DE8520236U1 - Poled electromagnetic relay - Google Patents

Description

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DESCRIPTION

The invention relates to a polarized electromagnetic Relay in the preamble of claim 1 specified genus.

Such a relay is known from German Auslegeschrift 2,348,423. This relay is a bistable relay that works with a rod-shaped armature. The armature is pivotally supported at its one end to one formed by a yoke pole face _t wherein he in a stable position of the relay with its other end to the group formed by the yoke assembly second pole face, in the other relay position on the other hand with a central portion at a The end face of the coil core rests. On the end of the coil opposite the armature, a permanent magnet is arranged asymmetrically to the coil body, the magnetic circuit of which closes over the entire yoke arrangement and the armature or over part of the yoke arrangement, part of the armature and the coil core, depending on the position of the armature. As a result, the armature is held stable in its respective end position. The armature can be switched by modulating the coil with current of one polarity or the other.

The invention is based on the object of providing a relay of the type indicated at the beginning with as inexpensive as possible To design means so that it has monostable switching behavior and possible without a center position inclination is kept safe in the rest and in the working position.

The solution of this task is in the characterizing part of the '.'"-. Specified protection claim 1. Thereafter, the anchor is formed as a rocker armature and mounted on the side opposite to the permanent magnet end of the coil core is in idle state now causes of the coil core asymmetrically arranged permanent magnet, that the rocker armature to the side of the permanent magnet is pivoted while an excitation of the coil, which is one of the permanent magnetic flux in the coil core

^ tgegöngesefcizte flow rate of sufficient size results in the rocker armature being pivoted into another position corresponding to the working position.

The developments of the innovation according to claims 2 and 3 relate on embodiments that are particularly favorable in terms of structure and assembly of the relay.

An exemplary embodiment of the innovation is shown below with reference to the drawings explained in more detail. In the drawings shows

1 shows a longitudinal section through a polarized electromagnetic relay, the right half being cut in the middle of the relay and the ^left half outside the coil according to the section line Ι-Ϊ ¹ in FIG. 2,

Fig. 2 shows a cross section through the relay at the level of the pole plate according to the section line II-II 'in Fig. 1,

Fig. 3 is a view of the relay from above with the housing cap removed and

4 shows a force-displacement diagram to explain the mode of operation of the Relay according to Fig. 1-3.

As can be seen from Fig. 1, within one of a base plate 10 and a housing cap 11 formed relay housing a coil body 12 with a winding 13 and a soft magnetic core 14 under- - brought. Asymmetrical to the core 14, specifically to the side of this, is on A permanent magnet 59 is arranged on the upper side of the bobbin 12, on one pole of which there is an upwardly angled end of a first pole plate 16 and at its other pole an outwardly cranked end of a second Pole plate 17 rests.

The lower end of the core 14 is with its cylindrical attachment in one, in the lower flange of the bobbin 12 partially recessed pole plate 19, which with a central region of a

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Rocker armature 20 cooperates, in turn with one middle cylindrical recess is provided in which the turned stump of the core 16 and the one perpendicular to the drawing plane of FIG Axis (designated 70 in Fig. 2) is pivotably mounted.

Pas lower end of the yoke plate 17 is designed as a pole face, which cooperates with the left arm of the rocker armature 20. In a similar way In this way, even if not shown in Fig. 1, the below F.nflA <outer right yoke plate 16 designed as a downward-facing pole face which interacts with the right arm of the rocker armature 20. As from the On the right-hand side of FIG. 1 and from FIG. 2, the yoke plates are visible 16, 17 in the area of the coil 13 in the middle for receiving the coil connection, consisting of the one anchored in the coil body 12 Contact pin 30 and the fork contact 31 fastened in the base plate 10, recessed. To achieve a sufficiently large pole equilibrium Yoke plates 16, 17 opposite the rocker armature 20 are on both sides Legs 16a / 16b and 17a / l7b are angular. Below the Legs 16a / 16b and 17a / l7b of the yoke plates 16, 17 are located the switch contact points 32a / 32b for the left switch contact and 33a / 33b for the right switching contact, which is shaped by the approximately w-shaped bent, resilient contact bridge 21 attached contact pieces 43 and the respective associated fixed contact connections 23 formed Will. The contact bridge 21 is suspended from the two outermost ends of the rocker armature 20. At the upper end of a central fixed contact connection 29, a cutting edge 70 is provided, which serves as a bearing for the contact bridge 21 and against which the contact bridge is secured by an in the core 14 engaging compression spring 22 is printed.

