DE102010032030B4 - Electrical switch - Google Patents

Abstract

Electrical switch with
- at least one controllable tripping magnet (10) with armature (20),
- a pivotable pawl shaft (30) which is operatively connected to the armature (20), which interacts with a downstream pivotable tripping shaft (40) and is latched to the tripping shaft (40) when the switch is switched on, with activation of the tripping magnet (10) The armature (20) moves and the pawl shaft (30) pivots, thereby releasing the latching between the trip shaft (40) and the pawl shaft (30) and the trip shaft (40) directly or indirectly switching off the switch,
- A handle (70) for switching the switch on and off and
- a resetting lever (80) which is pivotable about a pivot point (90) in a pivoting plane and which interacts with the handle (70) and the tripping shaft (40) and when the switch is switched off by means of the handle (70) from the handle (70) is pivoted and the tripping shaft (40) pivots into the latched position with the latch shaft (30).

Description

The invention relates to an electrical switch with at least one controllable tripping magnet with an armature.

Such an electrical switch is sold by the SUSOL company under the product name SUSOL250A. In the case of the previously known switch, a rotary movement of the switching mechanism of the switch is converted into a linear movement in order to reset or “reset” the switch.

The invention is based on the object of specifying an electrical switch which has few parts and can be manufactured simply and inexpensively.

In the DE 689 07 424 T2 discloses an auxiliary trip block with an insulating housing for lateral attachment and coupling to a multi-pole circuit breaker block. The auxiliary trip block is provided with a latch between a rocker arm and a dial pivoted on a fixed first axis between a cocked position and an uncocked position and with an intermediate reset lever which automatically resets a relay when the dial moves to the uncocked position, wherein said lever being pivoted on a fixed second axis of the housing.

In the U.S. 6,380,829 B1 describes an operating mechanism having an operating handle movable between on and off positions, the operating handle extending substantially upwardly at a point between the on and off positions; a crank for controlling a contact arm of a circuit breaker to cause the contact arm to move between open and closed positions as the crank moves; mechanism springs connected between the operating handle and the crank such that the crank moves when the mechanism springs are discharged and when the operating handle is moved between on and off positions; a trigger lock that prevents unloading of the mechanism unless moved; and a trigger having a lever arm, the trigger being biased by a trigger spring to cause the trigger to extend substantially upwardly from the operating mechanism and move the trigger latch and unload the mechanism springs unless the trigger is unable to rotate underneath the influence of the trigger spring.
In the U.S. 2004 022 7601 A1 discloses an arrangement for cooperating with a circuit breaker operating mechanism of a circuit breaker comprising a housing and a pair of contacts within the housing, the operating mechanism enabling the pair of contacts to be separated upon the occurrence of a trip event.

In the JP 2719436 B2 a structure for resetting a lever is disclosed. With normal tension, neither a link nor a lever is rotated. If the voltage drops, the lever is turned clockwise. A trip device is triggered, opening a contact. If a handle operation resets while a breaker is tripping, a crossbar is rotated clockwise, causing the lever to rotate counterclockwise. Because the crossbar resets an undervoltage trip device, the device need not be provided with a special reset structure.

According to the invention, this object is achieved by an electrical switch having the features according to patent claim 1 . Advantageous configurations of the switch according to the invention are specified in the dependent claims.

According to the invention, an electrical switch is provided with at least one controllable tripping magnet with an armature, a pivotable pawl shaft which is operatively connected to the armature, which interacts with a downstream pivoting tripping shaft and is latched to the tripping shaft when the switch is switched on, with the armature moving when the tripping magnet is activated shifts and pivots the pawl shaft, thereby canceling the latching between the release shaft and the pawl shaft and the release shaft directly or indirectly switches the switch off, a handle for switching the switch on and off and a reset lever which is pivotably mounted about a pivot point in a pivot plane and which is connected to the handle and interacts with the tripping shaft and is pivoted by the handle when the switch is switched off by means of the handle and the tripping shaft pivots into the latched position with the latch shaft.

An essential advantage of the electrical switch according to the invention can be seen in the fact that a decoupling between the reset function and the tripping function is ensured. The decoupling ensures better power transmission from the handle to the release shaft. In addition, intermediate elements for transmitting the force can be omitted.

In order to achieve a particularly good power transmission between the handle and the reset lever achieve, it is considered advantageous if the reset lever has a projection extending away from the pivot point in the pivot plane and which interacts with the handle.

