FI58844B - AUTOMATISK STROEMSTAELLARE I SYNNERHET SKYDDSTROEMSTAELLARE - Google Patents

Description

ESSr ^ l [B] (11) NOTICE OF ADVERTISEMENT

ffifA L J 1; utlAggningsskrift 5 884 4 C (45) Patent ^ (51) Kv., k3 / Int.a.3 H 01 H 71/24 FINLAND —FINLAND (21) Pitenttihalcemu * - Pu «nt« ftsöknln | 2776/7 * + (22) H »k« ml «ptlvl - Aiwttknlncidag 2t.09.7 * + (23) AlkMpIhfi — GIteighctadag 2ΐ + .09.7 * + (41) Translators Public - Bllvlt offcntllg 28.03.73

Fatantti. ia rakittarihallitus (4 * NihUvttu) pw> on the moonUNMtltain ^ _

Patent · och raglstarstyralaan Anekin utit | d och uti.tknft »n puicnrad 31.12.80 (32) (33) (31) Request * · ** / privilege —Begird priori * · * 27.09-73

Federal Republic of Germany-Förbundsrepubliken Tyskland (DE) P 23 ^ 8613.7 (71) Siemens Aktiengesellschaft, Berlin / Munchen, DE; Wittelsbacherplatz 2, D-ΘΟΟΟ Munchen 2, Federal Republic of Germany-Förbundsrepubliken Tyskland (DE) (72) Horst Drubig, Regensburg, Federal Republic of Germany-Förbundsrepubliken Tyskland (DE) (7 * 0 V) y Kolster Ab (5 * 0 Automatic switch, 5 * 0 Automatic switch - Automatic circuit breaker, which is a separate display

The invention relates to an automatic switch, in particular a safety switch with a switching lock and a magnetic trigger, with two anchors and their working air gaps in a common magnetic circuit comprising a magnetic core and an excitation coil and in particular a magnet yoke.

One such automatic switch is disclosed in German Patent Specification 2,115,030. The anchor acting on the release lever of the switch lock is a drop anchor and the anchor acting on the movable contact part is an immersion anchor. Parallel to the working air gap of the drop anchor is a side current body made of magnetic material, which causes the magnetic trigger in the coil to pass as the current increases, the magnetic flux first passing over the working air gap of the submersible anchor and through the magnetic side current body in series with this gap. Only after the magnetic side current cap has been impregnated does sufficient magnetic flux pass over the working air gap of the drop anchor so that this is pulled and the clutch lock is released. Since the magnetic flux passing through the side current body also passes through the working air gap of the immersion anchor acting on the movable contact part, the start-up current of the immersion anchor acting on the movable contact part is smaller than the start-up current of the drop anchor acting on the switch lock release lever. However, this means that the immersion anchor wakes up before the drop anchor and acts on the movable contact part before the switch lock is opened. However, a prerequisite for the correct operation of the automatic switch is that the starting current of the anchor opening the switch-lock is lower than that of the anchor acting directly on the moving contact part in the opening direction. This is achieved in a known automatic coupling only if the immersion anchor has a very high retention. However, this high retention of the immersion anchor means that it can only be excited by considerable, magnetic forces.

The ampere speed of the excitation coil of the magnetic trigger required to release the clutch lock is determined by the ampere speed which saturates the side current body, overcoming the air gap of the immersion anchor. Additional ampere revolutions are required to overcome the high holding force at the immersion anchor and to achieve a sufficiently high opening speed and opening force for the immersion anchor. Thus, in order to achieve a sufficiently large force of the immersion anchor in the known automatic switch, in addition to high ampere speeds, large geometrical dimensions are required for the iron circuit of the magnetic trigger and thus also large dimensions for the automatic switch.

Since the iron circuit of the magnetic trigger requires large geometric dimensions (cross-section) and the immersion anchor requires a large force, the known automatic switch additionally increases the magnetic force acting square on the drop anchor at currents higher than the start-up current. This circuit breaker is therefore particularly sensitive to short-term current pulses, e.g., switching pulse units from groups of incandescent or fluorescent lamps with capacitive compensation, which adversely affect the tripping of the circuit breaker when these current pulses slightly exceed the start-up current of the drop anchor. In addition, due to this high pulse sensitivity, the known circuit breaker has very little or virtually no choice in relation to the trailing, current-limiting circuit breaker.

