DE2258607C2 - Overcurrent switch - Google Patents

Description

The invention relates to an overcurrent switch with a fixed contact, with a movable contact lever, that by means of elastic elements (compression spring) in the disconnection direction and thus in the lift-off position the fixed contact is biased, and with a switching device, the one hand the movement and the retention of the movable contact lever in the switched-on position and, on the other hand, the release of the movable contact lever Contact lever based on at least one trigger pulse such as a magnetic circuit, a bimetal trigger (Bimetallic strip) or the like ensures, with a switch handle against the bias an elastic element (leg spring) is movably arranged and equipped with a profile curve, a latching lever which can be pivoted by the release element or elements is supported on the contact lever and wherein a locking pin for the latching lever is provided in a slot guide in the housing is.

The field of application of the invention is in particular the protection of circuits in electrical installation networks and distribution networks.
The following requirements are to be made of an overcurrent switch: The space requirement must be as small as possible so that the overcurrent switch can be installed in a wall of shallow depth or in a control cabinet of shallow depth. On the other hand, the overcurrent switch should have as high a breaking capacity as possible, because the installed connection capacities are getting bigger and bigger.

An overcurrent switch mentioned at the outset An is known from DE-OS ~ /> 18 01 014th With this

manned switch, the latching is done by locking ; operation of a pawl that engages in a fixed, pin-shaped detent The lock of the switch in the on position takes place separately from this ·· latching, pdem a nose of a rocker arm in a recess of a Leg engages a leaf spring. As during the switch-on movement the latching and the locking or latching are effected separately from one another, a precise coordination of the relevant components and their kinematics is required. The separated constructive training of the two functions requires a comparatively large number of components. You need three springs for the function of this switch, namely a leaf spring for the latching, one Helical spring for the contact pressure and a spring acting on the pawl.

The object of the invention is the functional linkage of the latching and the locking.

This object is achieved according to the invention by that the locking pin can be moved in contact with the profile curve of the switch handle and that the profile curve of the switch handle ends in a Rastprofü for latching retention of the locking pin, the Locking pin on the one hand the locking of the latching lever and on the other hand the latching of the Ensures switching handle

According to the invention, the locking pin takes over both the latching function and the locking or latching of the overcurrent switch. As a result, you only need a spring, but that has numerous tasks, namely the opening of the movable contact and the closing movement bias of the latching lever, the provision of the contact pressure for the contact lever and the Fixed contact The invention leads to a reduction in the number of components. This takes the moving elements comparatively little space, so that in proportion a large space for the arc quenching chamber is available This increases the breaking capacity. The formation of contact erosion is reduced In addition, the use of several release elements is possible, which increases operational safety of the overcurrent switch is increased.

According to a preferred embodiment of the invention it is provided that the movable contact lever on the housing or a housing extension with a Pivot pin and slot guide that are opposite the contact plane of the movable contact lever with the Fixed contact is inclined, is attached so that the return spring (compression spring) of the contact lever a displacement the contact point on the fixed contact causes the return spring to act for the contact lever as a return element when lifting the contact lever and on the other hand to provide the contact pressure in closed position. On the one hand, this means a reduction in the number of components required for the Overcurrent switch and, on the other hand, the use of a rigid contact lever. This is more economical than the use of compliant contact levers. For the contacts of overcurrent switches are anyway High quality materials required.

The inclination of the sliding guide in relation to the contact plane ensures self-cleaning. This will also caused by the return spring for the contact lever, because the contact lever slides in the closing division via the fixed mating contact. As a result, the contact quality is retained over time.

