DE4000206A1 - Circuit breaker e.g. three-pole disconnecting switch - has movable contact slidably electrically connected to fixed contact - Google Patents

Abstract

The circuit breaker which supports a movable contact device (31, 41) by a means of a holder (36) of electrically isolating material, which is pivotably fixed to a housing (1) via a switch rod. The movable contact device (31, 41) is driven by a switch device (6) such that it is rotatable together with the holder about the switch rod (38) to perform a switching operation. The movable contact device (31, 41) is slidably, electrically connected to a connection line (33, 43) which is fixed in the housing (1). ADVANTAGE - No need for flexible conductors to connect movable contact to stationary contact. Connection is very secure. Circuit breaker is simply attached to the holder. Electrically connected parts have increased life span.

Description

The invention is concerned with relatively small Disconnectors, such as line disconnectors and earth faults disconnectors, and in particular relates to the Erfin design of such a disconnector, which is a moving contact made by a driver unit is electrically charged with a connector connecting the conductor, which is fixed to a housing.

Figs. 13 and 14 show an example of a conventional three-pole circuit breaker (line disconnector). In particular, FIGS. 13 and 14 are sectional views along the central pole for illustrating a closed state and an open state thereof, respectively.

In Fig. 13, the reference numeral 1 denotes a resin molded housing, with 2 a cover, with 3 a statio nary contact, which is designed in one piece with a line supply side connection 3 a, the contact 3 on the housing 1 by means Screws (not shown) is fixed, 4 with a stationary contact, which is provided on the stationary contact 3 , and 5 denotes a movable contact, which is pivotally mounted about an axis 7 on a resin molded holder 6 . With 8 a movable contact is designated, which is provided on the movable contact 5 such that it is the stationary Kon 4 opposite. With 9 is a Überlastauslöseein direction (an overload protection switch), a bimetallic part 9 a, an L-shaped, stationary conductor 9 b, which is welded to the bimetallic part 9 a, a statio nary magnet 9 c, which surrounds the bimetallic part 9 a and has an armature 9 d, which faces the stationary magnet 9 c in such a way that it can perform a pivoting movement. With 10 , a connecting conductor is referred to, which is seen in an overlying arrangement on the stationary conductor 9 b before and be connected to the housing 1 with the help of a screw 11 . With 12 a flexible conductor is referred to net, the two ends of which are connected to the movable contact 5 and the connecting conductor 10 by means of soldering. With 13 a consumer-side connection is designated, which is attached to the housing 1 with the aid of a screw 14 . 15 with a flexible conductor is designated, which is seen as an intermediate connection between the bimetallic part 9 a and the connection 13 before.

Furthermore, in Fig. 13, reference numeral 16 denotes a switching device for pivoting the movable contact 5 together with the holder 6 . The switching device 16 is normally locked or self-locking by means of a trigger device 18 which contains a cross member 19 which extends over the poles. A hand lever 19 is back and forth movably mounted such that it can be swiveled to the right and left. In particular, the hand lever 19 is connected via a switching spring 20 to the switching device 16 and has a handle part 21 on its top. A contact spring 22 is seen between the holder 6 and the movable contact 5 in such a way that the movable contact 5 is pressed in the direction of the sta tionary contact 3 .

The movable contacts of the right and left poles (not shown) are seen on the right and left of the movable contact 5 before. These movable contacts are also rotatably supported about axes on the holders in a manner similar to the part 6 shown in FIG. 13. This holder of the three poles are connected to each other via a control shaft or switching axis, which is rotatably mounted in bearing recesses which are formed in partitions provided between the phases of the housing 1 Ge. Furthermore, in Fig. 13 with the reference numeral 23, an arc quenching chamber is designated, which is hen vorgese over the range of motion of the movable contact 8 .

In the disconnector designed in this way, the current from the stationary contact 3 via the stationary contact 4 , the movable contact 8 , the movable contact 5 , the flexible conductor 12 , the connecting conductor 10 , the stationary conductor 9 b, the bimetal part 9 a and the flexible conductor 15 flow to the terminal 13 . In this case, an overcurrent of approximately ten times the rated current in the circuit breaker flows, then the bimetallic 9 13 curves a in Fig. To the left, is applied whereby the cross member 17 with a pressing force. As a result, the switching device 16 is triggered by the Auslöseeinrich device, so that the movable contact 5 together with the holder 6 is pivoted by the spring force of the switching spring 20 and this is thus quickly lifted from the stationary contact 3 . In this mode of operation, arcs are formed between the stationary contact 4 and the movable contact 8 . However, these are drawn into an arc extinguishing chamber 13 with the help of the induced electromagnetic force.

