DE2752114A1 - Electromagnetic relay with flap armature - has two part excitation coil, each coil part for specified induction flux related to AC half period - Google Patents

Abstract

The excitation coil of the electromagnetic relay is under alternating current and moves a flap armature. A permanent magnet is mounted on a yoke. The excitation coil (34) consists of two single coils (15, 16). The first one (15) is designed to provide excitation in each second half-period of the alternating current, while the other coil (16) generates an induction flux, smaller and with an opposite phase in relation to the first coil. Preferably the first coil has a greater number of winding turns. The two coils are typically parallel and a diode (17) is in series with the first coil. Alternately the two coils may be in series and the diode in parallel.

Description

Electromagnetic device

The invention relates to an electromagnetic device with a through an excitation coil through which alternating current flows, and a movable hinged armature permanent magnets arranged on a yoke.

In the devices known for example from US Pat. No. 3,968,406 aforementioned type, which are used in particular for relays, is used for rectification of alternating current a so-called.

All-wave rectifier 6 used, according to FIG. 1 of the drawing four diodes. The alternating current provided by an alternating current source 5 is thus about this all-wave rectifier 6 of the hinged armature 3 surrounding it Excitation coil 4 supplied so that it depends on the direction of magnetization of the hinged armature 3 generates the induction flux shown in FIG. With these devices In addition, two yokes 2a and 2b of unequal length are provided, which are attached to the two Pole faces of the permanent magnet 1 are arranged so that the hinged armature 3 with its one end in the air gap between these yokes and with its other, the axis of rotation receiving end rests against the longer yoke 2b. The disadvantage is that a such all-wave rectifier with the four diodes and / or with a smoothing capacitor results in a corresponding increase in price and also the size of the device enlarged.

The invention is therefore based on the object for such electromagnetic device uses a simpler circuit to drive the excitation coil provide so as to obtain a cheaper manufacturing option and at the same time thus also a reduction in size.

This object is achieved in that, according to the invention, the excitation coil consists of two individual coils, one of which is a coil for excitation in each second half cycle of alternating current and the other coil for generating one to this one coil of smaller and anti-phase induction flux is arranged. The two coils should expediently have an unequal number of turns, only one diode is provided, which is then either in series or in parallel with which a coil with the larger number of turns is connected, on the other hand the other coil provided with the smaller number of turns is then connected either in parallel or in series.

According to the invention, an electromagnetic device is thus provided, which can be made noticeably cheaper, for example, by only one diode in the preferred embodiment discussed here instead of the four diodes of the known all-wave rectifier is required in combination with only one reversed winding of the two individual coils. This means that the device size can also are reduced accordingly, it generally being the case that these proposals also are applicable to other than polarized device types.

The invention is explained in more detail below with reference to the drawing. 1 shows a schematic representation of a known one described above electromagnetic device, Fig. 2 is a diagram to illustrate the with this Device to be obtained induction flux, FIG. 3 shows a representation corresponding to FIG an electromagnetic device according to the invention, Fig. 4 is a diagram of a a circuit equivalent to the device according to FIG. 3, FIG. 5 a circuit corresponding to FIG. 2 Diagram to illustrate the induction flux to be obtained with the device according to FIG. 3, FIGS. 6-9 different working phases of the device according to FIG. 3, FIGS. 10-12 representations 3 to 5 of a second embodiment of the electromagnetic Apparatus according to the invention and FIG. 13 is a perspective view of a practical one Embodiment of the electromagnetic device according to the invention.

Referring to Fig. 3, an electromagnetic device according to the invention comprises a permanent magnet 11, on the two pole faces of which two yokes 12 of unequal length and 13 are present. In the one formed between the two ends 12a and 13b of this yoke Air gap encloses one end of a plate-shaped hinged armature 14, the other, its axis of rotation receiving end on the longer yoke 13 is present. The hinged armature 14 is from a first excitation coil 15 with a larger number of Windings and a second excitation coil 16 surrounded, the smaller number of turns is wound opposite to the turns of the excitation coil 15. The two coils 15 and 16 generate with opposite phase induction fluxes, which because of the different Number of turns of the coils are also different in size. Besides, is still with one excitation coil 15, a diode 17 is connected in series, while the coil 16 has a parallel connection to the coil 15, with which they are jointly connected to a AC power source 18 is connected.