The object of the invention is to avoid said high retention of the anchor acting on the movable contact part and to keep small the geometrical dimensions of the iron circuit and the ampere turns of the magnetic trigger excitation coil which are required to wake up the anchor acting on the clutch lock.

In order to solve this problem, such an automatic switch according to the invention is characterized in that a magnetic side current flowing magnetically, at least partially over this working air gap, is parallel to the working air gap of the second anchor acting on the movable contact part,

As the overflow increases with the magnetic trigger excitation coil, the magnetic flux initially penetrates the movable contact portion through a side stream parallel to the working air gap of the anchor and at the same time through the working air gap of the first anchor acting on the clutch lock release lever. The amount of ampere speed required to wake up the anchor acting on the clutch lock thus determines only the working air gap of the first anchor acting on the clutch lock release lever up to the magnetic saturation of the side current opening lever. or in parallel with respect to the working air gap of the first anchor, so that it is only from this overflow that a downward force exists,

Despite the small geometrical dimensions of the iron circuit and the low ampere speed required to start the anchor acting on the switch lock, the automatic switch of the magnet trigger is a quick switch according to the invention which can of course be made in the form of a current limiting switch.

It is preferable to dimension the side current body parallel to the working air gap of the second anchor acting on the movable contact part so that it becomes magnetically saturated or changes to magnetic saturation at the peak value of the current flowing through the magnetic trigger trigger coil 1 For this purpose, the anchor acting on the movable contact part requires practically no retention but only a weak attachment, e.g. with a weak and soft spring. In addition, this ensures that the force of the anchor acting on the clutch lock no longer increases squarely above its wake-up value. For this reason, the anchor acting on the clutch release lever is not particularly sensitive to the impulse currents that enter the magnetic trigger coil (optional). Read the tolerance of the wake-up current is e.g. depends on the different possible phases of the current oscillations, the 'timing of these oscillations and the mechanical' characteristics of the circuit breaker, etc. There are safety regulations for automatic switch 4 58844 which require this tolerance range to be within predetermined limits. When the upper limit is exceeded, the automatic switch must always trip, but it does not have to trip below the lower limit. According to the terminology used in the art (cf. e.g. AEG manual 1, Basic laws in electrical engineering, Elitera-Verlag Berlin 1972, especially page 192, left column, lines 5-7), a magnetic raw material changes to magnetic saturation when its magnet constant yu = / ur. / Uq (/ ur = relative magnetic constant, / uQ = magnetic constant in a vacuum decreases from the maximum value with increasing magnetomophoric force or magnetic field force.

However, according to the published principles of the German operating model 1 79Θ 76Θ, there is a previously known automatic switch with a magnetic trigger and in which the iron strip is parallel to the air gap between the magnetic core and the immersion anchor hitting the contact part directly. However, the magnetic trigger in the master does not have a second anchor that acts on the clutch lock release lever, and the iron strip only serves to transfer a sufficiently strong magnetic stray field to the arc-arc, which thus does not receive DC current when the contacts open. The iron strip, and in particular its cross-section, is therefore dimensioned so that it is impregnated with currents which are considerably lower than the starting current of the magnetic trigger.

The invention and its advantages will now be described in more detail by means of embodiments and with reference to the drawing, in which: Figures 1 and 2 show embodiments of a magnetic trigger for an automatic switch according to the invention; Figures 1 and 2 show the flow of force in the magnetic trigger anchors of Figures 1 and 2, Figures 7 and 8 show a second embodiment of the magnetic trigger of the circuit breaker Fig. 7 and 8 show the flow of forces in the magnetic trigger anchor of Figs. 7 and B, Fig. 13 shows multipole automatic switches.

