PL180036B1 - Line protecting cut-off - Google Patents

Abstract

1. Wired protective switch with a thermally and magnetically protected pole of the outer conductor and an unprotected pole of the neutral conductor, each of which is assigned a contact device consisting of a fixed contact element and a pivotable contact lever, and both contact devices are arranged together in one switch housing with a normal, single pole width] and are mechanically coupled to each other and are controlled by one manually actuated switching mechanism, characterized in that both contact devices (3,7) are arranged in relation to to the functional plane of the switching mechanism (2), in this plane, one above the other, with the bearing places (3.2, 7.2) of their contact levers (3.1, 7.1) and the contact levers (3.1, 7.1) being spatially separated. are spring-loaded and coupled by means of a slider (9), where the slider (9) is located almost on the axial extension of the magnetic release device (4) provided with a movable anchor (4.5) and the slider (9) is movable towards coincident with the direction of movement of the movable anchor (4.5) Wired safety switch Fig. 1 PL PL PL PL PL PL PL

Description

The subject of the invention is a wire protection switch.

Such a wire protection switch is known from EP 0 599 800 A1. This circuit breaker has one external conductor pole contact device and one neutral pole contact device, disposed inside one common housing with the usual pole width, in planes parallel to each other. The two contact devices are mutually separated from each other by an angled inner shell placed in the arc extinguishing chamber of the outer conductor pole. Therefore, the space in front of the arc-extinguishing device is, at least one-sidedly, very limited. The two contact devices are mutually engaged by means of a slide, guided in the inner shell, which for its part carries the associated switching bridge on coaxially arranged bearing axes. When the switch mechanism is actuated, the two switch bridges, respectively supported by a pressure spring, swivel in the same direction. The switching bridges, which are coupled essentially directly by means of a common bearing axis, interact with each other, in particular in switching operations, to a great extent, which can generally negatively affect the protective function of the outer conductor pole.

According to the invention, a wire-operated circuit breaker with a thermally and magnetically protected external conductor pole and an unprotected neutral conductor pole, each of which has an associated contact device consisting of a fixed contact element and a pivoting contact lever, and both contact devices are arranged together in a switch housing with normal, single pole width, and are mechanically interconnected and controlled by a single manually operated tripping mechanism, characterized in that the two contact devices are arranged, with respect to the functional plane of the tripping mechanism, one above the other in that plane, with the spatially separated bearing positions of their contact levers and that the contact levers are spring loaded and coupled by a slide, the slide being located almost on the axial extension of the magnetic release device provided with a movable k hole, and the slider is movable in a direction coinciding with the direction of travel of the movable anchor.

Preferably, on the one hand, the slider is movably mounted on the contact lever of the external conductor pole, between the place of its bearing and the point of contact of the external conductor, and on the other hand, it cooperates with the two-armed contact lever of the neutral conductor, on its free, opposite to the contact point of the neutral conductor, end with its sliding surface.

Preferably, the two contact levers connected to the contact tension springs acting on them in the same direction of rotation are, at least temporarily, forcibly connected via a slide.

Preferably, the contact lever of the neutral conductor is pressed in the closing direction of the contacts by a contact tension spring fitted between the lever bearing and its contact point.

According to the invention, the bearing location of the contact lever and the mounting points of the two ends of the tension contact spring are spatially relative to each other such that in the opening position of the contacts, the bearing location of the contact lever lies in the force direction of the tension contact spring.

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According to a further feature of the invention, the two contact levers are positioned facing each other between the fixed contact elements and their ends facing the contact points are movable in approximately the same direction but with the opposite sense.

Preferably, the contact device for the neutral pole is arranged in the base of the housing, immediately adjacent to the input terminals.

Further, according to the invention, the slider, movably connected by a pin to the contact lever of the outer conductor pole, has a sliding surface at its free end acting on the contact lever of the neutral conductor.

