CZ300092B6 - Switching mechanism for a circuit breaker - Google Patents

Abstract

In the present invention, there is disclosed a circuit breaker switching mechanism (15) having two jointly switched switching paths with movable contacts (8,8') attached to switching bridges (9, 9?) wherein there is arranged on the switching mechanism housing a bearer (17) pivotable about a fixed axis (16) of rotation. Said pivotable bearer (17) has an intermediate wall (18) extending normal to the mechanism rotation axis (16) wherein a cylinder (19, 19?), a support pawl (26, 26?) being concentric with the mechanism rotation axis (16) and an arm support (25, 25?) are formed on both lateral surfaces of the intermediate wall (18). Said cylinder (19, 19?), switching bridges (9, 9?) with their bore holes (20, 20?) and torsion springs (21, 21?) with their coils (22, 22?) are inserted on the arm. Longitudinal axes of the cylinders (19, 19?) form rotation axes (36) of the switching bridges, wherein the first arms (23, 23?) of the torsion spring (21, 21?) abut the switching bridges (9, 9?) while the second arms (24, 24?) abut the arm supports (25, 25?) to thereby permanently loading the switching bridges (9, 9?) in the direction of the support pawls (26, 26?) having different thickness, wherein a pin (27) with a first end of a helical compression spring (28) inserted thereon is formed on the intermediate wall (18) upper end opposite to said cylinders (19, 19?), whereby said helical compression spring (28) other end abuts the mechanism housing. There is also arranged a pawl support (29) being inserted through the mediation of its bore hole (30) on the support pawl (26) and in the region of the intermediate wall (18) upper end has an arm (31) in which a projection (27) of a pawl (33) can engage, wherein said pawl (33) is rotatably mounted at the intermediate wall (18) upper end in the pawl rotation axis (32), wherein there is arranged a yoke (34) that connects the pawl (33) with a control lever (35). Rotation axes (36) of the switching bridges (9, 9?) are arranged in the direction of the movable contacts (8, 8?) with an offset relative to the mechanism axis of rotation (16).

Description

Switching mechanism for protective switch

BACKGROUND OF THE INVENTION

BACKGROUND OF THE INVENTION 1. Field of the Invention The invention relates to a switch mechanism for a protective switch having two switch-on switching paths having a movable contact mounted on a switching bridge, and providing a beam rotatably mounted about a fixed pivot axis on the mechanism housing having a partition wall perpendicular to the pivot axis of rotation of the mechanics, on both sides of which there is always formed a cylinder, support stop concentric with the axis of rotation of the mechanics and arm support on which the cylinder is mounted, switching bridges with their bore holes and twisted springs with their threads, the axes of rotation of the switching bridges, the first legs of the twisted spring abutting on the switching bridges and the second legs on the arm supports, whereby the switching bridges are permanently loaded in the direction of the abutment stops having a different thickness, the upper end of the partition opposite the cylinders; A pin is formed on which a first end of a helical compression spring is mounted, the other end of which rests on the housing, and a latching support is provided, which is drilled into the support stop and has an arm in the region of the upper end of the partition. engage the latch projection, the latch being rotatably mounted at the upper end of the partition about the latch pivot axis, and wherein a yoke is provided to connect the latch to the actuating lever.

BACKGROUND OF THE INVENTION

A switching mechanism of this kind is known from EP-B1 696 041. This patent provides in its main claim that the axis of rotation of the mechanism is coaxially oriented with the axis of rotation of the switching bridges.

Switching tests were carried out with a protective switch whose switching mechanism has the features described in EP-B1 696 041, in particular the axis of rotation of the mechanism, concentric with the axis of rotation of the switching bridges. It has been shown that when both movable contacts are disconnected, these contacts are not lifted simultaneously from the associated fixed contacts but with a certain time offset. In paragraph 2, lines 14 and 15 of 69-Β1 696 041, this time-delayed separation of the two movable contacts is also cited.

It should be appreciated that the two-pole switching device in question is designed in ^one: a pole of alternating current, wherein the first switching path being switched at the inlet (-phase wire). and a second switching path on the outlet (neutral conductor) of the current circuit. The same current flows through both switching paths, or the same current must be interrupted in the case of a short circuit.