Figures 1 and 2 show magnetic triggers with an iron magnetic core 1. These magnetic triggers also have an IJ shape. second yokes 2, which are a magnetic material, e.g. iron, and which form a magnetic connection between the core 1 and the two immersion anchors 1 3 and 4. These immersion anchors 3 and 4 are coaxially interconnected. They are both arranged coaxially with respect to the guide tube 6, which is a non-magnetic material, e.g. brass, in this guide groove 6, which further has a magnetic core 1 coaxially with the guide tube 6. The outer jacket surface of the guide tube 6 has a magnetic trigger coil 5.

The magnet in the trigger of Fig. 1 has an immersion anchor 3 acting on the opening lever 7 of the clutch lock 8 placed inside a percussion anchor j acting as a cylindrical immersion anchor 4 acting directly on the movable contact part 9. The magnet in the trigger of Fig. 2 is located inside the immersion anchor 3 acting in the form of a hollow cylinder and acting as an immersion anchor 4 acting directly on the movable contact part 9 and acting on the opening lever 7 of the clutch lock 8. The magnetic trigger anchor 4 of Fig. 2 is provided with a pusher coaxial with the guide tube 6; 4a, which is a non-magnetic substance and which is guided through a magnetic core 1 made into a hollow cylinder and strikes the movable contact part 9 of the safety switch when the immersion anchor 4 is actuated. In the rest position of the two anchors of the two triggers of Figs.

In the magnetic triggers of Figures 1 and 2, the immersion anchor 3 acting on the opening lever 7 of the switch lock 8 acts as a magnetic side current body located parallel to the working air gap & 2 between the magnetic core 1 and the immersion anchor 3 acting directly on the movable contact part 9.

This magnetic side current body extends over the working air gap between the magnetic core 1 and the immersion anchor 4 and is converted to magnetic saturation by overcurrent or short-circuit currents flowing through the scraper coil 5 and in the start-up tolerance range of the anchor 3.

The magnetic substitution circuit diagram according to Fig. 3 relates to the magnetic trigger of Figs. when the magnetic side current body at the air gap S ^ is unsaturated. Through the symbolic switches and, the magnetic resistances of the supply air gap [working air gap) between the magnetic core 1 and the anchor 3 or anchor 4 are connected in parallel. The symbolic switch in the branch of the magnetic resistance of the working air gap between the magnetic core 1 and the anchor 3 extends to the magnetic resistance Rm (g ^) of the working air gap 1 between the magnetic core 1 and the anchor 3. Θ is the excitation ke, a magnetomotive force emitted by the child.Figures 3 and 4 do not take into account the very small, large-area motion air gaps between the yokes 2 and the two immersion anchors 3 and 4, because they do not in principle affect the magnets of Figures 1 and 2. triggers.

It can be seen from Fig. 3 that when the magnetic side current generated by the anchor 3 in relation to the working gap between the magnetic core 1 and the anchor 4, the initial length of which is & 2> is unsaturated, is a symbolic switch open, i. when the iron of the anchor 3 is unsupported, the magnetic flux caused by the magnetic excitation of the excitation coil 5 passes practically exclusively over the working air gap between the magnetic core 1 and the anchor 3 acting on the opening lever 7 and whose starting length is and the working air gap between the anchor 4 is magnetically saturated, so the situation corresponds to the magnetic substitution circuit diagram of Fig. 4, in which the symbolic switch S 1 is open and the symbolic switch is closed. Thus, there is an additional magnetic resistor R ^ £ 2- 51) connected in series with respect to the magnetic resistance R ^ g of the working air gap between the magnetic core 1 and the anchor 3. The sum of these two magnetic resistors corresponds to the gap between the magnetic core 1 and the anchor 4 having the same cross section as the anchor 3. with these two magnetic resistors connected in series, due to the closed, symbolic switch S2, there is a magnetic resistance of the working air gap between the magnetic core 1 and the anchor 4, which slit has the same cross section as the anchor 4 and has an initial length S1. In the case of Fig. 1 the cross-section of the anchor 4 is annular and in the case of Fig. 2 the cross-section of the anchor 3 is annular.