Preferably, the protected pole of the field conductor with its essential structural elements is mainly constructed of existing functional parts of the same type of normal wire-operated protection switch which does not have a neutral pole.

The invention has the advantage that the protected pole of the external conductor works like a normal wire-based protective switch and is made up largely of unchanged parts of such a switch. With the same size of the housing, in this type of construction, an unprotected neutral pole has been additionally integrated, saving space and ensuring proper functioning. It is additionally ensured that during the switching-on operation, first the contact of the neutral conductor closes automatically by means of its own contact spring, and only then the contact of the external conductor. In the closed position of the neutral conductor contact, moreover, the force connection with the contact device of the outer conductor pole is completely lost. Its contact lever is thus finally free to swing into the closed position, as with a conventional wire-operated circuit breaker.

During a shutdown operation, either by overload, short circuit or manually, the contact of the external conductor is opened first, with its contact lever initially moving towards the magnetic system. Consequently, at the beginning of the switch-off phase, the degree of freedom between the contact of the outer conductor and the contact of the neutral conductor is further increased, so that the contact lever of the outer conductor pole can open completely without being influenced by the neutral conductor. The slider creates a force connection with the neutral wire pole lever and opens it in time, along the external wire pole, only after covering the designated section of the contact opening path. In this case, the contact spring of the movable contact of the neutral conductor reduces very quickly its force directed against the contact spring of the external conductor contact, which is therefore almost not retarded. This effect is achieved by means of a contact spring of the neutral pole, which is designed as a tension spring, and a particularly preferably selected engagement point. As a result, during the opening operation, the tension spring can swing almost to the bearing point of the movable contact of the neutral conductor into a position close to the dead point, so that its moment in the closing direction very quickly reaches a value close to "zero". Therefore, also in the open position of the outer conductor pole and the neutral conductor, their mutual influence is negligible.

The main advantage of the device according to the invention is used in the short-circuit opening procedure. After releasing the pawl of the switch lock, the impacts of the magnetic core to accelerate the opening of the external conductor contact are transferred directly to the slider, located in the same direction, so that the time-shifted one also impacts the neutral conductor contact in the opening direction. As a result, the welding of the neutral conductor contact is effectively prevented by the impact action of the magnetic release.

The invention is illustrated in an exemplary embodiment in the drawing, in which Fig. 1 schematically shows the circuit breaker with the external conductor pole and the neutral conductor pole in its functional plane in the off position, while Fig. 2 shows the wire-on position in the same way. the circuit breaker.

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Shown as only partially open, the wire-operated circuit breaker has a switch housing 1, only marked by its outer outline and composed in a known manner from two half-shells, and having a thickness of about 18 mm in the plane of the drawing, that is, having the usual pole width from the scale. The switch housing, with its outer outline corresponding to the relevant standard dimensions for wired circuit breakers, houses a tripping mechanism 2, a contact device 3 for the protected external conductor "L" pole, a magnetic release 4, a switching and extinguishing chamber 5, and a thermal release 6. the units 2 to 6 hereby consist, to the maximum extent, of the existing structural parts of a normal single-pole wire-operated circuit breaker, which both in their arrangement and in their functions are practically unchanged compared to such a circuit breaker. Only in the plinth housing 1.1, in the area of common connection terminals, changes to the internal contour of the housing have turned out to be necessary in order to obtain, on the one hand, sufficient space for the double number of terminals (one input and output terminal per external conductor pole and neutral conductor pole), and in addition, in the area of the input terminals 1.2, accommodate the arrangement of the contact device 7 for the neutral conductor "N", together with the necessary mechanisms and electrical components.

