contact with the surfaces Impurities that generate a humming noise, especially with the AC contactors, are therefore less critical of the same, d. left in the case of the contactors with a negative characteristic curve of the armature return force these noises are greatly reduced.

If, on the other hand, it is assumed that the same total spring force PTl or / T2 should be present in the attachment of the armature in both cases, then in the case of a shooter with a negative characteristic curve of the armature return force, the contact pressure can increase by the difference between the two return forces I. 'l and Pl can be chosen larger. It follows from this that the switching capacity or the switching cycle can be selected correspondingly larger.

If the magnetic attraction force is

borrowed the respective total spring force is sufficiently high and, for example, corresponds to the characteristic curve E , the tightening of the armature against the core is not affected. If the magnetic attraction force has a smaller value and, for example, corresponds to the characteristic curve F, this means for a contactor with a negative characteristic curve of the armature return force that the armature can no longer be attracted against the core because in its rest position there is a compared to the attraction force greater total spring force prevails. Although this occurs with a contactor with a positive characteristic curve of the armature return force, it can happen there in de! Tightening position h for the so-called bouncing blow mil

^J 5 result from heavy wear of the armature, because the total spring force is greater than the magnetic attraction force, so that the armature vibrates constantly.

For this purpose 10 sheets of drawings

Claims (3)

Patent claims: 1. Electromagnetic contactor with a magnet core fixedly arranged with respect to a surrounding housing with an exciter arrangement placed on it and a magnet armature connected to the contact bridge carrier, which is movable in its tightening position against the force of two wire springs arranged on both sides, which are fixedly supported and a negative characteristic curve have their anchor return force, characterized in that the two wire springs (18,18 ') are essentially C-shaped and with their two' 5 respective ends from two sides into lateral plug-in holes (27; 28, 28 '; 35) of the between the wire springs arranged armature (19) or the contact bridge carrier (1) are inserted or supported on lateral projections (31) of the same and in such a way over the respective central spring section (29, 29 ') in a respective groove-shaped recess (27') or on a respective projection (34) of the housing (A, B; 32, 33) or of the winding body (25) of the excitation spool (22) are supported so that both springs are aligned obliquely to the direction of movement of the armature during the entire armature stroke. 2. Contactor according to claim 1, characterized in that next to each on the housing (32, 33) and the central spring section (29, 29 ') of an associated wire spring (18, 18 ') supporting projection (34) serving as an assembly aid housing opening (36) is formed is. 3. Contactor according to one of claims 1 or 2, characterized in that the groove-shaped Recesses (27 ') or the projections (34) on the housing (32,33) are formed in such a way that the normal vertical movement of the armature (19) when it is moved into the tightening position the core (23) is superimposed with a rotary movement about a vertical axis.