Fig. 5 shows a magnetic induction in the working air gap between the magnetic core 1 and the anchor 3 and a magnetic induction in the working air gap between the magnetic core 1 and the anchor 4 in the magnetic triggers according to Figs. 1 and 2 plotted magnetomotive force -Λ A, 8 = w * I (I = peak current, w = winding speed). For simplicity, the magnetic excitation required to saturate the irons of anchors 3 and 4 is marked as zero. As is known, the induction in the working gap between the magnetic core 1 and the anchor 4 is zero as long as the iron of the anchor 3 is magnetized; s t i ky 1 unsaturated, Only when the iron of the anchor 3 is already magnetically saturated does the magnetic induction increase in the working air gap between the magnetic core 1 and the anchor 4 acting directly on the moving contact part,

Figure 5, in which the magnetic force P acting on the anchors is

V A

kitty above the peak value of the magnetomotive force 0 = wl (ampere revolutions), it appears that the magnetic force acting on the anchor 3 connected to the opening lever 7 increases correspondingly squarely to the iron saturation of the anchor 3 and then increases only slightly with the linearly increasing magnetomotive force. Only after the iron impregnation of the anchor 3 does a magnetic force P 1 appear at the anchor 4 acting directly on the movable contact part 9. The anchor 3 is preferably dimensioned so that it changes to magnetic saturation at the peak value of the current flowing through the excitation coil 5 of the magnetic trigger, which current is within the tolerance range of this start-up current N / ^ 2 ^ w, (N = | T ~ 2w I ampere-cycle). magnetically impregnated.

If a short-wave image current flows through the excitation coil 5 of the magnetic trigger according to Figs. 1 and 2 at the level of the start-up current of the anchor 3 acting on the opening lever 7 of the switch lock 7, the magnetic force P1 acting on the anchor 3 increases squarely and generally produces several sides. after opening the clutch lock. If the excitation coil 5 exhibits a current pulse with a duration equal to or less than the AC half-wave, then a portion of the current exceeding the start-up current tolerance range N / l / "~ 2w of the anchor 3 achieves only a small increase in force obtained from an approximately linear increase in force P 1. so that the opening occurs upstream of pulses that are much larger than the opening of the armature start current. both the opening of the cases will switch lock Θ triggered and the movable contact portion 9 will be moved in the direction of arrow 9a in the direction away from the fixed contact portion 10 of larger lyhytsu connection lkuvirt.ojen increases after magnetic saturation of the armature 3 iron Figure 6 also the magnetic force on the anchor 4. the relatively weak tension of the anchor 4. The return force is quickly overcome and the anchor 4 accelerates more and more β 58844 as the length of the air gap between it and the magnetic core 1 Especially the example n with higher short-circuit currents the movement of the anchor 4 can take place completely independently of the movement of the anchor 3 acting on the opening lever 7, both movements depend only on the magnitudes of the magnetic force and the accelerated mass, and when the short-circuit currents are substantially greater than the start-up current, it is always permissible and even and by means of a corresponding determination of the anchor masses, the anchor 4 acting as an impact anchor immediately opens the movable contact part 9 to be used with the clutch lock 1, before opening the clutch lock 8. Since the increasing force also affects the immersion anchor 3 connected to the release lever 7, in this case the clutch lock is opened in fractions of a millisecond after the anchor 4 has opened the contact, without the anchor 4 pumping the clutch lock non-release ground, the moving contact part 9. With a large short-distance rapid opening, together with a sufficiently high arc voltage, provides a current limitation and thus a good switching capacity.

The automatic switch according to the invention with a magnetic trigger according to Figures 1 and 2 has in particular the advantage that the anchor 3 acting on the opening lever 7 only needs a relatively short air gap with respect to the magnetic core 1, the length being determined only by the geometric shape of the switch lock 8, i. release lever 7 tripping distance. Thus, the nominal starting current of the automatic switch only needs to be provided by a magnetomotive force determined by the required relatively small air gap between the magnetic core 1 and the anchor 3 connected to the opening lever 7 and possibly even the opening force of the switch lock 8. The air gap between the magnetic core 1 and the impact anchor 4 acting directly on the movable contact part 9 is completely irrelevant to the dimensioning of the magnetic trigger with respect to the anchor 3 connected to the release lever 7. This air gap can have a relatively large length so that after a long forward travel it strikes with great force and speed 9 and gives this a very high opening speed. Despite the large air gap between the magnetic core 1 and the anchor 4 (impact anchor) hitting the movable contact part 9 directly, it does not affect the dimensioning of the opening part of the magnetic trigger of Figures 1 and 2 connected to the release lever 7 with respect to the anchor 3 wake-up current. In addition, practically no retention is required for the anchor 4 acting directly on the movable contact part 9, because the effect of the force only occurs when the current flowing through the excitation coil 5 has reached approximately the value of the start-up current of the anchor 3. In general, however, a weak retaining spring 13 is used which secures the anchor 4 to the starting position shown in Figures 1 and 3.