If now, as stated in EP-B1 696 041 (see paragraph 2, lines 14, 15 of this document) or, as the case may be, in the case of a switching mechanism according to EP-81696 041, both movable contacts are separated from the fixed contacts they are offset with respect to one another so that in the first phase of the opening process, in which the first contact has already been lifted but the second movable contact is still adjacent to its corresponding fixed contact, an arc only occurs between the contacts of the first switching path. Since a short-circuit current flows through this electric arc, a large amount of energy is released which changes into the corresponding amount of heat in the contacts of the first switching path.

Heavy contact heating results in relatively high wear of these contacts (contact tanning). This strong burning of the contacts leads to a short service life of the first switching path and thus of the entire switching device. If the service life of the first switching path and thus of the entire switching device is to be increased, these contacts of the first switching path must be formed in an appropriate size in order to compensate for the strong burn of the contacts. Large-area contacts, however, necessarily result in large dimensions, which ultimately lead to an enlargement of the entire switching device.

SUMMARY OF THE INVENTION The object of the present invention is to provide a switching mechanism of the kind mentioned at the outset which, with the smallest possible contact volume of the two switching paths - and thus the small dimensions of the switching device - and the long service life of these switching paths.

io

SUMMARY OF THE INVENTION

This object is accomplished by a switch mechanism for a protective switch having two interconnected switch paths having a movable contact mounted on a switching bridge, providing a beam rotatably mounted about a fixed axis of rotation on a mechanism housing having a partition wall perpendicular to the axis of rotation of the mechanics, on both sides of which there is always formed a cylinder, support devices concentric with the axis of rotation of the mechanics and arm support on which the cylinder is mounted, switching bridges with their bore holes and twisted springs with their threads, the axes of rotation of the switching bridges, the first legs of the twisted spring abutting on the switching bridges and the second legs on the arm supports, whereby the switching bridges are permanently loaded in the direction of the abutment stops having a different thickness, the upper end of the partition opposite the cylinders; A pin is formed on which a first end of a helical compression spring is mounted, the other end of which rests on the housing, and a latching support is provided, which is drilled into the support stop and has an arm in the region of the upper end of the partition. engaging a latch projection, the latch being rotatably mounted about the latch rotation axis at the upper end of the partition, and providing a yoke connecting the latch to the actuating lever according to the invention, wherein the axes of rotation of the switching bridges are arranged in the direction of the movable contacts offset from the rotation axis of the drive.

By offsetting the rotational axes, the two movable contacts are lifted simultaneously from their associated fixed contact portions. This simultaneous opening means that the current to be switched off during a short circuit can be interrupted at the same time at the beginning of the switch-off process. An electric arc is generated on both switching paths, so that the energy of the current in a short circuit can be released in two arcs.

Thus, the energy released within each arc is only half that released and concentrated on the contact in a single arc of the switching mechanism according to EPB 1 696 041. This results in a significantly reduced tanning of the contacts and thus a longer service life of both the individual parts of the contact and the entire switching device.

When the AC is interrupted by moving the second part of the contact apart, the contact movement is slow compared to the AC frequency (50 Hz). Thus, during the opening movement of the contact, the alternating current will pass through a single period during which it is also zero, with the arc extinguishing. The ignition of the electric arc after such an extinguishing, which is due to the zero curve, can then only occur when the voltage generated by the short-circuit current exceeds the voltage necessary for a new ignition of the electric arc. The voltage for re-igniting the second electric arc in series with the first arc is significantly higher than the voltage in a single arc, so that when the two switching paths of the invention are opened simultaneously, the current can be definitively interrupted EP-81 696 041, first opens only one of the two switching paths.

-2GB 300092 B6

Thus, the heat generated in the switchgear during the entire switch-off process may be less, so that the entire switchgear can be made with less heat resistance, in particular with smaller dimensions.

The second factor essential for the rapid ultimate quenching of the arc caused by alternating voltage is the elongation of the arc path as long as possible over a large length. Because the design of the switching mechanism can achieve a simultaneous disconnection of the short-circuit current at two points - thus creating a second, in-line arc, the total arc path is twice as long as when opening the circuit at only one location. During the opening movement of the movable contacts, two arcs are formed simultaneously, whereby the total arc path when the current is cut off is generated twice as fast as the mechanics of the file

EP-B1 696 041, where only one arc is formed at a time.

