DE1910101U - ELECTROMAGNETIC PROTECTION. - Google Patents

Description

16 »December 1964 Gtt / wa

Dr.-Ing. Heinrich Scheuer

Patent attorney

AACHEN, Zol! Ernstr. 1
Telephone: 32192 and 25182

Electromagnetic contactor

The innovation concerns an electromagnetic contactor with a spring-loaded magnetic core »

The resilient mounting of the magnetic core in the known contactors is used to reduce the impact force exerted by the armature on the magnetic core when switching and thereby to extend the service life of the contactor, in particular because it is subjected to a large number of switching operations and also with a soft elastic mass as a support between the core yoke and the bottom of the contactor housing. In particular, the soft elastic mass has the advantage, if dimensioned appropriately, that the number of switching operations that can be carried out with the contactor can be increased considerably

The control is based on the task, the contactor so to train that the number of possible circuits can be increased even further, and not just with consideration on the wear and tear of the armature and magnetic core, rather

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also with regard to the contact from "br and.

Types of embodiments are known in which the contactor has a vibrational effect on switching Masses and spring forces matched to an aperiodic, creeping or static friction movement of the magnetic core The damping force of the vibration damper has »The vibration-effective masses and spring forces can through Attempt to be determined. In this way it can be determined whether and to what extent, in addition to the mass of the magnetic core, In particular, the masses of the armature, the bobbin with winding and the moving contacts are of importance are. It can also be determined whether the vibrational spring forces are essentially from the Spring force of the resilient mounting of the magnetic core or also from additional pressure spring forces as well as from the spring forces to keep the armature spaced and the contact spring forces, etc. By such Preparatory measurements can be used to determine the required damping force of the vibration damper.

An expedient embodiment of the contactor according to! Control is characterized by the vibration damper in the form of serving as a clamping or braking springs are leaf springs between the movable magnetic core and the surrounding stationary parts, such as housing parts ₀ *

Leaf springs of this type are structurally very simple, and they can be used to achieve the required damping force very easily be achieved. It is useful that these springs also have different ones for different sizes of shooter Sizes or strengths so that they are adapted to the size of the vibrating masses and spring forces « Basically, for example, these springs can be used on housing

parts get stuck and the magnetic core rubs against them »The springs can also stick to the magnetic core and rub against housing parts, "

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An expedient design of the last-mentioned embodiment of the contactor is marked according to the innovation through a hat running transversely to the magnetic sheets on the lateral end faces of the magnetic core and by approximately I-shaped bent leaf springs, which at the end of the first L-leg have an inwardly directed one have an additional short fold with which they can be inserted into the groove intervene, and their second L-leg with which they the yoke ends of the magnet core engage resiliently under, is slightly curved inward and with the first L-leg forms an angle of slightly less than 90 °, so that the first L-leg with its to the second L-leg pointing part resiliently protruding obliquely from the relevant lateral end face of the magnetic core runs *

The leaf springs described above are attached to the magnetic core without screws, which greatly simplifies assembly is. They reliably take part in the magnetic core movement when switching and it also occurs in the long run no loosening of their seat.

An advantageous development of the contactor according to the innovation is characterized by an L-shaped width curved leaf springs, which is larger than the width of the magnetic core, and adapted by this larger width Guide grooves in the housing of the contactor "

This larger width can, for example, be selected to be of a similar size to the width dimensions of the coil former In this way, the leaf springs easily have space in the housing of the contactor, since this housing is the The bobbin dimensions must be adapted anyway. The guide grooves in the housing therefore also do not require any additional complex structural measures, because of the fixed connection of the leaf springs with the magnetic core the guide for the leaf springs is also a guide

for the magnetic core * The larger width of the leaf springs also has the advantage that the springs can have the necessary clamping force with respect to the housing parts without that they must be made of too thick material «

Another useful embodiment of the contactor according to the innovation is characterized by such a distance of the wall of the housing of the contactor from the lateral end faces of the magnetic core that the L-shaped bent leaf springs resiliently and strongly rubbing against the The housing wall

In and of itself, the mentioned distance does not need to be greater than that of conventional shooters, since the L-shaped bent leaf springs between the lateral end faces of the magnetic core and the housing wall anyway take up very little space, this is another one Advantage of designing the vibration damper as L-shaped bent leaf springs «

In addition, a soft elastic mass known per se can be used as a resilient support between the yoke of the magnetic core and the housing arch ₆

