DE3404462A1 - Polarised relay having protection against external magnetic influencing - Google Patents

Abstract

The polarised relay having protection against external magnetic influencing consists of a contact spring system which is mounted in an insulating spring bracket and whose active contact springs can be switched over by means of an insulating web which engages on the part of a rocker which can pivot, which rocker is supported in a rotating bearing in the spring bracket such that it can pivot and is connected to a changeover lever, a permanent-magnetic field and a control magnetic field, produced by the drive system, acting on the rocker. Locking of the pivoting movement is provided in the region of the pivoting path of the changeover lever in such a manner that, when an external, magnetic and non-related constant field acts on a locking plate which is mounted on the cap, the locking plate is moved by the constant field and this movement locks the pivoting movement of the changeover lever for as long as the external constant field is applied.

Description

Polarized relay with protection against magnetic

Foreign influence The invention relates to a polarized relay the preamble of claim 1.

Such relays act on one in a central pivot point mounted rocker a permanent magnetic field and a control magnetic field generated by the coil a.

Depending on the polarity of the coil, these fields are added or subtracted and deflect the rocker to the side of the stronger overall field.

In addition, corresponding return springs can also be used on the rocker works. However, the disadvantage of the known relay is that such a relay is by means of a "foreign magnet" can cause switching.

Such a "Frendmagnet" generates an external, magnetic constant field, where this constant field must be greater than the holding force of the relay, how - how described above - through the magnetic circuit of yoke and rocker with integrated permanent magnet is generated.

The external magnetic field has the same effect as that through the coil generated a magnetic field of opposite polarity to the permanent magnet, with this opposite polarity the switch causes.

The relays mentioned are therefore sensitive to external magnetic fields, whereby the external, constant magnetic field is not just a temporally constant, magnetic field Field is understood, but also generally alternating fields, the magnetic flux changes are so slow that they are able to change the position of the seesaw to change in the spring bracket of the relay.

The object of the present invention is to provide a polarized relay of the to be developed further so that it is essentially insensitive to external, magnetic interference fields that could change the position of the rocker.

To solve the problem, the invention is characterized in that that in the area of the pivoting path (direction of the arrow) of the switching lever there is a lock the pivoting movement is provided in such a way that when an external, magnetic, external constant field on a locking plate whose movement in the external constant field the pivoting movement of the switching lever is locked.

The essential feature of the present invention is the so-called Magnetic locking of the rocker, which takes effect when a magnetic one Constant field - even if only briefly - acts on the locking plate, so that this moves by magnetic force and locks the pivoting movement of the switching lever.

The polarized relay according to the invention thus receives in the area of the switching lever a locking plate made of iron that moves when exposed to an external magnetic field so in locking grooves, ribs or recesses moves that the rocker of a polarized relay neither by external magnetic fields nor by those from the coil The generated magnetic force can move and thereby a switching of the relay is prevented.

The locking plate is either resilient in itself or by additional Spring elements, such as spring tabs, or also separate springs, held in rest position.

There are certain spring forces to hold down the locking plate in Rest position required to prevent the locking mechanism from e.g. Gravity, or vibration, appears. So it must go through the following described spring mechanisms are prevented that the lock is then in force occurs when, for example, the relay is "turned upside down" without the action of an external magnetic force acts on the locking plate.

The retaining spring force of the locking plate must be less than the force that is required to switch the relay from outside. as well the lock is constructed so that the generated by the coil Magnetic force prevents locking.

For the implementation of the proposed magnetic Locking the rocker of a polarized relay are several different embodiments suggested. A first embodiment is characterized in that the locking plate is understood as a cantilevered spiral spring, which with its free, pivotable End engages over the switching lever (claim 3).

Here, the locking plate is according to the subject matter of the claim 2 in the area of the pivoting path of the switching lever with its broad side approximately perpendicular attached to the longitudinal axis of the switching lever on the hood or the spring bracket and is perpendicular to theirs under the influence of the external, magnetic constant field Broad side can be raised.