A preferred embodiment of the invention is explained below with reference to the drawings in which represent

^{1 shows} an overcurrent switch in the closed position with the housing half removed, partially in section, FIG. 2 shows a detail of FIG. 1 on an enlarged scale,

F i g. 3 is an enlarged perspective partial view of various elements of the overcurrent switch Scale,

F i g. 4 shows a partial section along the line IV-IV in FIG. 1,

F i g. 5 is a partial view in the direction of arrow V in FIG. 1, 6 shows a perspective partial view in the direction of the arrow VI of Fig. 1,

F i g. 7 is a partial view corresponding to FIG. 1 for the tripping position of the overcurrent switch and

F i g. 8 is a partial view corresponding to FIG. 1 to explain the trip-free release.
The overcurrent switch according to the invention is completely enclosed in a housing OK. The underside of this housing 10 is designed as a clamping plate 11, which is intended for fastening the overcurrent switch to an equilateral flange rail. This clamping plate can also be used for a different type of loading

fastening of the overcurrent switch be formed on any carrier.

At a distance from this clamping plate 11 forms the Housing 10 a parallel to the clamping plate aligned chamber 12, which the switching device 13 of the over-current switch records

Subsequent to the clamping plate 11, a first connection terminal 14 is arranged next to one another the outside of the housing, which is electrically connected to a fixed contact 15 within the housing is, an arc chamber 16, a bimetallic strip 17 and a second terminal 19 on the Outside of the housing 10. The arc extinguishing chamber 16 contains deionization plates 20, which are at run inclined to the clamping plate 11 in the illustrated embodiment. This known arrangement allows either the same size of the arc extinguishing chamber 16 to the same height reduce and thereby the available height for the chamber 12 for receiving the switching device 13 and to enlarge the corresponding release elements or longer with the same size of the switching chamber Use deionization chambers and thereby a larger volume of the arc extinguishing chamber 16 reach. You can also use both options together combine.

The terminal 19 has a leg 21, the inside of the housing 10 has two lateral claws for has an entrapment in said housing. These claws 22 form a pivot bearing and enable a deformation of the leg 22 under the influence of an adjusting screw 23 which is inserted into a threaded hole 24 of said leg engages, see FIG. 1 and 5. The leg 21 carries the bimetallic strip 17, which is welded, for example. With the help of the screw 23 you can adjust the position of this bimetallic strip adjust. One end of the bimetal strip 17 is directly connected to a connecting terminal 19 tied together.

The bimetal strip 17 forms a first release element. A second trigger element, namely a magnetic circuit 18, is above the arc extinguishing chamber 16 between the same and the switching device 13 arranged.

The magnetic core 26 of the magnetic circuit 18 is parallel slidable to the clamping plate It and is by a Spring 46 preloaded in the initial position. The winding 27 for controlling the magnetic circuit is electrical on the one hand via a line 28 to the bimetal strip 17 and on the other hand to a metal housing 29 connected, which serves as a carrier for the magnetic circuit 18. The magnetic core 26 has a free end Slot 47, FIG. 3.

The arrangement of the deionization plates 20 is limited by pole plates 30 and 3t. The pole plate 30 is electrically connected to the fixed contact 15 and forms an extension of the same. The pole plate 31 is electrically connected to the metal housing 29 of the magnetic circuit 18 and forms a stop 36 for the Metal case 29.

The pole plates 30 and 31 are also electrical with the respective adjacent deionization plates tied together. For this purpose, a respective tongue 32 is used, which by cutting free an opening 33 in the relevant Pole plate is formed. This tongue is bent up so that one can make contact with the associated Deionization plate obtained (Figs. 1 and 6).

At the lower edge, the pole plates 30 and 31 each have a cutout 34 that opens onto a labyrinth canal 35 is aligned, which is incorporated into the housing 10. This labyrinth channel is used in each case for connection the arc extinguishing chamber 16 with the outside space.

The fixed contact 15 is curved, and a core 37 is made of in the space left free thereby inlaid with soft iron.

The fixed contact 15 is assigned a movable contact lever 40 which is attached to the housing 10 or an approach or a carrier that is connected to the same, is hinged. For this purpose there is a swivel-slide connection intended. The movable contact lever 40 carries a pivot pin 41 which is pivotable and is slidably received in a slot guide 42 fixed to the housing. This slot guide 42 runs inclined to the clamping plate 11. This inclination of the slot guide 42 has for the desired self-cleaning some meaning. It can also be vanishing.