The projection particularly preferably has a convex and a concave section. The convex section and the concave section are preferably arranged in such a way that when the switch is pivoted in the direction of the switched-off position, the handle first presses on the convex section and then slides into the concave section during the pivoting movement of the reset lever. This sliding movement ensures particularly efficient power transmission.

The convex section and the concave section preferably adjoin one another in order to ensure that the elements can be pivoted with little force.

In a particularly preferred embodiment, it is provided that the projection of the reset lever has an at least approximately S-shaped contour—seen perpendicularly to the pivot plane.

In the case of an S-shaped contour, it is considered particularly advantageous if a contour section of the S-shaped contour forms the convex section of the projection and a further contour section of the S-shaped contour adjoining this contour section forms the concave section.

In addition, it is considered advantageous if the reset lever has a projection extending perpendicularly to the pivoting plane, which interacts with the release shaft and pivots the release shaft into the latched position with the latch shaft when the reset lever is pivoted. Accordingly, it is therefore considered advantageous if the reset lever has two projections which extend at least approximately perpendicularly to one another, one projection being perpendicular to the pivoting plane and the other projection lying within the pivoting plane.

The distance between the projection extending perpendicularly to the pivot plane and the pivot point of the reset lever is preferably smaller than the distance between the pivot point and the projection extending away from the pivot point in the pivot plane of the reset lever.

A torsion spring preferably acts on the reset lever, which is supported on the housing of the tripping device of the switch or the switch housing and exerts a pivoting torque on the reset lever in the direction of the handle. Such a torsion spring ensures that defined positions of the reset lever are always assumed.

With a view to achieving particularly high stability with low weight at the same time, it is considered advantageous if the reset lever has an at least partially planar rear wall on the side facing the release shaft and a ribbed structure on the side facing away from the release shaft.

It is also considered advantageous if the pawl shaft is spring-loaded in such a way that, when the release shaft is pivoted by the reset lever, it automatically pivots into the position latched to the release shaft.

The trip shaft preferably has a reset portion which, after the latch has been released, pivots between the trip shaft and the pawl shaft and is pressed against and pivots the pawl shaft, whereby the pawl shaft resets the armature into the trip magnet. Alternatively, it can also be provided that the reset section of the tripping shaft directly displaces the armature and pushes it back into the tripping magnet itself.

• 1 Bestandteile eines Ausführungsbeispiels für einen erfindungsgemäßen elektrischen Schalter in der eingeschalteten Position,
• 2 den Schalter gemäß 1 nach einem Auslösen eines Auslösemagneten,
• 3 den Schalter gemäß 1 nach einem Verschwenken einer Handhabe des Schalters in eine mittlere Schaltposition („Trip-Position“),
• 4 die Schaltposition gemäß 3 in einer dreidimensionalen Sicht schräg von oben,
• 5 den elektrischen Schalter gemäß 1, nachdem die Handhabe des Schalters in eine ausgeschaltete Position („Aus-Zustand“) gebracht worden ist,
• 6 den Schaltzustand gemäß 5 in einer dreidimensionalen Sicht von schräg oben,
• 7 den Schaltzustand gemäß 5 in einer anderen dreidimensionalen Sicht, und
• 8-9 andere dreidimensionale Sichten auf die Komponenten des elektrischen Schalters gemäß 1.

The invention is explained in more detail below using an exemplary embodiment; show examples

• 1 Components of an embodiment of an electrical switch according to the invention in the switched-on position,
• 2 according to the switch 1 after a triggering magnet has been triggered,
• 3 according to the switch 1 after a handle of the switch has been pivoted into a middle switch position (“trip position”),
• 4 the switch position according to 3 in a three-dimensional view obliquely from above,
• 5 according to the electric switch 1 after the handle of the switch has been moved to an off position (“off state”),
• 6 according to the switching status 5 in a three-dimensional view from above,
• 7 according to the switching status 5 in another three-dimensional view, and
• 8-9 other three-dimensional views of the components of the electrical switch according to FIG 1 .

For the sake of clarity, the figures always use the same reference symbols for identical or comparable components.

In the 1 are exemplary components of an embodiment of an electrical switch according to the invention. You can see in the 1 a controllable release magnet 10 which interacts with an armature 20. In the representation according to 1 the armature 20 is pushed into the tripping magnet 10 so that only the right-hand edge of the armature 20 can be seen.