When a large current, such as a short-circuit current, flows in the circuit breaker, the stationary magnet 9 c attracts the armature 9 d. In this case, therefore, the impact on the cross member 17 before the bimetallic part 9 b is curved, so that it acts that the movable contact of the stationary contact 3 is released suddenly and immediately. If the isolating switch is opened by the fact that the operating lever 21 in Fig. 14 is rotated to the right with the switch device 16 locked, the movable contact 5 is raised by the spring force of the switching spring 20 so that it stands out from the stationary contact, such as this is shown in the drawing. In the conventional disconnector of the type described above, the movable contact 5 , which is pivoted by means of the switching device 16 , is electrically connected via the flexible conductor 12 to the connecting conductor 10 , which is fastened to the housing 1 . The flexible conductor 12 is generally formed by a braid made from a number of bundles of thin copper wires. However, the following difficulties arise when using the flexible conductor in the disconnector:

• 1) When the movable contact 5 pivots, the flexible conductor 12 also pivots . If the movement of the flexible conductor 12 is increased, this also increases the pivotal movement of the flexible conductor 12 , so that the flexible conductor 12 can break due to concentration and a resulting metal fatigue.
• 2) In order to prevent the flexible wire from breaking, it should not be deformed so strongly during its swiveling movement. For this purpose it is essential to provide a room which is large enough to be accommodated. However, this necessarily increases the nominal current, and the flexible conductor 12 must be designed with a larger diameter in a corresponding manner. As a result, the size of the housing 1 inevitably increases. Thus, it becomes difficult to reduce the size of the circuit breaker.
• 3) The movable contact 5 is opposed by the flexible conductor 12 when it performs a pivoting movement during a switching operation. This caused by the flexible conductor resistance depends on the connection state of the flexible conductor with the associated parts and on the switching frequency of the disconnector or the switching frequency of the same, whereby the contact pressure of the contacts 4 and 8 and the speed of movement of the movable contact 5 be adversely affected .

Taking into account the above statements, the Invention to provide a circuit breaker at which the movable contact electrically with the stationary side connecting cable without the use of a flexible cable ters is connected, whereby the above described Difficulties with a common interpretation a switch disconnect.

The invention further aims to provide a circuit breaker make the electrical Ver binding is inevitably maintained.

Furthermore, according to the invention, a disconnector is to be prepared in which the moving contact is easy and simply attaches to the holder.

According to the invention, a circuit breaker is also to be provided be in which the electrically connected parts ver have a longer service life.

According to the invention, a disconnector is provided for this purpose, in which a movable contact by means of a holder made of elec trically insulating material is held, which over a Shift axis or shift shaft rotatably mounted on a housing is where the movable contact by a switching device tion is driven such that it is about the pivot axis  can pivot together with the holder to a Schaltvor to perform gear, and in which according to the invention the mov Liche contact slidably and electrically with a connection is connected to the conductor, which is fixed to the housing.

To allow the movable contact to slide and electrically with the connecting conductor according to the invention can be connected, the connecting conductor has a pair of arms at the connection end over which the connection conductor elek is connected to the movable contact in such a way that the moving contact is between the arms and it is featured a pair of springs on either side of the arms see that the arms against the side walls of the movable Kon be pressed.

In this context, the arms of the connecting conductor Sections near the contact surfaces of the arms with the be mobile contact in such a way that the sections face each other and the distance between them is smaller than that between the contact surfaces, so that the electromagnetic force induced therein is used more effectively can be used to increase the contact pressure between them.

The movable contact is engaged on a holding part pieces attached by cutting a thin plate are formed, and the holding part is then by means of an interference fit provided in a holder in a recess, the engagement stages corresponding to the engaging pieces. This will the assembly of the disconnector is facilitated.

The contact surfaces are heated by the frictional heat, generated by the sliding movement, or by Joule Warms up heat that is generated when the current flows through same goes. If the contact surfaces come from a usual  electrically conductive material, such as copper or a copper alloy, these are quickly replaced by heating tion oxidized, which increases the contact resistance. Here through the load capacity or the current strength decreases. Around to prevent the oxidation of the contact surfaces, and in order the resilience of the latter remains unchanged the following method is generally used: The sliding contact surfaces are plated with silver (Ag).

However, it has been found in ver by the inventors seek shown that when a no-load shift (where the contact surfaces are gliding without execute movement) is repeatedly executed, the silver layer ten on the contact surfaces, so that the reason metal, copper, exposed, and when a large current to under break (with the current flowing through the contact surfaces) the silver layers are melted and thereby the copper is exposed.

To overcome this difficulty, according to the invention the sliding contact surfaces of at least one of the movable cones clock and the connecting conductor with a silver-carbon connecting material plated.

In the disconnector according to the invention, the movable Contact and the connecting conductor in sliding contact with each other, so that they are electrically connected to each other. This overcomes the difficulty that the flexible Can break contact and it is not necessary to have one To provide space for the flexible conductor in the housing. In In this case, this is via the connecting conductor to the mov brake contact when the latter performs a switching movement (i.e. when the moving con clocks around the connecting axis of the holder swings) that  Product from the frictional force at the contact surfaces and the average turning radius of the small contact areas. Therefore is the influence of the braking torque on the contact pressure and the switching speed of the moving contact is low, which is provided at the end of the movable contact which is much longer than the average turning radius. To In addition, the above-mentioned frictional force remains in the essentially unchanged constant until the sliding contact surface Chen are ground in or welded.