The movable contacts must deviate from the fixed contacts during the opening movement such that in the "off" position, the movable contacts from the fixed contacts are arranged at a distance which ensures the disconnection of the current without risk of shock.

If the axis of rotation of the switching bridge is arranged concentrically with the axis of rotation of the mechanism as in EP-B1 696 041, it is associated with the switching bridges extending over the total distance between the movable contacts and the axis of rotation of the mechanism.

If, on the other hand, according to the invention, the axes of rotation of the switching bridges are arranged in the direction of the movable contacts offset with respect to the axis of rotation of the mechanics, the switching bridges are thus significantly shorter. Due to the shorter design, the switching bridges have smaller dimensions, whereby the mass moment of inertia of the entire switching mechanism is reduced. This reduced mass moment of inertia results in the switching mechanism being quickly brought from the "on" position to the "off" position.

In summary, offsetting the axis of rotation of the switching bridges according to the invention relative to the axis of rotation of the actuator 30 in the direction of the movable contacts in three ways results in faster switching off of short-circuit current associated with less contact burning and less heat generation in the switchgear:

By simultaneously forming a second electric arc in series, the energy generated by the short-circuit current is divided into both switching paths, resulting in a relatively low contact load on both switching paths, i.e. less tan.

· By simultaneously forming a second arc, the total arc path for bridging the short-circuit current is greater than that of a single-pole disconnection only, or, compared to a single-pole disconnection, the arc is formed twice as fast. Thus, the voltage for re-ignition is higher, or rises twice as fast in the opening movement as with only a single-pole opening.

· The moment of inertia of the mass of the whole mechanic, which is reached by means of smaller switching bridges, allows their faster movement.

A further effect which can be obtained by offsetting the axis of rotation of the switching bridge relative to the axis of rotation of the mechanism is that the closing movement of the adjacent and movable contacts in the "on" position is cleaned:

When the beam is rotated and the switching bridges attached to it are turned to the “on” position, the movable contacts are brought to the position in which they are fixed to the fixed contacts. As soon as during this closing movement, the movable contact of its associated fixed contact is contacted, thereby preventing further deflection of the movable contact concerned, which is synchronous with the beam. As the rotation continues, the contact bridge is rotated against the pressure of the twisted spring against the direction of rotation of the beam about the axis of rotation of the switching bridge. The end of the switching bridge opposite the movable contact is raised from the stop (see Fig. 2).

-3GB 300092 B6

With this rotation of the switching bridge, the movable contact moves tangentially against the fixed contact, the adjacent surfaces of the fixed and movable contact rub against each other.

The contamination present on these surfaces is eliminated by this friction, thereby ensuring a transition from fixed to movable contact with a particularly low resistance.

The offset arrangement of the axis of rotation of the mechanics relative to the axis of rotation of the switching bridge is already known from AT-B 404 648 (see claim 1) in connection with a single-pole protective switch (see claim 1). switching bridges 5, pawl support 6 and pawl 3 are disposed. The entire drive is rotatably mounted about a fixed drive rotation axis 11 on the housing. It is also possible to pivot the latch support 6 relative to this axis of rotation 11 relative to the beam axis 4. The switching bridge 5 can be pivoted about the pivot axis 12 relative to the beam hinge 4, this pivot axis 12 being some distance from the rotation axis H of the mechanics, so that the pivot axes 12 and 11 are arranged offset from one another.

Since AT-B 404 648 exclusively describes a single-pole switch, no reference can be made in this case to the principle of offsetting the axis of rotation of the switching bridges relative to the axis of rotation of the mechanics of the two-pole switches. In addition, single-pole switches do not need to separate two movable contacts from fixed contacts simultaneously.

Thus, AT-B 404 648 cannot be an incentive to achieve the effects advantageous of two-pole switches which are based on the offset of the axes of rotation of the switching bridges relative to the axes of rotation of the mechanics.