The slot guide 42 can be designed as an opening in the housing wall.

The contact lever 40 ends in a U-bend 43 which cooperates with the fixed contact 15. In one middle area is according to FIG. 3 a breakthrough 44 is provided, which over the magnetic core 26 of the magnetic circuit 18 takes effect. A slot 45 extends from this opening 44. At the other end of the contact lever 40 a line piece 48 is attached, which has an electrical connection to the metal housing 29 of the magnetic circuit 18 manufactures. The contact lever 40 is subject to the action of a compression spring 49 which moves it in the lifting direction biased by the fixed contact 15 Fi g. 1 shows a compression spring, which is located on the housing 10 or on an asset graded by an approach or a carrier within the housing 10 goes out

The switching device 13 has a switching handle 50, a latching lever 51 and a locking pin 52. The switching handle SO is arranged pivotably on a pivot 53. A leg spring 54 biases the switch handle 50 in the off position. One leg of this leg spring rests on a nose 55 fixed to the housing, the other leg on a nose 56. which is firmly connected to the switch handle 50. According to FIG. 4, the sound handle 50 has a slot 58 which engages in the corresponding end of the latching lever 51 and a slide 59 which has a central longitudinal web 60 for this purpose. This Gleipfi-> slide 59 acts upon the Verklinktingshebel 51 under bias of the Bimetallslre'fens 17. The slider 59 is also in a passage 62 of the ^r: häuses out 29 of the magnetic circuit 18th The latching lever 51 is pivotable in its central area

ίο mounted on a pivot pin 63, which is in two Eyes 64 of the contact lever 40 is received. One end of the latching lever 51 engages in the Slot 45 of the contact lever 40 and into the slot 47 of the magnetic core 26; this end of the latch lever 51 is thus on the one hand between a pin 66 which holds the magnetic core 26 perpendicular to the slot 47 traversed, and on the other hand enclosed by the rear wall 67 of this slot which forms a support. The pin 66 is thus a support so that the magnetic core 26 both on the latching lever 51 as well as being able to transmit a tensile force to the contact lever 40.

At the other end of the latching lever 51 has a latching profile 70, which with the locking pin 52 cooperates. This locking pin 52 is on the one hand in a slot guide 71 in the housing 10 or in approaches of the same, and on the other hand in a slot guide 72 of the switch handle 50 movable. The edges of the slot guide 72

jo form profile guides 74a and 74i>, which are a return element form for the latching lever. The slot guide 72 ends in a latching profile 75. You can instead also use a single guide profile, on which the locking pin 52 by elastic EIemente is kept in the plant.

In the latched on position according to FIG. 1, the acts Compression spring 49 via the contact lever 40 on the latching lever 51, which is pivotable on the contact lever 40 is arranged The line of action of the force is

* u Mi / .t a component in the longitudinal axis of the latching lever in the direction of the arrow Fi in FIGS. 1 and 2. Due to this force component of the compression spring 49, the latching lever 51 becomes with the latching profile 70 held in engagement on the locking pin 52. The same in turn lies in the latching profile 75 of the Slot guide 72 of the switch handle 50. As a result, the switch handle 50 is locked in the switched-on position, in the opposite direction the effect of the leg spring 54, which biases it in the switched-off position

^{V |} The triggering of the thermal shock occurs through the magnetic core 26 of the magnetic circuit 18, which is displaceable against the action of the compression spring 46, or through the bimetallic strip 17 or through manual actuation of the switch handle 50.

When triggered by the magnetic core 26, the pin 66 transmits a tensile force to the end of the latching lever 51 and thus pivots the same about the pivot pin 63 in the direction of arrow F2 in FIG

M) the locking pin 52 free. The contact lever 40 pivots under the bias of the compression spring 49 about the pin 41; the U-bend 43 lifts from the fixed one Contact 15 from. This lifting is accelerated by the pin 66 of the magnetic core 26, which is also a Pulling action on the contact lever 40 exerts.

At the same time, the switch handle 50 is no longer held by the locking pin 52. Consequently swivels the same on its axis 53 in arrow

direction Fj of Fig. 1 until it is in the off position according to FIG. 7 is coming.