As can be seen directly from the drawing, the contact device 7 for the neutral conductor "N" is arranged to the side, under the thermal fuse 6 in the housing base 1.1 in the immediate vicinity of the input terminal 8. The contact device 7 operates in the same, however, slightly offset in height with the plane of movement (corresponds to the plane of the drawing), like the contact device 3 for the outer pole of the "L" cable. The contact device 7 essentially consists of a two-armed contact lever 7.1, which is pivoted in relation to the mounting point 7.2, fixed in the axle housing, and which, with its free end 7.11 of the lever, opposite its actual contact point 7.3, interacts with a slide 9 which will be described in more detail. The contact lever, under the action of its contact spring 7.4, cooperates with a fixed contact element 8.1 which, as an angled extension socket, is directly connected to the input terminal 8, which for its part enables, by means of a terminal box 8.2 and a clamping screw 8.3, the connection of a wire not shown neutral. Starting from the contact lever 7.1, the electrical connection 7.6, on the other side, merely marked, sufficiently insulated, leads transversely through the switch housing to an input terminal 8 opposite on the upper side, not shown for a neutral output terminal.

Moreover, in the plane above the input terminal 8, there is provided an input terminal of the same size, not shown, for the outer conductor pole, separated therefrom by an insert 1.3 (marked with an axial line) in the base of the housing. From this terminal there is an electrical connection directly to the base 6.1 of the thermal release 6 (shown schematically with a short section of flexible cable 6.2), which is suitably insulated from the contact device 7. Likewise, from the free end 6.3 of the thermal switch, to a known as not shown in more detail for triggering the switching mechanism 2 in the event of an overload current, leads the electric cable 6.4 to the pivotable contact lever 3.1 as part of the contact device 3 for protecting the outer cable pole.

The contact lever 3.1 of the outer conductor pole has an oblong hole, pivotally mounted at the mounting point 3.2, firmly embedded in the axle housing, and at the same time slid sideways by a small amount so that, in addition to increasing the contact pressure, it can, for example, compensate for changes at the end of the contact point 3.3 caused by its burnout. To this end, the contact lever cooperates with a fixed contact element 4.1, which is pulled through the so-called contact horn 4.2 into the closing yoke 4.3 of the magnetic release 4, which for its part encloses the frame winding 4.4.

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The current path of the external conductor pole leads from the winding directly to the output terminal, not shown, on the top side of the switch housing. The winding 4.4 surrounds the magnetic core 4.5 which, at least in the event of a short circuit, tilts the only partially depicted actuating lever. 1 with respect to the axle 2.2 mounted in the housing in an anti-clockwise direction, and thereby actuates the switching-off mechanism 2 in a known manner by means of its knee-joint lever 2.3, so that the contact lever 3.1 can be made from the closing position shown in FIG. 2 pivoted into the opening position according to FIG. 1. The shortest opening movement of the contact lever 3.1 is on the one hand caused by a contact spring 3.4 which rotates to the left and acts above its pivot position, the axle 3.2, in particular by an accelerated core. magnetic 4.5 trigger lever ?. 1, which, after triggering with its "hammer end"? .11, accelerates the termination with the contact point 3.3 of the contact lever and breaks the point of contact of the outer pole of the conductor.

Exactly at the height of the "hammer end" "11 of the release lever" .1, the contact lever 3.1 is provided with an opening 3.5, which is articulated by its pin 9.1, the slider 9. The slider 9 is guided by its sides, for example between the schematically shown bridges 1.4, so that it cannot deviate from its travel path, especially in the area of the contact lever 7.1. Behind these casing bridges, the free end of the slider 9 is provided with a sliding surface 9 "which cooperates with the free end 7.11 of the neutral wire contact lever, and the mode of operation of which will be discussed in more detail. Especially in the on position (fig.?), The slider 9 is arranged and guided in the manner described so that its main axis has the same direction as the impact direction of the magnetic core 4.5. In this way it is certain that the movement of the magnetic core, through the "hammer end" ?11 and the impact opening contact lever 3.1, will act exactly in the longitudinal axis of the slide 9 and will almost fully transfer the impact action of the anchor. Thus, this force is available on the sliding surface 9.?, So that during the opening operation after a short free distance (segment "X" in Fig.?) It is possible to hit the end of the lever 7.11 and pivot the contact lever 7.1 in relation to its mounting point 7.? to the off position according to Figure 1.