In the raised position, locking tongues grip the locking plate on associated locking surfaces of the switching lever so that it is not in his can pivot other rest position.

This blocks the rocker as long as the outer, magnetic one Interference field is present.

When the external, magnetic interference field disappears, the locking plate springs back to their rest position and the locking tongues come out of engagement with the assigned locking surfaces of the switching lever.

As soon as a control magnetic field is then generated with the coil as intended is, the switching lever can be pivoted freely into its other rest position because the magnetic lock is out of engagement with the switching lever is located.

In a further embodiment according to the invention it is according to the claim 4 provided that the locking plate as deflectable in the broad side Ubertotpunktfeder is held in associated guide grooves of the hood, and itself with spring tabs extending from the broad side on the inside of the hood. A spring is referred to as an over-center spring, which has the so-called "cracking frog effect" executes, i.e. a spring that can be bent in itself, with a stable position is maintained as long as the external, magnetic interference field is applied while when the external, magnetic interference field disappears, the locking plate due to the the restoring forces inherent in the over-center spring moves back into the rest position and locking the locking plate out of engagement with the associated locking surfaces the switch lever arrives.

In the first embodiment, the switching lever can only be in his move a rest position in the area of the recess of the locking plate while in the opposite, other rest position, the switching lever on the outside of the Locking plate rests, the locking tongues with the associated Interlocking surfaces of the switching lever cooperate.

In a second embodiment, the recess in the locking plate twice as large as the first-described recess can be chosen, so that the changeover lever in its one rest position as well as in its other Rest position always moved in the area of the recess of the locking plate.

To increase the insulation and resistance to leakage current, it is important to that the locking plate consists in a development of a combined element, namely from a metallic locking plate, which in ener leaf-shaped, elastic bendable plastic encapsulation is held. The spring force for the one-sided clamped The spiral spring is thus achieved by the sheet-shaped plastic material, while the magnetically effective force is achieved by the inserted iron plate. Instead of using an iron plate as a magnetic flux concentrator it is of course possible to make the locking plate from higher quality, magnetically effective Materials to manufacture so that the magnetic lock also on relatively low Interfering fields already responded.

The subject matter of the present invention does not result only from the subject matter of the individual claims, but also from the combination of the individual claims with one another.

All information and characteristics disclosed in the documents, in particular the spatial training shown in the drawings are considered essential to the invention claimed insofar as they are individually or in combination compared to the prior art are new.

In the following the invention is illustrated by means of several ways of implementation Illustrative drawings explained in more detail.

In this connection, further elements that are essential to the invention can be found in the drawings and their description Features and advantages of the invention.

They show: FIG. 1: side view of a polarized relay according to a Section along the line I-I in Figure 2; Figure 2: Section along the line II-II in Figure 1; Figure 3: Section along the line III-III in Figure 1 with a top view on the magnetic lock; FIG. 4: Section along the line IV-IV in FIG 3; Figure 5: Top view of a magnetic lock in a modified form Embodiment in comparison to Figure 3; Figure 5a: top view of the locking plate of Figure 5; FIG. 6: section along the line VI-VI in FIG. 5; Figure 7: side view the arrangement of Figure 5 according to arrow VII; Figure 8: Section along the line VIII-VIII in Figure 5; FIG. 9: an embodiment modified in comparison to FIGS. 3 and 5 a magnetic lock; FIG. 10: Section along the line X-X in FIG 9; FIG. 10a: perspective illustration of the locking plate according to FIG. 10; figure 11: an embodiment of a modified compared to FIG. 3, FIG. 5 and FIG magnetic lock; FIG. 11a: top view of the locking plate; Figure 12: Section along the line XII-XII in FIG. 11; Figure 13: Section along the line XIII-XIII in Figure 12; FIG. 14: Top view of a locking plate with plastic encapsulation according to a further embodiment.