For this training of the electromagnetic device according to the invention it can be deduced from FIG. 5 that one coil 15 has an induction flux P1, which is correspondingly larger than that because of the larger number of turns of this coil Induction flux i2 of the coil 16. Because further the two coils are opposite to each other are wound and so that the opposite phase appears is in further combination with the diode 17 connected in series with one coil 15 and the one implemented for this purpose Parallelsohaltung the other coil 16 achieved that the generated by the coil 15 Induction flux 1 every two half cycles of the alternating current coming from the source 18 appears. The induction flux generated by the other coil 16, however, also occurs every half cycle of this alternating current, the opposite phase to the coil 15 causes that when the induction flux appears at the coil 15, the smaller induction flux i2 of the coil 16 is swallowed up by this greater induction flux {1. The two InduktionsflUßen and i2 of the coils 15 and 16 thus result in the superimposed induction flux i, in which the absolute magnitude of the induction flux i2 appears in alternation to the absolute size of the reduced by the induction flux i Induction flux i1. The (superimposed) induction flux i consequently magnetizes each Half period of the alternating current the hinged armature 14 in the same direction, so that from this then the individual work phases illustrated in more detail in FIGS. 6 to 9 can be obtained.

In the work phase recorded in FIG. 6, no current should flow through the two coils 15 and 16 flow. The hinged armature 14 is consequently then with his into the air gap between the yokes 12 and 13 reaching end c through the end 12a of one yoke 12 tightened. If now the power source 18 is turned on and the alternating current flows through the coils 15 and 16 then becomes dependent on the direction of flow of the current and due to the superimposed in the two coils 15 and 16 Induction flux + the end c of the hinged armature 14 according to FIG. 7 from the end 12 a of the yoke 12, so that the hinged armature 14 to its at the free end 13b of the yoke 13 adjacent axis of rotation d is pivoted against the yoke 13. The folding anchor 14 will then also rest with its end c on the yoke 13, as in FIG. 8 shown, wherein it assumes a fairly stable position, although according to Fig. 5 the superimposed Induction flux H changes its size every two half-periods. This fluctuation is However, irrelevant because that caused by the hinged armature 14 and the yoke 13 Magnetic resistance is extremely small, since the hinged armature 14 is very close to the yoke 13 is created. As soon as the current flow through the coils 15 and 16 is interrupted the magnetization caused thereby in the hinged armature 14 and the The hinged armature 14 can then again with its end c through the free end 12a of the yoke 12 as shown in FIG. The hinged anchor 14 is therefore then again brought back into the work phase according to FIG. 6, from which he in the next Switching on the current flow through the coils 15 and 16 again in the working phase 8 for the duration of the current flow through the coils.

In the alternative embodiment according to FIGS Again a permanent magnet 21 is realized for the device, on both of its pole faces two yokes 22 and 23 of unequal length are in contact. Holds in the air gap of this yoke one end of a hinged armature 24, the other, the axis of rotation receiving End of the longer yoke 23 rests. The hinged anchor 24 is also here by two oppositely wound coils 25 and 26 with a different large number of Surrounding turns, with respect to which, however, the The difference in circuit technology is that the two coils 25 and 26 are in series are connected and a diode 27 is connected in parallel with the larger number of turns having coil 25 has. However, this difference is related to of the superimposed induction flux + received no deviation by the alternating current supplied by a source 28 during every other half cycle in the coil 25 with the larger number of turns generates the induction flux 61 while in the coil 26 with the smaller number of turns in each half cycle of the alternating current the induction flux +2 is generated. This induction flux () 2 appears every second Half-period at full size and is due to the existing antiphase in everyone in between lying half cycle swallowed by the induction flux # 1 of the coil 25, whereby thus the induction flux # 1 when it appears every two half-periods of the alternating current is reduced by the induction flux i2 standing in phase opposition to it.