This operation is supported by the contact spring 3.4 of the outer conductor pole, which is much stronger than the contact spring 7.4 of the neutral conductor pole. The latter is also shaped as a tension spring and with its longer, slightly curved hook-shaped catch is suspended in the eye 7.5 of the contact lever, approximately in the middle between the attachment point 7.? and the point of contact 7.3, while its shorter hitch is engaged with the fixed pin 1.5. The position of this pin 1.5 is spatially assigned to the contact lever 7.1 that the contact spring 7.4, in the on position (Fig.?), Pulls the already operating, relatively short lever arm, while in the off position (Fig. 1) the lever arm it almost reaches "zero". The intentional connecting line between the eyelet 7.5 and the pin 1.5, which corresponds to the operating direction of the contact spring 7.4, therefore, in the switch-off position of the contact lever 7.1, only runs slightly below or almost through the center of the axle of the mounting point 7. This means that the contact spring 7.4, with almost the same spring tension, loses its counter force very quickly and only a very slight left turning moment is exerted on the contact lever, so that it is practically at a dead point. So the contact lever 7.1 rests with its end point of lever 7.11 on the sliding surface 9.? of the slide 9 by force, but without substantially exerting a force on the contact lever 3.1 of the outer conductor pole.

If from this position the wire-operated safety switch is actuated manually by means of the manual operating device ".4 and with the knee-joint lever" .3 in the closed position according to Fig. ", The contact lever 3.1 will pivot relative to its mounting location 3.? and takes the slide 9 by the spigot 9.1 in the clockwise direction. The end of the lever 7.11 adjacent to the sliding surface 9 moves in the same direction. under

180 036 due to the action of the contact spring 7.4, the tilting moment of which acting on the contact lever 7.1 becomes larger and larger due to the movement of the eye 7.5. When, in this movement, the contact point 7.3 reaches the fixed contact element 8.1, it enters the abutting position thereto, the contact spring 7.4 developing its greatest force and now exerting the contact pressure force. Only then does the contact lever 3.1 reach the contact side 3.3 on the contact side with the fixed contact element 4.1 and close the pole of the external conductor. This follow-up of the contact of the outer conductor is ensured by the free path between the sliding surface 9.2 and the end 7.11 of the contact lever of the neutral conductor. In this case, the section "X" shown in FIG. 2 is the measure for the free travel with the final tensioned switching mechanism. On the first contact of the end with the contact point 3.3 on the contact side, with the fixed contact piece 4.1, this free path is slightly greater, since then there is no distance, visible in FIG. 2, between the attachment point 3.2 and the semi-cylindrical wall of the elongated hole below it, which serves as a bearing cup during the switching-on operation (Fig. 1). However, this distance is necessary so that, in the engaged position, the contact lever 3.1 is supported only at the contact point and on the knee-joint lever 2.3 and pulled by the contact spring 3.1, due to the tolerances and the necessary burnout reserve, is held securely and that the mechanism the switch on the manual control organ 2.4 could be tensioned without the so-called "connection extension".

Conversely, the above-mentioned greater free path between the sliding surface 9.2 and the end of the lever 7.11 is also available for the switching-off operation, because after releasing the lever with the knee joint 2.3, the contact lever 3.1 first tilts counterclockwise to it. the end from the joint side 3.3, until the walls of the elongated hole meet at the point of attachment 3.2. In the event of a short circuit, the contact lever 3.1 is in fact struck by the "hammer end" 2.11 at about the same time and in the same direction of rotation, the movements overlapping each other, depending on the cut-off speed. It is at least ensured that the "hammer end" of the contact lever will sufficiently accelerate the contact lever 3.1 and open the contacts before, after traversing the free path "X", the slider 9 hits the contact lever 7.1 of the neutral wire and depresses it into the open position (fig. 1).

