DE2059052C - Circuit breakers, especially fault current circuit breakers - Google Patents

Description

The invention relates to a circuit breaker, in particular a fault current circuit breaker, with a driver rotatable about an axis of rotation for a release lever of a switch lock and with a holding magnet which has an armature acting on the driver and with an armature that acts on the driver or the armature of the holding magnet - in particular consisting of a release spring - release force storage whose line of action perpendicular to the axis of rotation of the driver runs at a distance from this axis of rotation ver.

A circuit breaker of this type is known from German Offenlegungsschrift 1,538,370. However, when it is switched on, a latch force is exerted on the unlatching lever of this protective switch, which force is often very large. The moment exerted by the release spring via the driver on the release lever of the switch lock must therefore be relatively high when the switch lock is released in order to overcome the possibly considerable pawl force. In the known circuit breaker, however, when the driver is rotated in the triggering direction until the sound lock is triggered, the torque generated by the trigger spring on the driver is reduced. This means that the Hall force to be exerted on the armature of the holding magnet in the I! However, this means that a sum current transformer, whose primary windings are in the known circuit breaker is in the monitored circuit, and the secondary winding of the occurrence of a Fehleisiroms il '·: Erregerspuie feeds the holding magnet, and dan; the protection switch it even large geometrical dimensions has.

The foundation is based on the task of sounding such a circuit breaker with the smallest possible size, whose holding magnet only needs to exert a small holding force and whose driver is nevertheless able to overcome the latch force acting on the release lever when the switch lock is triggered .

To solve this problem, a circuit breaker of the type mentioned is characterized according to the invention by a point of attack of the release force accumulator on the driver or on the anchor which is the distance between the line of action and the axis of rotation of the driver when the driver rotates enlarged in the direction of release and release of the key switch.

As a result, the torque transmitted from the release force store to the driver and thus also the force exerted by the driver on the unlocking lever of the switching mechanism compared to the holding force of the holding magnet is increased.

The invention and its advantages are explained in more detail with reference to the drawing.

Fig. 1 shows a holding magnet in side view for a circuit breaker in a partially open housing,

F i g. 2 shows a plan view of the holding magnet according to Fig. 1 without housing,

Fig. 3 shows the side view of the closed, the housing containing the holding devices in the switched on State of the circuit breaker,

F i g. 4 shows the side view corresponding to FIG. 2 each when the circuit breaker triggers.

According to Fig. 1, the holding magnet is at right angles bent housing 2 arranged. As shown in FIG. 2 shows, of two arranged side by side Legs 3 and 4 made of magnetically highly conductive material (e.g. a nickel-iron alloy with 70 to 80 percent by weight nickel content), which each have a recess 5 and 6 at one end. These recesses 5 and 6 are opposite one another. A permanent magnet 7 is arranged in them in such a way that that each leg rests against a different pole face of the permanent magnet 7. The armature 8, which is also consists of magnetically good conductive material (e.g. from the above-mentioned nickel-iron alloy), is located at the other end of the legs 3 and 4 opposite the pole faces of these legs. An excitation coil 9 is also arranged there on the leg 4. Between the excitation coil 9 and the Permanent magnets 7 are located in a magneüscher which causes high triggering sensitivity Shunt to the permanent magnet 7. This shunt consists of two closely spaced Approaches 10 and 11 on legs 3 and 4.

Between the approaches 10 and 11 is a thin film of magnetically poorly conductive material, /.B. an I (J μ thick aluminum foil, arranged. The legs 3 and 4 are connected to one another by a cross screw 36.

The anchor K is attached to an arm 13 which has a bow! 30 has two legs 31 which are each provided with a l.ugcrbohrung 32 and are rotatably mounted on a shaft 14 about the shaft 14. The shaft 14 is rotatably supported in a passage υ in the side wall 16 of the housing 2, which is only partially shown in FIGS. The axis of rotation of the armature 8, which coincides with the longitudinal axis of the shaft 14, is also perpendicular to the plane of the drawing in FIG.