In another embodiment of the inventions, it may be provided that the support stops are designed as structural elements different from the arm supports and spaced apart from one another. The forces by which the spring is applied to the switching bridges can be adjusted in a very simple way by changing the distance between the arm supports and the support stops.

Furthermore, it can be provided that the pivot axis of the pawl is arranged at a distance from the abutment stops and the arm supports.

Thus, the latch can be fixed to the beam independently of the conventional components of the switching mechanism and hence the connection with low technical requirements. It has proven to be advantageous if further cylindrical shapes are formed on the beam and if a further twisted spring is provided, the first end of which is fixed to this cylindrical shape and whose free end abuts the latch section.

By means of a further twisted spring, the pawl arm moves in the pawl direction, so that when released, the pawl can be locked again by the pawl arm. This allows the switching mechanism to be switched on again using the control lever.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS The invention is explained in more detail with reference to the accompanying drawings, in which: FIG. 1 shows a two-pole protective conductor switch in an oblique view; FIG. 2 shows the switching path of the protective conductor phase conductor. FIG. 3 is an exploded drawing of the switching mechanism (15) according to the invention, FIG. 3 shows the switching path of the phase conductor of the protective switch of FIG.

FIGS. 5 and 6 the support (17) of the switching mechanism according to the invention with the switching bridge 9, 9 'in an oblique view, each viewed from different angles, and FIG. 7, the object of FIGS. (16) rotation of mechanics.

DETAILED DESCRIPTION OF THE INVENTION

FIG. 1 shows a protective conductor switch housing having two switching paths, namely one for the phase conductor L of a single-phase AC circuit and one for the respective neutral conductor N.

Each of these switch paths includes a connection terminal 2 for the lead wire and a connection terminal 3 for the lead wire (see Fig. 3). Connected to the first terminal 2 is a current busbar 4 which is connected to a first end of the winding of the impact anchor switch 5. The second end of the winding of the impact anchor switch 5 is connected to another current connection of a destroyer 6 carrying a fixed contact 7. in the switched-on state, this fixed contact 7 abuts and is fixed to the switching bridge 9. This switching bridge 9 is connected to the free end of the bimetallic strip IT via a flexible braided conductor 10. The other end of this bi-metal band 11, immovably attached to the housing, is connected via a current busbar 12 to the second terminal 3. This current busbar 12 is connected to a spark arc 13, which forms a spark path to the current busbar 6 connecting the contacts 1, 8. , in the end region of which there is arranged a spark extinguishing chamber 14, consisting of a plurality of mutually parallel interrupter plates. In this arc chute 14, arc arcs that arise at a certain point in time between the contacts 7, 8 when they are opened and which, along the current busbar 6 and the spark arc 13, enter the arc chute 14.

The current of the phase conductor connected to this switching path flows through the impact anchor switch 5 and the bimetallic strip 10, the switch 5 being used to control the intensity of the current. Both components act on the switching mechanism when this current is impermissible and can thus lead to tripping of the protective switch, that is, moving the movable contact 8 away from the fixed contact 7, which causes the switching mechanism 15 to trip. The impact anchor switch 5 serves in this way to detect a short-circuit current which is present in the known manner but which exceeds the nominal value many times over. The bi-metal circuit breaker i 1 is used to detect current overload, which, although only slightly exceeds the nominal value, has a longer duration.

The neutral conductor switching path N, not shown in the figures, is constructed in the same way as the phase conductor switching path explained above, but which does not have an impact anchor switch and a bimetallic strip, so that it does not control the current flow. However, the switching bridge 9 'of the neutral conductor switching path 40a moves together with the switching conductor of the phase conductor switching path 9, so that the neutral conductor switching path is always switched together with the phase conductor switching path. Nevertheless, two fully-fledged switch paths are located in the protective conductor switch housing, and only a 18 mm wide separation unit is provided.

The present invention relates to the construction of a switching mechanism 15. This comprises in particular both switching bridges 9, 9 'of both switching paths of a protective switch, which each carry a movable contact 8, 8'. In addition, the switching mechanism 15 has three main structural elements, namely the beam 17, the latch support 29 and the latch 33 (see FIG. 4).