The measure of the free path and thus the correct sequence of connecting the neutral and the pole of the outer conductor changes slightly with burnout of the contacts, since burnout of the contacts is canceled out due to the opposite directions of rotation of the contact levers 3.1 or 7.1. The same applies to both contact springs. Before, when opening the contact lever of the external conductor, the tensile force of the contact spring 3.4 has significantly decreased, already before, the moment of the contact spring 7.4 exerted on the contact lever 7.1 is reduced to a minimum value. Thus, the switch-off function of the protected pole of the external conductor is essentially exactly the same as in a purely protective line switch.

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Publishing Department of the UP RP. Circulation of 60 copies

Price PLN 2.00.

Claims (9)

Patent claims 1.Wired device circuit breaker with a thermally and magnetically protected outer conductor pole and an unprotected neutral pole, each of which has an associated contact device consisting of a fixed contact element and a tilting contact lever, and both contact devices are housed together in one normal circuit breaker housing, single pole width, and are mechanically interconnected and controlled by a single manually operated tripping mechanism, characterized in that the two contact devices (3,7) are positioned, with respect to the functional plane of the tripping mechanism (2), in this plane, one above the second one, with spatially separated bearing positions (3.2,7.2) of their contact levers (3.1, 7.1) and that the contact levers (3.1, 7.1) are spring-loaded and coupled by a slide (9), the slide (9) is situated almost on the axial extension of the magnetic release device (4) provided with a movable anchor (4.5) and the slider (9) is movable in a direction coinciding with the direction of travel of the movable anchor (4.5). 2. A wired switch according to claim The slider (9) is mounted movably on the contact lever (3.1) of the outer conductor pole (L) between its bearing (3.2) and the contact point (3.3) of the outer conductor on the one hand, and cooperates with the two-armed contact lever (7.1) of the neutral conductor (N) pole at its free end (7.11) opposite the neutral conductor contact point (7.3) with its sliding surface (9.2). 3. Wired switch according to claim The contact tension springs (3.4, 7.4) acting on them in the same direction of rotation, characterized in that the two contact levers (3.1, 7.1) are interconnected at least temporarily via the slide (9) forcefully. 4. Wired switch according to claim The method of claim 1, characterized in that the contact lever (7.1) of the neutral conductor (N) pole is pressed in the contact closing direction by means of a contact tension spring (7.4) fixed between the lever bearing (7.2) and its contact point (7.3). 5. Wired switch according to claim 4, characterized in that the bearing location (7.2) of the contact lever (7.1) and the mounting locations of both ends of the contact tension spring (7.4) are spatially relative to each other that in the opening position of the contacts, the bearing location (7.2) of the contact lever (7.1) lies in the force direction of the tension contact spring (7.4). 6. Wired switch according to claim A method according to claim 1, characterized in that the two contact levers (3.1,7.1) are positioned and directed towards each other between the fixed contact elements (4.1,8.1) and their ends on the contact side (3.3,7.3) are movable in approximately the same direction, but with the opposite phrase. 7. Wired switch according to claim A device as claimed in claim 1, characterized in that the contact device (7) for the pole of the neutral conductor (N) is arranged in the housing base (1.1), directly adjacent to the input terminals (8). 8. Wired switch according to claim The slider (9), movably connected by means of a pin (9.1) to the contact lever (3.1) of the outer conductor pole (L), at its free end acting on the contact lever (7.1) of the neutral conductor (N) pole has the sliding surface (9.2). 180 036 9. Wired switch according to claim A method according to claim 1, characterized in that the protected outer conductor pole (L) with its essential structural elements (2,3,4,5,6) is mainly constructed of existing functional parts of the same type of normal wire-operated circuit breaker that does not have a conductor pole neutral (N). * * *