9,58844

Since, according to Fig. 6, only a relatively small increase in force occurs in the anchor 3 connected to the opening lever 7 with currents exceeding the start-up current of the anchor 3 in the excitation coil 5 corresponding to approximately linear elevations of the curve P1. reduction is particularly suitable as a protective switch for incandescent or fluorescent lamp groups, capacitive circuits, etc. This feature is also particularly important, especially for the series circuit of current-limiting power switches. If a short circuit occurs behind a downstream current limiting circuit breaker, this downstream circuit breaker will be disarmed for less than half the AC half cycle and the unaffected short circuit current height will be limited so that only one pulsation of the current will affect the power switch located above the circuit breaker. If the latter power switch is an circuit breaker according to the invention, then it is substantially less sensitive to this single current pulse than known circuit breakers and therefore only trips at substantially higher, ineffective short-circuit currents than the known circuit breaker, so that a substantially higher optionality.

The automatic switch according to the invention provided with the magnetic trigger 1a according to Figures 7 and 8 has the same advantages. The magnet in the trigger of Fig. 7 forms a stationary body of magnetic material in the magnetic circuit of the magnetic trigger, the magnetic trigger of the magnetic trigger. This body of magnetic material consists of a hollow cylinder 15 which, at its end surface, coincides with the magnetic core 1 of the magnetic trigger. and the working air gap between the magnetic core 1 over $ 2 · The excitation coil 5 has a magnetic core 1 and a hollow cylinder 15. A drop anchor 3 is placed on the folded yoke 2, which acts on the opening lever 7 of the clutch lock 8 and is opposite the pole of the magnetic core. The pusher 4a is guided concentrically through the magnetic core 1. The magnetic core 1, the hollow cylinder 15, the ies 2 and the drop anchor 3 form a closed magnetic circuit. A return spring 14 is connected to the drop anchor 3, while the immersion anchor 4 has a weak fixing spring 14 which fixes it in the initial position shown in Fig. 7. The hollow cylinder 15 is dimensioned so that when the current flowing through the excitation coil 5 in the start current tolerance range of the drop anchor 3 reaches its peak value of 10,588,444, it becomes magnetically saturated.

The magnet in the trigger of Fig. On is a magnetic core 1 and a pin 1b on the end surface, both of which are magnetic raw material. The anchor 3 acting on the opening lever 7 of the switch lock 8 consists of a plate guided in the guide 16, which is a magnetic raw material and is provided with a return spring 11a 14. The excitation coil 5 sits on a secretion cylinder 6 in which the magnetic core 1 and pin 1b are placed coaxially. The excitation coil 5 is attached to a magnetic yoke 2, which consists of a double angle, by an annular plate 17 of non-magnetic material. The anchor acting directly on the movable contact part 9 is made as an immersion anchor 4, which is placed coaxially in the insulating material sleeve 6 and has a coaxial bore 4a in the middle, in which a pin 1b is placed. This stationary pin 1b forms a magnetic side arm relative to the air gap between the magnetic core 1 and the immersion anchor 4. The air gap between the pin 1b and the anchor 4 has a large cross section and a small length. The pin 1b is preferably dimensioned so that it becomes just magnetically saturated at the peak value of the current to the inertial current of the drop anchor 3 flowing through the excitation coil 5.