In the 1 one can also see a pivotable pawl shaft 30 which is operatively connected to the armature 20 and which interacts with a pivotable release shaft 40 arranged downstream. It can be seen that at the in the 1 illustrated switched-on state of the electrical switch, a section 50 of the pawl shaft 30 bears against an associated section 60 of the release shaft 40, so that the pawl shaft 30 is latched to the release shaft 40 when the switch is on.

In the 1 one recognizes also a handle 70 of the electrical switch, which when the switch is on in the 1 is pivoted to the right and thus assumes its "on" position.

the 1 also shows a reset lever 80, but in the case of FIG 1 shown view is covered both by the release magnet 10 and by the release shaft 40 substantially.

In the 2 a switching state of the electrical switch is shown after the armature 20 has been displaced to the right by the controllable tripping magnet 10 and pressed against the pawl shaft 30 . By pivoting the pawl shaft 30, the section 50 of the pawl shaft 30 is pivoted away from the section 60 of the release shaft 40, so that the spring-loaded release shaft 40 can now pivot clockwise along the direction of the arrow P1.

In the 3 1 shows the position of the switch components after the trip shaft 40 has been pivoted along the direction of arrow P1. By pivoting the release shaft 40 are by cams of the release shaft 40 in the 3 not shown switching contacts of the switch directly or indirectly separated and switched off the switch. By turning off the switch also the handle 70 in the 3 counterclockwise, ie along the direction of the arrow P2 pivoted. The handle 70 now assumes its middle switch position, which will be referred to below as the “trip position”.

In the 3 it can also be seen that the latch shaft 30 has also been pivoted as a result of the pivoting of the tripping shaft 40 . In order to achieve this pivoting, the tripping shaft 40 is equipped with a return section which, after the latching between the two sections 50 and 60 has been released (cf. 1 and 2 ) is pivoted and pressed against the pawl shaft 30, so that the pawl shaft 30 pivots in the direction of the armature 20 and thereby pushes the armature 20 back into the tripping magnet 10. the 3 shows the switching situation after the tripping shaft 40 has pivoted the pawl shaft 30 and the pawl shaft 30 has pushed the armature 20 back.

In the 4 is the switching state according to 3 shown again in a three-dimensional view. You can see the pawl shaft 30, which is pressed onto the anchor, and the release shaft 40 and the handle 70. In addition, can be in the 4 the reset lever 80 can be seen in more detail. The reset lever 80 is mounted pivotably about a pivot point 90 and has a first projection 100 which extends away from the pivot point 90 in the pivot plane and interacts with the handle 70 .

In addition, one recognizes in the 4 a second projection 110 which extends perpendicularly - at least approximately perpendicularly - away from the pivot plane and interacts with the tripping shaft 40 . When pivoting the reset lever in the 4 downwards, the second projection 110 will press a lever arm section 120 of the release shaft 40 downwards and thus the release shaft into the in 1 pivot position shown and latched to pawl shaft 30; this is explained in more detail below.

In the 4 it can also be seen that the distance between the second projection 110, which extends perpendicularly to the pivot plane, and the pivot point 90 is smaller than the distance between the pivot point 90 and the first projection 100, which extends away from the pivot point in the pivot plane.

The reset lever 80 is preferably connected to a torsion spring which is supported on the housing of the tripping device of the switch and on the reset lever 80 a pivoting torque in the direction of the handle 70 - ie in the 4 up - exercises.

the 4 also shows that the reset lever 80 on its release shaft 40 or the side facing the release magnet 10 has a rear wall 130 that is planar at least in sections. On the side facing away from the tripping shaft 40 or the tripping magnet 10, the reset lever 80 is provided with a rib structure 140, for example in FIG 8th is clearly recognizable.

the 8th also shows the pivot point 90 and the first projection 100 in more detail. This is how in the 8th recognize that the first projection 100--seen perpendicularly to the pivot plane--has an at least approximately S-shaped contour 150. A contour section of the S-shaped contour 150 forms a convex section 160 of the first projection 100, and a further contour section of the S-shaped contour 150 adjoining this contour section forms a concave section 170 of the projection 100.