The polarized relay 1 shown in FIG. 1 consists of a hood 2, which encloses an insulating spring bracket 20 with the exception of the base plate. In the spring bracket 20, the drive system, not shown in detail, is in a manner known to me 3, the coil of which acts on a yoke 4. On the spring bracket 20 is a pivot bearing 6 designed for a rocker 5, wherein in the rocker 5 in not shown Way, a permanent magnet for generating a permanent magnetic field is integrated. The rocker 5 is also connected to a web 7 in a manner not shown, which is displaceable in the direction of its longitudinal axis when connected to the rocker 5 Switching lever 11 is pivoted into its position 11 '. With the web 7 is the upper, free end of one or more active contact springs 8 connected, which in the drawn Embodiment with the right, passive contact spring 10 has contact. In the Pivoting the rocker 5, i.e. when the switching lever assumes its position 11 ', the web 7 is moved in the direction of its longitudinal axis and the active contact spring 8 receives contact with the passive contact spring 9.

From Figure 2 it can be seen that parallel side by side by a insulating partition of the spring bracket 20 arranged separately two sets of contacts are, in each case the active contact spring 8 of the respective contact set over the web 7 is operated in parallel. To secure the polarized relay 1 against magnetic Interference fields, which could overplay the permanent magnetic field of the rocker 5, is one so-called magnetic locking of the switching lever 11 is provided. she consists from a magnetically effective locking plate 12, which in the embodiment as thin, elastically bendable sheet iron strips is formed. The locking plate 12 has a slug 13 which passes through an associated hole in the locking plate 12 engages (compare also Figure 3 and Figure 4) on the inside of the hood 2 in held like a cantilevered spiral spring.

With reference to FIGS. 3 - 6, the further function will now be described the magnetic locking described.

According to Figures 3 and 5, the locking plate has an approximately T-shaped Recess 27, the border of which the switching lever 11 with play in the area of a Constriction 15 of the switching lever 11 engages. The border of the rectangular Recess 27 of the locking plate 12 is in the direction of movement 17 of the switching lever 11 pierced by a slot 33. The slot is here by, a mutual The locking tongues 18, 19 of the locking plate 12, which are spaced apart from one another, are defined.

The length of the slot is greater than the width of the constriction 15, so that the switching lever 11 is in the rest position shown in FIGS the locking plate 12 can pivot in the direction of arrow 17 without hindrance and likewise in the opposite direction to this, namely in the direction of arrow 17 '.

However, if a magnetic interference field acts on the locking plate 12 a, that this is raised in the direction of arrow 14, then get the locking tongues 18, 19 according to the illustration in FIG. 6 in the area of wider design Locking surfaces 16 of the switching lever 11. In this raised position, the Switching lever 11 can no longer be pivoted in the direction of arrow 17 and is through the engagement of the locking tongues 18, 19 on the associated locking surfaces 16 of the switching lever 11 blocked.

The same function results when the switch lever its position 11 'according to Figure 5, because then the locking tongues 18,19 of the rest against the locking surfaces 16 on the other side.

According to FIG. 7, the locking surfaces 16 are narrow, in the constriction 15 protruding surfaces formed, the outer width of the the remaining width of the switching lever 11 corresponds. In Fig. 8 it is shown in dashed lines, that the locking plate 22 under elastic deformation in the grooves 23 of the hood 2 can be pressed in, with corresponding tongues 21 for engaging in the grooves 23 the locking plate 22 are provided.

Figures 3 and 4 show that the locking plate 12 with the help of a Butzens 13 attached to the inside of the hood 2 (e.g. by ultrasonic welding) can be, while the locking plate 22 shown in Figures 5-8 differs from the locking plate 12 only in that it is made with the help of tongues 21, which engage in associated grooves 23 of the hood 2, attached to the hood 2 is.

In the embodiment of the locking plate 32 according to FIGS. 9 and 10 becomes the so-called cracking frog effect for the deflection of the locking plate 32 used.