Fig. 9 shows a magnetic substitution circuit diagram, where Θ is the magnetanotoric force from the excitation coil 5, 2) is the magnetic resistance in the air gap between the magnetic core 1 and the anchor 4, R 1 -jj is the magnetic resistance in the air gap between the drop core 3 and the magnetic core 1 and is a symbolic switch which is closed when the hollow cylinder 15 or pin 1b is magnetically unsaturated and which is open when the hollow cylinder 15 or pin 1b is saturated, whereby the air gap between the magnetic core 1 and the immersion anchor 4 is initially inoperative , so. the symbolic switch is closed when the cylinder 15 or pin 1b is magnetically unsaturated. Only the working air gap with an outlet length 1 between the drop anchor 3 and the magnetic core 1 is effective. Fig. 10 shows that the symbolic switch S1 is opened when the hollow cylinder 15 or pin 1b is open, and the magnetic resistance of the air gap (output length S) between the magnetic core 1 and the immersion anchor 4 is connected in series with the air gap (output length) between the drop anchor 3 and the magnetic core 1.

Fig. 11 shows that the induction in the air gap between the anchor 3 and the magnetic core 1 and the induction in the air gap between the anchor 4 and the magnetic core 1 are plotted as a function of the peak value of the magnetic trigger magnet0 = wl (ampere revolutions) of Figs. the air gap between the magnetic core is determined only by the length of this air gap. The magnetic saturation of the iron in the hollow 11 58844 cylinder 15 or pin Ib is determined by the surface ratio (F1-F2) / F1 in Fig. 11 which is approximately 1: 2 and F1 is the cross-sectional area of the magnetic core 1 and F2 is the cross-sectional area of the anchor 4. Thus, the passage of the induction in the air gap between the anchor 3 and the magnetic core 1 is bent when a magnetic induction of about 50% of the saturation induction is achieved by means of the current flowing through the excitation coil 5. Only below this current does an increase in induction for induction B2 occur in an air gap with an initial length of ^ 2 between the magnetic core 1 and the anchor 4.

Fig. 12 shows the magnetic forces obtained as a function of the peak value of the magnetomotive force Θ = WI Cam.) And the application to the anchors 3 and 4. The tolerance range N / l / ~ 2 'w flowing through the excitation coil 5 of the anchor 3 is approximately the bend of the force curve P1 7 for the active anchor 3. In this way, it is ensured that the anchor 4 acting on the immediately moving contact part is first subjected to a magnetic force when, at low overload or short-circuit currents, the tolerance range of the start-up current of the anchor 3 is exceeded.

In the magnetic trigger of the circuit breaker according to the invention, the anchor acting on the air gap between the magnetic core and the anchor acting directly on the movable contact portion may also consist of a parallel magnetic side stream and a stationary hollow cylinder directly contacting the magnetic core. There may be an intermediate layer of non-magnetic material between the magnetic core and the hollow cylinder. By pulling out a part of the magnetic core at the end surface opposite the anchor acting on the clutch lock release lever, a part of this end surface can increase the air gap between the anchor acting on the release lever and the magnetic core and thus change the induction course and the magnetic force acting on the opening.

In particular, the automatic switch according to the invention has the advantage that the air gap of the impact anchor acting directly on the contact part and thus e.g. the contact burning and manufacturing tolerances do not affect the operation of the anchor acting on the clutch lock release lever, which requires a magnetic trigger to open the clutch lock.

As shown in Fig. 13, the invention relates not only to single-pole circuit-breakers with only one switch lock and only one magnetic trigger, but also to multi-pole circuit-breakers with at least one movable contact part per pole, a single switch lock or one switch lock for each pole. as well as a magnetic trigger for each pole which can be manufactured according to the invention. This may include line circuit breakers, power switches, and motor circuit breakers. It is particularly advantageous to manufacture a circulating power switch according to the invention and to connect a movable contact part 39 and a magnetic trigger to each of the three poles. Each of the three magnetic triggers has a trigger anchor 33 acting on the switching lock 3 luk of the circulating current switch, acting on the opening lever 37 of this switch lock 38. Three trigger anchors 33 are held by a common spring 44, so that the sum of the forces of the three trigger anchors , an impact anchor acting in each case on the movable contact part 39 connected thereto, which has a magnetic side current body 45 made in accordance with the invention in relation to the air gap. According to the German patent specification 1,588,109, this circulating current power switch has further improved optional features relative to the current limiting power switch. It achieves optional values that are practically the same as those achieved with circulating current-power switches with time-delayed magnetic triggers. The impact anchors 34 acting on the movable contact parts 39 are not affected in any way due to the engagement of the tripping anchors 33 acting on the opening lever of the three switch locks 38, so that the circulating current circuit breaker according to the invention has a high switching capacity and current limiting. It is preferred that the three release anchors 33 be rigidly connected to each other via the connectors or that they be located independently of each other on the release lever 37 of the switch lock 38. In addition, the three impact anchors 34 may preferably be connected to each other by means of connectors, acting simultaneously on three movable contact members 38. However also be unconnected and can independently influence the to the movable contact part 39.