In the housing 2 a Drehfedci 33 is arranged concentrically to the shaft 14, which is supported on the housing 2 and on the arm 13 of the armature 8 and seeks to rotate the armature 8 in the direction of the pole surfaces of the legs 3 and 4. The shaft M is also provided within the housing 2 with a dowel pin 34 which only takes the arm 13 with it when the shaft 14 is rotated in the triggering direction according to arrow 28.

The arrow 15 symbolizes that of the legs 3 which act on the armature 8 in the switched-on state and 4 of the Hall magnet outgoing holding force. In Fig. 1, the armature 8 is shown in the switched-on state and the position of the armature :; 8 at Triggering of the circuit breaker indicated.

According to FIG. 3, in the same parts with the same Reference symbols as in FIG. 1 and which shows the holding magnet in the switched-on state of the circuit breaker sits outside the housing 2 the side wall 16 on the shaft 14 a rotatable about the axis of rotation of the armature 8 driver 17 for cine.i unlocking lever 18 of a not shown Switch lock ^. One arranged between two tongues 17 a on the driver 17 and on the shaft 14 Another dowel pin 35 fastened outside the housing 2 ensures that the driver 17 drives the shaft 14 rotates in both directions of rotation when turning. The unlocking lever 18 is through the driver 17 to one to the plane of the Γ i g. 3 vertical axis of rotation 19 rotatable. The switch lock, not shown, is arranged in the circuit breaker so that the Shaft 14 and thus the axis of rotation of the armature 8 is parallel and stationary with respect to the axis 19.

The unlatching lever 18 sits on a shaft 18a, the longitudinal axis of which coincides with the axis of rotation 19 and which is arranged on the switch lock (not shown) so that it can rotate about its longitudinal axis. The shaft 18a is provided with a partial shaft 186, on which a pawl 20 of the switching mechanism, which is otherwise not shown, rests, which pawl 20 can pivot about an axis 21 parallel to the axis of rotation 19. When the switch is switched on, the pawl 20 exerts a considerable pawl force in the direction of the arrow 22 on the outer surface of the partial shaft 18 ft.

At the end of an arm 23 of the driver 17 and on a stationary pin 24 on the side wall 16 of the housing 2 of the holding magnet, a tension spring consisting of a helical spring 25 is attached perpendicular to the axis of rotation of the armature 8 as a release spring. The curve line 26 of the helical spring 25 is thus perpendicular to the axis of rotation of the armature 8, which coincides with the longitudinal axis of the shaft 14, and is at a distance from this axis of rotation when the protective switch is switched on, in which the armature 8 is in contact with the PnÜlachen Jei legs 3 and 4 Ci ₁ . In the direction of the shaft 14, the helical spring 25 is advantageously provided with a web 27, which is beneficial for the shaft 14, especially when the holding magnet is held in place. Du: Actual line 26 of the helical spring 25 is arranged in such a way that the helical spring 25 tries to rotate the driver 17 in the triggering direction of the armature 8 indicated by the arrow 28. In addition, the coil spring 25 is on the Se: '. of the shaft 14, on which the distance / between its line of action 26 and the axis of rotation of the armature 8 coinciding with the I.angsach-e of the shaft 14 increases when de! Armature 8 in tripping direction according to arrow 28 in the jjesirichel 'in Fig. 1. shown. Lie on the trigger. Is turned towards one another

Fig. 4 illustrates d'-n tripping process on the holding magnet. If the / * nker8 is released by the legs 3 and 4 of the holding magnet when a fault current flows through the primary windings of the summation current transformer (not shown) located in the circuit breaker, the secondary winding of which is connected to the excitation coil 9, the driver 17 and the armature 8 are released from the a tension-exerting helical spring 25 rotated against the action of the torsion spring 33 about the longitudinal axis of the shaft 14 in the direction of the arrow 28. As can be seen, the distance α, the line of action 26 from the axis of rotation of the armature 8 coinciding with the longitudinal axis of the shaft 14 when the unlatching lever 18 is actuated by the driver 17 is considerably greater than the corresponding distance «] in the switched-on state according to FIG Helical spring 25 is advantageously arranged in such a way that its expansion when the driver 17 is rotated from the switch-on position according to FIG. 3 into the position when the switch lock not shown is triggered changes only slightly or practically not at all. Therefore, the tensile force of the helical spring 25 practically never changes when the armature 8 is turned into the release position. and when the circuit breaker is triggered, the coil spring 25 exerts a considerably greater moment on the driver because of the greater distance a ..