The recess 26 is in comparison to the recess 27 Figures 3 and 5 doubled so that a double-T-shaped recess 26 results, in the area of which the switching lever is both in its position in solid Lines as well as in its position 11 'in dashed lines. The border the double-T-shaped recess 26 engages around the switch lever with play in the Area of its constriction 15, two in the middle of the recess 26, facing locking tongues 28,29 between them a slot 34 reduced Form a length whose length is greater than the width of the constriction 15, however smaller than the width of in the longitudinal direction of the switching lever 11 above the constriction 15 arranged locking surfaces 16 of the switching lever 11. The rest position of the locking plate 32 is defined here by guide grooves 24 in the area of the inside of the hood 2, the locking plate 32 being displaceable in the area of these guide grooves 24. The locking plate 32 is supported here with from the broad side of the locking plate 32 protruding spring tabs 25 which are supported on the inside of the hood 2 on this hood 2.

A magnetic force now acts in the direction of arrow 14 on the locking plate 32, this is arched up in the middle, the length of which is shortened and a displacement in the longitudinal direction takes place in the area of the guide grooves 24. In the The locking plate 32 is then deformed in the direction of the arrow in the manner of a top dead center spring 14 outwards towards the inside of the hood 2, whereby the locking tongues 28, 29 get into the area of the associated locking surfaces 16 of the switching lever 11. The locking surfaces 16 of the switching lever 11 are always in the longitudinal direction of the switching lever 11, seen above the constriction 15, in order to achieve the described locking effect to achieve with outward deformation of the locking plate 12,22,32.

Instead of the dead center effect (cracking frog effect) of the locking plate 32 it is also possible to simply bend the locking plate without an over-center effect to reach. The tabs 25 hold the locking plate 32 in the rest position. Upon exposure an external magnetic field, the locking plate 32 is parallel to its rest position in Fig. 10 raised to the right, with only the resilient tabs 25 being elastic deform.

As a result, the locking tongues 28 come into engagement with the in Fig. 7 shown locking surfaces 16 of the switching lever 11, which is thereby locked will.

In FIGS. 11 to 13, the locking plate does not encompass the changeover lever 11, but intervenes in them. For this purpose, the switching lever 11 according to FIG 13 has a central recess 35, the function of the previously described Constriction 15 corresponds.

The locking surfaces 16 described above correspond to those in FIG 13 shown locking surfaces 36, which between them a slot 31 reduced Train width. The locking plate is in the rest position shown in FIG 42 with locking tongues 38 in the region of the recess 35 and can be moved therein with play.

As soon as the locking plate 42 is raised in the direction of arrow 14, arrives the constriction 30 in the area of the slot 31, so that the locking tongue 38 strikes against the locking surfaces 36 of the switching lever 11 and its further pivoting locked.

14 shows a further locking plate 52, which consists of a magnetic effective locking plate 51 consists, which is completely from a leaf-shaped Plastic encapsulation 50 is surrounded.

The flexibility of the entire locking plate 52 is made by the elastic Bendability of the plastic encapsulation 50 is achieved. In the double-T-shaped recess 47 are also in turn formed locking tongues 48, 49 facing each other, so that the locking plate 52 functions in the manner shown in FIG. 9 and FIG.

DRAWING LEGEND 1 polarized relay 2 hood 3 drive system 4 yoke 5 rocker 6 pivot bearing 7 web 8 active contact spring 9 passive contact spring 10 "11 Toggle lever 11 '12 Locking plate 13 Slug 14 Direction of arrow 15 Constriction 16 Locking surfaces 17 arrow direction 17 '18 locking tongue 19 locking tongue 20 spring bracket 21 tongue 22 locking plate 23 grooves 24 guide groove 25 spring tabs 26 recess 27 Recess 28 Locking tongue 29 Locking tongue 30 Constriction 31 Slot 32 Locking plate 33 slot 34 slot 35 recess 36 locking surfaces 38 locking tongue 42 locking plate 47 Recess 48 Locking tongue 49 Locking tongue 50 Plastic encapsulation 51 Locking plate 52 locking plate