The relay has monostable switching behavior, FIG. 1 the Shows rest position of relay. In this position, the armature is held stable by the permanent magnetic flux from the N-PoI of the permanent magnet 59 goes out, the part of the right yoke plate lying against this pole 16, the core 14, the pole plate 19, the left arm of the rocker armature 20 and the left yoke plate 17 penetrated and over this to the S-PoI of the Permanent magnet 59 returns.

isäät t, ί & '. ^ l-feliü

If the winding 13 is now excited in such a way that a 2Um Däüermagnnetfluß opposing control magnetic flux of sufficient strength is generated * so the resulting penetrating the left arm of the rocker anchor 20 becomes Magnetic flux low / while running over the right Jochplatfce 16 Part of the control magnetic flux between the pole face on the lower End of the yoke plate 16 and the right arm of the rocker armature 20 a tightening force generated, which pivots the rocker armature 20 in its working position. In this position the middle foot is in contact 29 no longer over the switching contact point 33a / 33b with the right Fixed contact connections 23, but via the contact point 32a / 32b with the left plague contact terminals 23 are connected. When the winding 23 is de-energized, the rocker armature is moved back into the by the permanent magnet 59 position shown in Fig. 1 returned.

In the embodiment shown in Fig. 1, there is the permanent magnet 59, the core 14 and the rocker armature 20 coupling yoke arrangement exclusively from the two yoke plates 16 and 17, of which the right, longer yoke plate 16 through one at the upper end of the core 14 provided rivet is held, namely a turning 71 of the core 16 printed through a hole in the yoke plate 16 and attached to their Flanged edges, with which the core 14 is magnetically coupled to the yoke plate. As can be seen from the left half of FIGS. 1 and 3, is for the purpose of tolerance compensation and to avoid air gaps between the yoke plate leg 16c, the permanent magnet 59, the surface of the yoke plate 17 facing the permanent magnet, the yoke plate 17 is provided with laterally bent tabs 17c / 17d, which. act as a backlash compensation when assembling the individual parts and depending on Tolerance position of the individual parts more or less strong and with generation - a corresponding contact pressure are deformed back. Similarly, a tolerance compensation between pole plate 19 and its contact area achieved on the bobbin 12, the aim being that independent from the tolerance position of the individual parts, the magnetic resistance between pole plate 19, core 14 and yoke plate 16 becomes small, that means practically can be joined without mutual air gap and that, nevertheless, an exact alignment between the pole faces 16a / 16b and 17a / 17b one hand and pole plate 19 is reached. For this purpose, the tabs 16d, 16e, 16f, 16g are bent downwards and are used during assembly while achieving a corresponding contact pressure between pole

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plate 10 and the bobbin 12 also back-deformed.

In the diagram of FIG. 4, those acting on the rocker armature 20 are shown Magnetic and spring forces applied over the pivoting path of the rocker armature, where the right end of the abscissa is the rest position shown in FIG. 1 reproduces, while the left end of the abscissa corresponds to the working position of the rocker armature 20. The dash-dotted curve A in FIG. 4 gives the course of the spring forces resulting from the contact bridge 21 again, the right branch corresponding to the force that results from the contact of the right contact piece 43 on the right fixed contact connection 23 results, so with closed contact points 33a, 33b, f

I; and to pivot the rocker armature in the direction of its working position I

searches, while the left branch of the dash-dotted curve A corresponds to Appendix |

of the left contact piece 43 on the left fixed contact connector 23

Reproduces spring force, so with closed contact points 32a, 32b, |

which move the armature from the working position in the direction shown in FIG. 1

tries to sway in the rest position. In the middle of the characteristic 1

line field that corresponds to the middle range of motion of the rocker armature 20 |

corresponds, have all contact pieces 43 of all fixed contact terminals |

sen 23 lifted so that no spring forces act on the rocker armature 20 / I

d. H. In this example in FIG. 4, the contact bridge 21 has no prefix

tension mounted on the rocker armature 20. Yy

The dashed curves in Fig. 4 give the output on the rocker armature 20 i ' practiced magnetic forces again, the lower dashed curve Bl the J from the superposition of the control magnetic flux with the permanent magnetic flux re- | a resulting total magnetic force when pivoting the armature from the in;

Fig. 1 shows the rest position in the working position, while the upper )

Dashed curve B2 represents that magnetic force after completion ^r turn of the winding 13 only through the remaining Dauarmagnet-

flow on the rocker armature 20 pivoting back into its rest position. j,

is practiced. By superimposing the spring and magnetic forces, i. H. by ·!