In the drawing, the innovation is explained in more detail using an exemplary embodiment «

Show it

Fig. 1 in side view, partially broken open and sectioned, an embodiment of the innovation according to the invention Contactor,

Mg. 2 in plan view a section along the section line H-II in Fig * I,

Figure "3 is a front view, partially broken away and sectioned, of the contactor according to Fig 1 and 2 and _o

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4 is a perspective view of the magnetic core and the brake springs of the contactor according to Fig. 1 to 3 «

The housing has the side walls 1 and the housing "bottom 2" on the housing bottom 2, the soft elastic mass 8 is held between the webs 11 _a The soft elastic mass 8 forms a resilient support between the yoke of the magnet core 4 and the housing bottom 2 «

The bobbin 10, which carries the winding 9, encloses the middle leg of both the magnetic core as well as the armature 3s The armature 3 is de-energized The winding 9 is held at a distance from the magnetic core 4 by the springs 13. The springs 12 also act in the same way, which keep the contacts 14 open when the winding 9 is de-energized »The springs 13 also act in the same way, that they press the bobbin 10 with its bearing surface 16 against the surfaces 15 of the magnetic core * on this On the one hand, the coil body 10 is fixed in its position in relation to the magnetic core 4. On the other hand will in this way the magnetic core 4 is pressed with its yoke against the elastic support 8. The support surface 16 can be designed, according to the new, expediently curved, so that when they are in contact with the surfaces 15 of the magnetic core 4 a tilting of one or the other part avoided

The magnetic core 4 has on its lateral end faces a groove 5 running transversely to the magnetic sheets, in which the folds 6 "'and 7"' of the brake springs 6 and 7 engage «The brake springs 6 and 7 are L-shaped bent leaf springs with the L-legs 6 ^{ and 6 "and 7 ^f and 7" * The leaf springs are wider than the magnetic core and protrude beyond the magnetic core 4 on both sides. Their ends also act as guide elements together with the guide grooves 17 in the housing wall 1,

The! Legs 6 "and 7" engage under the yoke ends of the Magnetic core 4 resilient and are slightly curved inwards and form angles of something with the L-legs 6 'and 7' less than 90 °, so that the legs 6 'and 7' protrude resiliently at an angle from the relevant lateral end face of the magnetic core 4. This oblique protrusion is particularly clear in Pig. I recognize.

The obliquely protruding L-legs 6 'and 7 ^f are rubbing or clamping on the inside of the housing wall 1 and in this way act as a vibration damper to dampen the movement of the magnet core 4 when switching , creeping, static friction or similar movement of the magnetic core is given when switching, whereby the vibratory masses and spring forces must be taken into account the movable contacts 14 including these contacts bearing contact bridges "the vibration-effective spring forces may be the spring force of the flexible material 8, the springs 15p of the springs 12, etc. ₀ How far in individual involved the masses and spring forces can be determined by trial" is essential, that bounce vibrations between the Armature 3 and the magnetic core 4 and between the movable contacts 14 and the fixed contacts 18 are largely avoided *

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Claims (1)

Ί1 HZ 1.65 - 7 claims 1,) Electromagnetic contactor with a masses and spring forces that act on vibrations when switching adjusted to an aperiodic, creeping or static friction movement of the magnetic core Damping force of the vibration damper, characterized in that the same vibration damper in Form of leaf springs serving as clamping or braking springs between the movable magnetic core and the these surrounding fixed parts, e.g. housing parts, * 2 ») Electromagnetic contactor according to claim 1, characterized by a hat running transversely to the magnetic sheets on the lateral end faces of the magnetic core and by approximately L-shaped bent leaf springs, which at the end of the first L * -handle an inwardly directed additional short TJ bow with which they engage in the hat, and whose second L-leg, with which they spring under the yoke ends of the magnet core, is slightly curved inward and forms an angle of slightly less than 90 ° with the first L-leg so that the first L-leg with its part pointing towards the second L-leg extends in a resiliently sloping manner from the relevant lateral end face of the magnet core ₉ 3β) Electromagnetic contactor according to claims 1 and 2, characterized by a width of the L-shaped bent leaf springs which is greater than the width of the magnetic core, and by this greater width adapted guide grooves in the housing of the contactor ^ - 8th 4.) Electromagnetic contactor according to claims 1 to 3 » characterized by such a distance between the wall of the housing of the contactor and the lateral end faces of the magnetic core that the L-shaped bent leaf springs resiliently and strongly rubbing against the housing wall *