The superimposed induction flux f thus effects the hinged armature 24 the same work phases as described above with reference to FIGS. 6 to 9 for the device 3 to 5 were explained in more detail according to FIGS.

For these work phases it can now be assumed, for example be that with a compared to the coil 26 three times the number of turns Coil 25 and if the resistance of the two is still assumed to be the same Coils 25 and 26 during the one half-periods A of the Wechaelstromes in which the larger Bere Number of turns having coil 25 an induction flux is generated, which is therefore the same three times the value of the induction flux i2 that has the small number of turns Coil 26 is. A superimposed induction flux therefore becomes for the half-periods A. i obtained because of the opposite phase to the induction flux {1 to the induction flux i2 is smaller than the induction flux Q1 and therefore has a size of 2/3 i1, since on the other hand the induction flux 2 is equal to a third of the induction flux. By now continuing to feed through the coil 26 during the other half-periods B the im Compared to the half-periods A, double the amount of current flows, then appears at the coil 26 a superimposed induction flux §, which is equal to twice the value of Induktionsflußes 92 corresponds, which means in practice that at Consideration of its relation to the induction flux also in the half-periods B a superimposed induction flux in the size of 2/3 41 occurs. rlFthin is moreover ensures that over all half-periods A and B of the alternating current the armature of the electromagnetic device remains unchanged in the same direction is magnetized, the magnetization by an induction flux in size of two thirds of that on the coil with three times the number of turns Induction flux generated is made. By this correspondingly strong and permanent magnetization, the hinged armature is held extremely stable on one yoke, against which it is applied when current flows through the coils.

In Fig. 13 is another practical embodiment of the electromagnetic Device according to the invention shown. It is a bobbin 33 with a cavity 32 realized on a lower yoke that also serves as a base plate 31 is attached. The yoke 31 has a central opening in the area of which the bobbin 33 is wound with an excitation coil 34 formed from two individual coils and so that a hinged armature 37 arranged in the cavity 32 surrounds the hinged armature with the crosshead 37a of its T-shape rests on the yoke 31. The hinged anchor grips on the other side 37 in the air gap formed with respect to an upper yoke 36 close to one of the Yoke 31 on its one pole face attached permanent magnet 35, on the other Pole face the yoke 36 rests, above which a connecting plate 38 with outer terminals 39 and inner terminals 40 for the excitation coil 34 and a diode 41 is arranged. A card 42 still present is for example provided for the purpose of moving the hinged armature 37 for opening and closing to transmit the contacts of a relay, so that the contact actuation of the relay takes place as a function of the passage of current through the excitation coil 34.

Claims (5)

P a t e n t a n s p r U c h e electromagnetic device with a through an excitation coil through which alternating current flows, and a movable hinged armature permanent magnets arranged on a yoke, characterized in that the excitation coil (34) consists of two individual coils (15,16; 25,26), of which the a coil (15,25) for energization every other half cycle of the alternating current and the other coil (16, 26) for producing a coil smaller than this one and anti-phase induction flux is arranged. 2. Electromagnetic device according to claim 1, characterized in that g e -k e n n z e i c h n e t that one coil (15, 25) has a larger number of turns than the other coil (16,26). 3. Electromagnetic device according to claims 1 and 2, characterized it is noted that the two coils (15, 16) are connected in parallel and with one coil (15) a diode (17) is connected in series. 4. Electromagnetic device according to claims 1 and 2, characterized it is noted that the two coils (25, 26) are connected in series and with one coil (25) a diode (27) is connected in parallel. 5. Electromagnetic device according to claim 2, characterized in that g e -k e n n shows that one coil (15, 25) has three times as many turns as that other coil (16,26).