17 than in the switched-on state according to FIG. 3, in which the distance α is very small. D, r driver 17 transmits a force to the unlocking lever 18 when the circuit breaker is triggered, which force is large enough to overcome the latch force emanating from the switch lock in accordance with PHl 22, so that the unlocking lever 18 is rotated by the driver 17 in the direction of arrow 37 and the pawl 20 with the release of the switch lock, not shown, from Teilwt ¹ '. ¹

18 b slides off.

The torque transmitted by the helical spring 25 in the switched-on state to the shaft 14 and the armature 8 and the holding force 15 to be exerted on the armature 8 by the legs 3 and 4 of the holding magnet are so with the same pawl force 22 and with practically the same tensile force of the helical spring 25 Kiemer, the closer the line of action 26 in the switched-on state to the axis of rotation of the armature 8 coinciding with the longitudinal axis of the shaft 14, the smaller the distance O ₁ .

During the triggering of the switch lock (not shown) after the pawl 20 has slid off of the half-shaft 18 ft, the driver 17 of

the switching shaft of the circuit breaker carrying the movable switching contacts, not shown a connecting part, also not shown, hung on the hook 29 of the driver 17 against the arrow 28 via the connection part shown in FIG. 3 shown in- switch position turned out. As a result, the dowel pin 34 lifts off the arm 13, which ensures is that the armature 8 is applied by the torsion spring 33 to the pole surfaces of the legs and 4.

Conveniently, the maximum distance of the web 27 of the helical spring 25 from the line of action 26 of this helical spring 25 is less than half the diameter of the shaft 14. Since the web 27 in FIGS. 3 and 4 runs parallel to the line of action 26, it has the line of action 26 everywhere Distance a ₃ , which is smaller than half the diameter of the shaft 14. The line of action 26 is located on the same side of the web 27 as the shaft 14. In this way, the shaft 14 prevents the line of action 26 after the triggering of the protective sounder from the side of the longitudinal axis of the shaft 14, on which the web 27 is located, skips to the other side of the longitudinal axis and the helical spring 25 on the driver 17 finally exerts a moment that this driver 17 against the Arrow 28 seeks to rotate. It is therefore ensured that the driver is rotated again by the helical spring 25 in the direction of arrow 28 into the switched-on position shown in FIG Circuit breaker switched on again by actuating a manual control element (not shown)) and in the process the connecting part, not shown, suspended from the hook 29, is released from the switching shaft, also not shown.

1 sheet of drawings

Claims (3)

Patent claims: ! Circuit breakers, especially residual current circuit breakers, ir.it a driver, which can be rotated around an axis of rotation, for a notch lever a * - switching ·. * hio-se · - as well as with a Haliemagneien, dci one on the carrier having acting anchor, and with one on the driver or on the anchor of the Haltemugiie- η th attacking triggering force - in particular consisting of a triggering spring - peieher, desse'i line of action perpendicular to the axis of rotation of the driver at a distance from this axis of rotation runs marked by an anir handle of the trigger plate on the driver (17) or in the anchor (S), at the sic'ii der Distance d_; Line of action (26) from the drive axis of the driver (17) when turning the Driver (17) in the release direction and release of the key switch enlarged. 2. Circuit breaker according to claim 1, characterized by a helical spring (25) trained Ausiosekraftsfeicher, who on the Side of the common axis of rotation of driver (I7) and armature (8) is arranged on the the distance of its line of action (26) from the axis of rotation when turning the driver in Trigger direction enlarged. 3. Circuit breaker; iarh. Claim 2, characterized by an anchor (8), which with the driver (17) on a g. a single wave (14) sits, the longitudinal axis of which is aligned with the axis of rotation of the driver (17) and armature (8), and by a helical spring (25) which has a web (27) in the region of the shaft (14), the The maximum distance from the line of action (26) of the helical spring (25) is less than half Diameter of the shaft (14). 40