Claims (11)

13 58844 An automatic switch, in particular a safety switch with a switch lock (8) and a magnetic trigger with two anchors (3, M and their working air gaps (-5, ύ ^) in a common magnetic circuit of this magnetic trigger, which includes a magnetic core (1) and an excitation coil) (5) and in particular the yoke (2) of the magnet, one of the anchors acting on the opening lever (7) of the clutch lock (8) and the other acting on the movable contact part (9), characterized in that the anchor (immersion anchor k) acting on the second movable contact part (9) parallel to the working air gap (5 ^) is a magnetic side current which travels magnetically, at least in part, in this working air gap (δyli. Automatic switch according to Claim 1, characterized in that the magnetic side current is dimensioned in such a way that it changes or becomes magnetically saturated when the current flowing through the excitation coil (5) of the magnetic trigger, in the start-up area of the first anchor (3) acting on the opening lever (7). Automatic switch according to Claim 1, characterized in that the magnetic side current is generated by the action of the first anchor 3 acting on the release lever (7) of the switch lock (Figs. 1 and 2). Automatic switch according to Claim 1 or 3, characterized in that the outlet air gap of the second anchor (U) acting on the movable contact part (9) is larger than the outlet air gap of the first anchor (3) acting on the clutch lock release lever (7). Automatic switch according to Claim 1, characterized in that both anchors (3, b) are immersion anchors (Figures 1 and 2). Automatic switch according to Claim 5, characterized in that the immersion anchor (3 or U) is connected coaxially to the second immersion anchor (3 and h) and is arranged coaxially with respect to the magnetic core (1) of the magnetic trigger (Figs. 1, 2). An automatic switch according to claim 1, characterized in that the magnetic side current body is formed by a body in the magnetic circuit of the stationary magnetic trigger (hollow cylinder 15 or pin Ib) which is a magnetic material (Figures 7 and 8). Automatic switch according to Claim 7, characterized in that the second anchor (1+) acting on the movable contact part (9) is an immersion anchor and in that the stationary body forming the magnetic side current body is an elongate, hollow body, preferably a hollow cylinder (15). li ik—,., 58844 illustrates an immersion anchor acting on the contact part (9) and which coincides at the end surface with the magnetic core (1) of the magnetic trigger or where this magnetic core (1) is located, (Fig. 7). Automatic switch according to Claim 7, characterized in that the second anchor k acting on the movable contact part (9) is an immersion anchor and that the stationary body forming the magnetic side current body is elongate, coaxial pin (1b) with respect to the magnetic core (1). at the end face and which engages a bore (kb) coaxial with respect to the magnetic core (1) in this immersion anchor (Fig. 8). Automatic switch according to Claim 1, characterized in that the anchor (3) acting on the release lever (7) of the switch lock is a drop anchor and the anchor (3) acting on the movable contact part is a drop anchor and the anchor (k) acting on the movable contact part (9) is an immersion anchor ). Automatic switch according to Claims 1 to 10, characterized in that each of the three poles is provided with a movable contact part (39) and an anchor (3k) acting thereon, each of which has its own magnetic trigger with a working air gap (2) for the movable contact part (39). for the magnetic side current body (k5) connected to the active anchor (3k), that in addition one switch lock (38) is additionally provided with one switch lock (38), and that in addition to the opening lever (37) of the opening lever (37) of this switch lock (38) 33) three magnetic triggers are connected together in a common retaining device {kh) (Fig. 13). 15 58844