As in the 8th As can also be seen, the convex section 160 and the concave section 170 of the projection 100 are arranged in such a way that when the switch is pivoted in the direction of the switched-off position, the handle 70 first presses on the convex section 160 and only then during the pivoting movement of the reset lever 80 slides into the concave portion 170.

In the 5 the electrical switch is shown after the handle 70 has been pivoted counterclockwise--along the direction of arrow P2--and pivoted to the "off" position. It can be seen that by pivoting the handle 70 of the reset lever 80 in the 5 has been pushed down and thereby the release shaft 40 back into the 1 shown position has pivoted. The trigger shaft 40 is pivoted by the second projection 110 according to FIG 4 , which presses the lever portion 120 of the release shaft 40 when the reset lever 80 is pressed down.

By pivoting the trigger shaft 40, it is the spring-loaded pawl shaft 30 possible, back in their in the 1 to pivot the starting position shown and to latch with the trip shaft 40 in such a way that the section 50 of the latch shaft 30 is latched with the section 60 of the trip shaft 40 .

The pivoting of the handle 70 in the 5 The "off position" shown is also shown again in three-dimensional representations in the 6 and 7 shown. It can be seen how a section 200 of the handle 70 first presses on the convex section 160 and then on the concave section 170 of the reset lever 80 and pivots it, as a result of which the corresponding turning of the release shaft 40 by means of the second projection 110 of the reset lever 80 is triggered.

In the 9 the release magnet 10, the reset lever 80, the release shaft 40 and the handle 70 are shown again in a different three-dimensional representation for better understanding.

reference list

10

trigger magnet

20

anchor

30

jack shaft

40

trip wave

50

section

60

section

70

handle

80

reset lever

90

pivot point

100

head Start

110

head Start

120

lever arm section

130

back panel

140

rib structure

150

S-shaped contour

160

convex section

170

concave section

200

section

P1

arrow direction

p2

arrow direction

Claims (10)

Electrical switch with - at least one controllable tripping magnet (10) with an armature (20), - a pivotable pawl shaft (30) which is operatively connected to the armature (20), which interacts with a downstream pivotable tripping shaft (40) and, when the switch is switched on, with the tripping shaft (40) is latched, with activation of the tripping magnet (10) shifting the armature (20) and the latch shaft (30) pivoting, thereby canceling the latching between the tripping shaft (40) and latch shaft (30) and the tripping shaft (40) directly or indirectly turns off the switch, - a handle (70) for switching on and off of the switch and - a resetting lever (80) pivoted about a pivot point (90) in a pivoting plane, which interacts with the handle (70) and the tripping shaft (40) and when the switch is switched off by means of the handle (70) by the handle (70) is pivoted and the tripping shaft (40) pivots into the latched position with the latch shaft (30). switch after claim 1 , characterized in that the reset lever (80) has a projection (100) which extends away from the pivot point (90) in the pivot plane and which interacts with the handle (70). switch after claim 2 , characterized in that the projection (100) has a convex (160) and a concave (170) portion. switch after claim 3 , characterized in that the convex (160) section and the concave (170) section are arranged in such a way that the handle (70) when pivoting in the direction of the switched-off position of the switch first presses on the convex (160) section and then during the Pivotal movement of the reset lever (80) slides into the concave (170) section. Switch according to any of the above claims 3 - 4 , characterized in that the convex (160) portion and the concave (170) portion are adjacent to each other. Switch according to one of the preceding claims, characterized in that the projection (100) - viewed perpendicularly to the pivot plane - has an at least approximately S-shaped contour (150). switch after claim 6 , characterized in that a contour section of the S-shaped contour (150) forms the convex (160) section of the projection (100) and a further contour section of the S-shaped contour (150) adjoining this contour section forms the concave (170) section. Switch according to one of the preceding claims, characterized in that the reset lever (80) has a projection (110) which extends perpendicularly to the pivot plane and which interacts with the release shaft (40) and when the reset lever (80) pivots, the release shaft (40) into the latched position with the pawl shaft (30). Switch according to one of the preceding claims, characterized in that a torsion spring acts on the reset lever (80), which is supported on a housing and exerts a pivoting torque on the reset lever (80) in the direction of the handle (70). Switch according to one of the preceding claims, characterized in that the pawl shaft (30) is spring-loaded in such a way that when the tripping shaft (40) is pivoted by the reset lever (80), it automatically pivots into the latched position with the tripping shaft (40).

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