Addition of the dashed curves B1, B2 with the dash-dotted curve I.

A results in the Ge 1 shown in FIG. 4 with solid lines

samtkxaütkurven Cl and C2, the lower curve Cl the total force |

run with the excitation of the winding 13 and the upper curve C2 the total force |

show the course with the winding 13 switched off.

In the non-excited state, the rocker armature 20 is in the position shown in FIG. 1, which corresponds to point 100 in the diagram of FIG. This point ίΟΟ lies by a certain value above the horizontal zero-force line, which means that the one exceeding the spring force Permanent magnet force results in a certain holding force for the rocker armature 20 in its rest position. When the winding 13 is excited it shifts the working point in the diagram according to Flg. 4 towards point 101, who is drawn there lying on the zero force line and himself thus is in equilibrium of forces. In practice, however, the relay always operated with the lowest permissible coil excitation, at which point 101 is a planned amount below the zero line and at which there is sufficient excess force to overcome the in the example 4 not taken into account system friction and for acceleration the parts to be moved (rocker armature 20 and contact bridge 21) 2ur is available. The rocker armature 20 now swivels according to FIG. 1 counterclockwise, the operating point in the diagram according to FIG. 4 being from point 101 along the solid curve C1 or lower lying is shifted to point 102. In this position I predominate the magnetic forces resulting from permanent magnetic flux and control magnetic flux according to the dashed curve B1 the spring section corresponding to curve A forces by far, so that point 102 is far below the zero force | 1 Line lies, which means that the armature is held securely in its working position when the winding is energized.

If the excitation is now switched off, the magnetic forces remain only the part based on the permanent magnetic flux that is in the working position of the anchor is practically zero. Therefore, when you go down, switch the winding of the working point from point 102 to point 103 *

above the zero-force line, with the Ankeir initially practically only the Contact spring force attacks, which seeks to pivot the armature back into its rest position. With increasing approach of the left arm according to FIG. 1 of the rocker armature 20 on the lower pole face of the left yoke plate 17, the air gap decreases and the permanent magnetic force increases lengthways The dashed; Curve B2, where because of the superposition with the Spring forces of the working point when pivoting the anchor back lengthways the solid curve C2 shifted back to the point 100;

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As can be seen from the above explanation of the diagram according to FIG. 4, the asymmetrical arrangement of the single permanent magnet 59 with respect to the central core 14 and symmetrically _{on it results}
pivoted rocker armature has _a switching behavior in which a passage through the zero force line during the pivoting of the
Anchor is avoided. This means that any unstable center position is avoided. In addition, the points 100 and 102 show that the anchor is held in the rest position and especially in the working position with high force, so that _an adjustment of the _Re i _{ais is not} necessary,

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Claims (3)

STREHk ^ CHUBEL-H (D-PP 1. Pole-s electromagnetic relay with a coil (12, 13) with a soft magnetic core (14), a yoke arrangement (16, 17) with two sections, the are guided around the coil (12, 13) on opposite sides starting from one end of the core (14) and on the end face of the coil (12, 13) corresponding to the other end of the core (14) each form a pole face, a permanent magnet (59) _t in one of the two portions of the yoke assembly (16, 17) is inserted, and a contact system (21, 23, 24, 29) actuating armature (20) connected to the other end of the core (14 ) and the two pole faces magnetically cooperates, characterized in that the An anchor in the area of the other end of the core (14) ^iB mounted rocker armature (20) is. 2. Relay according to claim 1, characterized in that g e k e η η that the yoke arrangement has two continuous yoke plates (16, 17) of different lengths, those with their ends at the. The permanent magnet (59) and the rocker armature at their other ends (20) facing pole faces, and of which the longer (16) one to the said one end of the core (14) magnetically coupled area. 3. Relay according to claim 2, characterized in that g e k e η η - shows that the area of the longer yoke plate (16) is firmly joined to one end of the core (14) is. te Mi * ti M Ii it * · * «** · · ι» I t * * «• * t 4 ·» · 4 · t (H