The contact lever 13 is in this switch-off position at the stop 36 of the pole plate 3! at.

When triggered by the bimetal strip 17, the same pushes the slide 59 back. This in turn presses on the latching lever 51, which pivots about its pivot pin 63. This comes about the same sequence of movements as described above is in motion. ίο

Finally, when triggered manually, the locking pin 52 is pushed out of the latching profile 75 of the slot guide 72 when the switch handle 50 is pivoted in the direction of arrow Fs, Fig. 1: the profile 74B at one edge of this slot guide causes a shift of the locking pin in the fixed slot guide 71 against the end that is closest to the pivot 53 of the switch handle 50. As a result, the latching lever 5t follows the locking pin 52 under the tension of the compression spring 49, so that the contact lever 40 is lifted from the contact 15

In the release position according to FIG. 7 holds the compression spring 46 the magnetic core 26 with the rear wall 67 of the slot 47 in contact with the latching lever 51. The same is therefore resiliently held in contact with the locking pin 52. According to a modification not shown According to the invention, the latching lever 51 itself is equipped with elastic return elements, for example with a leg spring on the pivot pin 63.

The overcurrent switch is switched on again by pivoting the switch handle 50 in the direction of the arrow Fi according to FIG. 7th

The profile curve 74Λ of the slot guide 72 moves while the locking pin 52 within the slot guide 71 against the pivot pin 63 of the latching lever 51 out. Be; this shift comes the locking pin 52 in turn with the locking profile 70 of the latching lever 51 in engagement. With white «o The Verklinkungshebei pivots a further shift the Kontakthebei 40 around the pivot pin 41 until the same is in its switched-on position according to FIG. 1 reached.

After the U-bend 43 of the contact lever 40 comes into engagement with the fixed contact 15, a Self-cleaning of the contact surface by shifting the contact point of the contact lever relative to the fixed contact, because the pivot pin 41 of the contact lever 40 moves in the inclined slot guide 42.

The core 37 made of soft iron generates an additional field when the contacts are lifted, which deletes of the arc between the contacts

The Lr.byrinthksnäle 35 allow a pressure equalization in the arc extinguishing chamber 16 by the shutdown gas, which occurs when the contacts are separated form, escape into the atmosphere. The outflow of this gas, which is in the foot area of the deionization plates20 arises, is promoted by the fact that the pole plates 30 and 31 are each electrically connected to the neighboring Deionization plates 20 are connected. Consequently no arc occurs between these pole plates and the adjacent deionization plates. They thus jointly form channels for a free outflow of the gas in question.

It is noteworthy that the circuit breaker has only a minimum number of individual parts, in particular due to the direct attachment of the bimetal strip 17 to the terminal 19 without additional Fasteners. The action of the magnetic core 26 with the pin 66 on the contact lever also contributes to this 40 and at the same time on the latching lever 51. In addition, it is based on the fact that an elastic Element (spring 46) at the same time the restoring force for the magnetic core 26 and for the latching lever 51 supplies

The parts of the fixed contact and the movable contact lever that come to rest against each other, are each curved in the release position according to FIG. 8 switching on is not possible even if an operator holds the switch handle 50 in the switched-on position.

The latch lever is balanced about its pivot pin 63; h the pivot pin 63 is located in the center of gravity of the latching lever. This becomes the moment of inertia and, consequently, the Opening time of the moving contact lever reduced.

In the overcurrent switch according to the invention, the pivot 53 of the switch handle 50, the locking pin 52 and the pivot pin 63 of the latching lever 51 both in the switched-on position as also in the lift-off exercise on a straight line. This is essential for the functional reliability of the arrangement. This arrangement also favors a better distribution of the switching device within the housing. Because the switch handle 50 can easily be placed over the center of the clamping plate II. This favors the Installation of the overcurrent switch. The exterior of the housing and the switch handle is symmetrical. Through this the appearance of the arrangement is improved.