The beam J / 7 is rotatably mounted in a fixed axis 16 of rotation of the mechanics on the housing, which is realized by holding a pin in the housing and in the beam J / 7 with a bore with an outer diameter corresponding to the pin through which the pin is pushed. The beam J / 7 has a partition 18 extending

300092 Bo in normal to the axis of rotation 16 of the mechanics, on both sides of which individual components, i.e. cylinders 19, 19 ', device support stops 26, 26' and arms supports 25, 25 ', are formed.

The rollers 19, 19 'serve to rotatably support the switching bridges 9, 9' on the beam 17, thus forming the axis 36 of the switching bridges. The switching bridges 9, 9 'are provided with bore holes 20, 20' whose diameter corresponds to the outer diameter of the cylinder 9. The switching bridges 9, 9 'are fitted with their holes on the cylinder 19 (see Figs. 5, 6).

The abutment stops 26, 26 'also have a particularly cylindrical form and are formed on the partition 18 at a distance from the rollers 19, 19' and concentrically with the axis of rotation of the mechanics. The axes of rotation of the switching bridges 36 are thus disposed relative to the axis of rotation 6 of the mechanism with an offset in the direction of the movable contacts 8, 8 '. The bridges 9, 9 'are permanently loaded by the twisted springs 21, 2Γ in the direction of the abutment stops 26, 26', or are elastically pressed against the abutment stops 26, 26 'by their ends 90, 90' opposite the movable contacts 8, 8 '. . For this purpose, the twisted springs 21, 2 'are mounted by their threads 22, 22' on the cylinders 19, 9 ', their first legs 23, 23' abut the switching bridges 9, 9 'in the region of the movable contacts 8, 8' and their second the arms 24, 24 'abut the abutments 25, 25'ramen (see Fig. 3).

The switching bridges 9, 9 'have exactly the same dimensions, so they are aligned. Supporting stops

26, 26 ' are aligned and concentric with the rotational axis 16 of the mechanics, but their force or diameters differ from each other such as the diameter of the abutment stop 26 ' It follows that the two movable contacts 8, 8 ', when viewed from the switching mechanism 15 in the direction of the axis of rotation 16 of the mechanism - in a state where they are separated from the fixed of the contacts 7, 7 '- offset angularly by the value α (see Fig. 7).

The angular misalignment results in the switching of the switching mechanism from its open state, as shown in FIG. 3, to the closed state, as shown in FIG. 2, initially closing only the neutral conductor switching paths while the phase conductor switching paths only slightly later. This prior closure of the neutral conductor switching paths is necessarily adapted to the standards applied to the protective switches.

Conventional components of the switching mechanism 15 are necessary for the movement of the support 17 or the switching bridges 9, 9 * which are fastened thereon. The latch 29 has a bore 30 through which it is mounted on the support stop 26 and thus rotatably supported on the support 17 In the region of the upper end of the partition 18, the pawl 29 has an arm 31 on which a pawl 33 can be mounted. This pawl 33 is a U-shaped bent component, preferably made of thin sheet metal, having drilled holes 38 in its arm for receiving. In the upper end of the partition wall 11 of the beam 17 there is also a bore 40 through which the hollow rivet 39 passes. Thus, the latches 40 and 33 are rotatably mounted at the upper end of the partition 18 about the pivot axis 32.

The latch 33 has a projection 37 at the ends opposite the apertures 38, which can be mounted on the arm 31. If, as shown in Figures 2 and 3, the latch 33 is secured by the latch 29 in such a manner, the three main components of the switching mechanism 15 are. (beam 17, latch support

29 and the latch 33) are connected to each other in a positive fit and the switching mechanism 15 can move with the latch 33 via the control lever 35, which is connected via the yoke 34, i.e. it can be deflected from the "on" position (Fig. 2). to the “off” position (Fig. 3) and vice versa.

When swung to the "on" position, the movable contacts 8, 8 '(with time offset) come into contact with the fixed contacts 2 »2' · Since from this point of time the further swivel of the movable contacts 8, 8 'occurs synchronously with the beam 17, to prevent the contact webs 9, 9 ' from rotating against the pressure of the twisted springs 21, 21 ' against the deflection direction of the beam, while moving away from the support stops 26, 26 ' (see FIG. 2).