Claims (8)

Claims 1. Polarized relay with protection against magnetic External influence, consisting of one fastened in an insulating spring bracket Contact spring system, the active contact springs of which can be switched over with an insulating bar are that engages the pivotable part of a rocker that is in a pivot bearing in the spring bracket is pivotally mounted, and is connected to a switching lever, on the Rocker a permanent magnetic field and a control magnetic field generated by the drive system have an effect that is in the area of the swivel path (Arrow direction 17, 17 ') of the switching lever (11) a locking of the pivoting movement it is provided that when a foreign, magnetic, external constant field acts on a locking plate (12,22,32,42,52) whose movement in the external constant field The pivoting movement of the switching lever (11) is locked. 2. Relay according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the locking plate (12,22,32,42,52) in the area of the pivoting path (direction of arrow 17, 17 ') of the switching lever (11) with its broad side approximately perpendicular to the longitudinal axis of the switching lever (11) is attached to the hood (2) or the spring bracket (20) and under the influence of the external magnetic constant field perpendicular to its broad side can be raised and in this position with locking tongues (18,19; 28,29; 38; 48v49) is in engagement with associated locking surfaces (16, 36) of the switching lever (11). 3. Relay according to claim 1 and 2, d a d u r c h g e k e n n z e i c h n e t that the locking plate (12,22,42,52) as a spiral spring clamped on one side is attached to the hood (2), (Fig. 1-8, 11-13). 4. Relay according to claim 1 and 2, d a d u r c h g e k e n n z e i c h n e t that the locking plate (32,52) as a bendable over dead center spring in the broad side is held in associated guide grooves (24) of the hood (2) and with From the The broad side of the outgoing spring tabs (25) is supported on the inside of the hood (2), (Fig. 9,10). 5. Relay according to claim 3, d a d u r c h g e k e n n z e i c h n e t that the locking plate (12,22) has an approximately T-shaped recess (27), the edge of which the switching lever (11) with play in the area of a constriction (15) encompasses that the border of the rectangular recess (27) in the direction of movement (17) of the switching lever (11) is interrupted by a slot (33), the length of which is greater than the width of the constriction (15) of the switching lever (11), and that in the direction of the longitudinal axis of the switching lever (11) above the constriction (15) Arresting surfaces (16) of greater width are arranged, which with the slot (33) interact between locking tongues (18, 19) of the locking plate (12, 22) which are formed, (Figures 1-8). 6. Relay according to claim 4, d a d u r c h g e k e n n z e i c h n e t that the locking plate (32,52) has a double-T-shaped recess (26), the edge of which the switching lever (11) with play in the area of a constriction (15) encompasses that two locking tongues which face one another and are arranged in the middle of the recess (26) (28,29) form a slot (34) of reduced length, the length of which is greater than the width of the constriction (15), but smaller than the width of in the longitudinal direction of the switching lever (11) above the constriction (15) arranged locking surfaces (16) of the switching lever (11), (Fig. 9,10,14). 7. Relay according to claim 3 or 4, d a d u r c h g e k e n nz e i c h n e t that the locking plate (42) has a locking tongue at its front, free end (38) has reduced width, which with play in an associated recess (35) engages in the switching lever (11) that is in the direction of the longitudinal axis of the locking plate (42) a constriction (30) of reduced width connects to the locking tongue (42), which with assigned, occupying a mutual distance between them Locking surfaces (36) interact on the switching lever (11) (Fig. 11-13). 8. Relay according to one of claims 1 - 7, d a d u r c h g e k e n It does not indicate that for the purpose of increasing the insulation and creepage resistance the locking plate (52) consists of a metallic locking plate (51) which held in a sheet-shaped, elastically bendable plastic encapsulation (50) is (Fig. 14).