The overcurrent switch according to the invention is compact and space-saving. This means that he has a larger available interior space with the same space requirement for the installation of various individual parts.

The return spring (compression spring 49) for the contact lifting) 40 provides the lifting and in the switching position the Contact system and the necessary contact pressure between the contact lever 4C and the contact 15 safe. These two contact elements can be designed as rigid parts, that is, inelastic.

For this purpose 3 sheets of drawings

Claims (10)

Patent claims: 1. Overcurrent switch with a fixed contact (15), with a movable contact lever (40) which is biased by elastic elements (compression spring 49) in the disconnection direction and thus in the lifting position with respect to the fixed contact, and with a switching device (13), which on the one hand ensures the movement and retention of the movable contact lever (40) in the switched-on position and, on the other hand, the release of the movable contact lever (40) due to at least one trigger element such as a magnetic circuit (16), a bimetallic release (bimetallic strip 17) or the like, with a switch handle (50) is arranged movably against the bias of an elastic element (leg spring 54) and is equipped with a profile curve (74a, 746) , with a latching lever (51) pivotable by the release element or elements being mounted on the contact lever (40) and with a locking pin (52 ) for the latching lever (51) in a slot guide (71) in the housing (10) v is esigned, characterized ge characterizing t, that the locking pin (52) in Aniage to the profile curve (74a, 74i>) of the control handle is movable (50) and that the section curve (74a, 74b) of the switching handle (50) in a latching profile ( 75) ends for the latching retention of the locking pin (52), the locking pin (52) ensuring on the one hand the locking of the latching lever (51) and on the other hand the latching of the switch handle (50) 2. Overcurrent switch according to claim 1, wherein the switching handle is pivotable on a pivot is mounted, characterized in that the pivot pin (53) of the switch handle (50), the locking pin (52) and the pivot pin (63) of the latching lever (51) essentially on a straight line lie. 3. Overcurrent switch according to claim 1 or 2, characterized in that as a biasing element a compression spring (49) is provided for the movable contact lever (40) and that in the switched-on position the compression spring (49) exerts a longitudinal force on the latching lever (51) in the direction of the locking pin (52) 4. Overcurrent switch according to one of claims 1 to 3, wherein the magnetic core (26) at one end has an actuating element which is used to transmit a tensile force to the movable contact lever (40) is suitable, characterized in that the actuating element on the magnetic core (26) for Transmission of a tensile force to the movable contact lever (40) and the actuating element the magnetic core (26) for transmitting a tensile force to the latching lever (51) one and the same Actuator is. 5. Overcurrent switch according to claim 4, characterized in that the actuating element is a the only pin (66) inserted transversely into the magnetic core (26) near said end is. 6. Overcurrent switch according to claim 5, characterized in that the latching lever (51) for cooperation with the pin (66) of the movable magnetic core (26) in a slot (47) of the Ma gnetkerns and in a slot (45) of the Kontakthe lever (40) engages, and that the pin (66 ) penetrates the slot (47) of the magnetic core (26) 7. Overcurrent switch according to one of the claims! to 5. characterized in that the magnetic core (26) has an actuating element (rear wall 67) for acting on the latching lever (5!) And for transmitting a thrust force to the same ■: that the elastic return elements ίο (spring 4o) also form the return elements for the latching lever (51). 8. Overcurrent switch according to one of claims 6 or 7, characterized in that the actuating element of the magnetic core (26) through the Rear wall (67) of the slot (47) is formed. 9. Overcurrent switch .nach one of claims 1 to 8, the housing of which contains an arc extinguishing chamber with deionization plates and terminal pole plates, characterized in that the pole plates each have a cutout (34) as a passage to a labyrinth channel (35) of the housing. 10. Overcurrent switch according to one of claims 1 to 9, characterized in that the movable contact lifts '(40) on the housing (10) or a housing extension with a pivot pin (41' and a slot guide (42) opposite the contact plane of the movable Contact lever with the fixed contact is inclined, so that the return spring (compression spring 49) of the contact lever (40) causes a displacement of the contact point on the fixed contact