-6GB 300092 B6

The movable contacts 8, 8 'are displaced radially against the fixed contacts 7, 7', the contact surfaces of the fixed contacts 7, 7 'and the movable contacts 8, 8' rub against each other, thereby removing the contaminants present thereon. If an inadmissible fault current occurs, which must be disconnected, the respective fault current detection component (impact anchor switch 5 or bimetal tape 11) acts on the latch support section 29 below the opening 30 as follows: Impact anchor 50 of the anchor switch 5 impinging directly on this section 44, the free ends of the bimetallic strip 11, which move in the case of an impermissibly intense continuous current in the direction of the second connection terminal 3, carry the tensile yoke 42, which is connected to the section 4L · 10

In both cases, the latch 29 is slightly rotated counterclockwise, thereby bringing the arm 31 into external engagement with the latch projection 37. As a result, the form-fit connection between the pawl 33, the beam 17 and the pawl support 29, respectively the three components and the control lever 35, is released, so that the beam 17 and the switching bridges 9, 9 'can swivel to the "off" position.

This deflection is effected by a helical compression spring 28, the first end of which is mounted on a pin 27 which is formed at the upper end of the partition 18 of the beam 17 opposite the rollers 19, 19 '. The other end of the helical compression spring 28 bears against the housing.

On the second cylindrical boss 44 of the beam 17 is fixed the first end of another twisted spring 45. Its free arm 46 abuts the section 44 of the latch support 29, so that the latch support 29 is biased clockwise by the twisted spring 45. This biasing causes the latch support 29 to rotate counterclockwise when the latch protrusion 37 and the arm 31 are snapped in, so that the arm 31 moves along the latch 33. Once the control lever 35 is brought to the "off" position (which is automatically done by means of a spring built into the lever), the latch projection 37 may rest on the arm 31.

Claims (4)

PATENT CLAIMS A switchgear mechanism (15) for a protective switch having two interconnected switch paths having a movable contact (8, 8 ') mounted on a switching bridge (9, 9'), wherein a beam (17) is provided, rotatably mounted about a fixed axis of rotation (16) on a mechanism housing having a partition (18) extending perpendicular to the axis of rotation (16) of the mechanism, on each side surface of which a cylinder (19, 19 ') is always formed; 26 ') concentric to the axis of rotation (1,6) 40 of the mechanism and the arm support (25, 25 ') on which the cylinder (19, 19') ', the switching bridges (9, 9') with their bore holes (20, 20 ') and the twisted springs (21, 2) are mounted. T) with their threads (22, 22 ') such that the longitudinal axes of the cylinders (19, 19') form the axes (36) of the switching bridges, the first legs (23, 23 ') of the twisted spring (21, 2T) abutting on the switching the bridges (9, 9 ') and the second arms (24, 24') on the arm backs (25, 25 '), whereby the bridges (9, 9') are permanently loaded in the direction of the support stops45 (26, 26 '), having a different thickness, wherein at the upper end of the partition (18) opposite to the rollers (19, 19 ') a pin (27) is formed onto which the first end of the helical compression spring (28) is fitted, a latching abutment (29) is provided, which by means of its bore (30) is mounted on the abutment stop (26) and has arms in the region of the upper end of the partition (18) (31), into which a latch (37) of the latch (33) can engage, wherein the latch (33) is rotatably mounted about the latch pivot axis (32) at the upper end of the partition (18), and the bracket (34) is provided which connects the pawl (33) with the control lever (35), characterized in that the axes (36) of the switching bridges are arranged in the direction of the movable contacts (8, 8 ') offset with respect to the axis of rotation (16) of the mechanics. -7EN 300092 B6 Switching mechanism according to Claim 1, characterized in that the support stops (26, 26 ') are designed as spaced apart elements from the arm supports (25, 25'). Switching mechanism according to claim 1 or 2, characterized in that the pivot axis (32) of the pawl is arranged at a distance from the abutment stops (26, 26 ') and the arm supports (25, 25'). Switching mechanism according to one of Claims 1 to 3, characterized in that a further cylindrical projection (44) is formed in the female carrier (17) and that a further twisted spring (45) is provided, the first end of which is disposed on this projection (44) and whose free arm (46) is mounted on a section (41) of the ratchet support (29).