In the disconnector according to the invention, the connection head a pair of arms formed at the connection end are, via which the connecting conductor is electrically connected to the be moving contact is connected so that the arms are each other are facing and the moving contact between the arms is held. In this case the contact area is twice as large as in the case where only one side of the mov Chen contact is in contact with the connecting conductor. Fer The electromagnetic attraction force acting between the currents induced in the two arms in the flow in the same direction so that the arms against the be mobile contact can be pressed more effectively. If in this If the arms of the connecting conductor are designed in such a way that they have inwardly curved sections near the Kon tact surfaces of the arms with the movable contact such ha ben that the distance between the inward Ab cut is smaller than that between the contact surfaces, then the electromagnetic specified above can be Tightening force more effectively to increase the contact pressure nut Zen. The contact pressure can inevitably be constant be held that one Druckfe on both sides of the arms which provides for the same against the moving contact to press.

The movable contact is attached to the holder  kept as described below. For one, it is movable contact firmly with a holding part with engagement pieces connected by cutting a thin plat te are formed, and then the holding part by means of pressing seated in a holder over a recess that Has engagement levels corresponding to the engagement pieces. In the In this case, the moving contact can be combined with Arrange the holder in one operation, whereby the Installation of the disconnector easier.

Investigations were also carried out with a view to exposing the Base metal, copper, in the manner described below performed. The reason that the silver layer is worn off and the base metal, copper, is exposed if like repeats a shift without load, at which the movable contact in sliding contact with the connector is the fact that the silver layers, those on the movable conductor and the connecting conductor are formed, rubbing against each other. Furthermore is another reason for exposing the copper layer, though a great current to be interrupted is that the Silver layers on the moving contact and connector welded together. If in the latter ten cases, the parts welded together during execution break a sliding movement, the contact surfaces rough and you get an unsatisfactory elek trical contact, from which results that another Erwär by the current to a higher temperature, so that the silver layers are melted even more easily and can weld together.

This difficulty can be overcome by thin ne, film-like layers on the sliding contact surfaces under Using a composite material, which one there by receiving carbon (C) particles in a silver  be dispersed matrix. As is known per se, Koh an excellent lubricant. But it works no welded connection with silver. So the silver Carbon composite material the appearance of scouring appearances when repeating a load Avoid loose switching. Furthermore, at Un Breaking a high current the layers that are on the Contact surfaces are formed with the composite material, he be melted, but they do not weld together at the. Thus, the sliding contact surfaces remain in both cases smooth, and consequently there is sufficient power consumption assets available.

Further details, features and advantages of the invention emerge from the description below of before preferred embodiments with reference to the accompanying Drawing. It shows:

Fig. 1 is a perspective view of a movable contact and this associated parts according to a first preferred embodiment of the invention;

Fig. 2 is a perspective view showing a movable contact and this zugeord neter parts according to a second preferred embodiment of the invention;

Fig. 3 is a vertical sectional view showing the center pole of a circuit breaker which is equipped with a movable contact and the associated parts corresponding to Fig. 1, wherein the center pole is closed,

Fig. 4 is a vertical sectional view showing the center pole in the open state,

Fig. 5A, 5B and 5C are a plan view, side view and rear view, respectively, showing a movable contact and this zugeord neter parts according to a third Favor th embodiment of the invention,

Fig. 6 is a plan view showing the essential parts of a holder which holds the movable contact in Fig. 5,

Fig. 7 is a sectional view taken along the line VII-VII in Fig. 6,

Fig. 8 is a perspective view Verdeut lichung the arrangement comprising the holder in Fig. 6 and the movable contact in Fig. 5,

FIG. 9A is an enlarged side view of a connecting conductor Ver deutlichung in Fig. 5,

Fig. 9B is a sectional view taken along line BB in Fig. 9A,

FIG. 10A, which 5C is a rear view showing the movable contact and the connecting conductor in Fig.

FIG. 10B is an enlarged diagram for Verdeut lichung a portion B in Fig. 10A,

Fig. 11 is a graph showing changes of an electromagnetic repulsive force and an electromagnetic attractive force at a short-circuit current at a Kon clock section in Fig. 10

12 is a sectional view showing a center pole of a circuit breaker having a movable contact as shown in FIG. 5, wherein the pole is closed.,

Fig. 13 is a vertical sectional view to illustrate the center pole of a conventional circuit breaker in which the center pole is closed, and

Fig. 14 is a vertical sectional view to illustrate the center pole in the open state.

Preferred embodiments of the invention are described in more detail below with reference to FIGS . 1 to 11. In these figures, those parts which were explained in connection with FIG. 13 and which showed a conventional disconnector are therefore provided with the same reference symbols.

Fig. 1 is a schematic view for describing the principle underlying the invention reason. In particular, FIG. 1 shows a perspective view of a movable contact of the center pole in a first preferred embodiment according to the invention. The movable contact device 31 is formed by a punched-out copper plate and has a movable contact 32 which is welded at one end by means of flames. A connecting conductor 33 is designed in one piece with the bimetallic part 9 a and has a through opening 34 into which a screw (not shown) is used to fasten the connecting conductor 33 to the housing 1 . In this case, it is not neces sary to provide the conductor 9 b (shown in FIG. 13) for fixing the bimetallic part 9 a. The connecting conductor 33 has a pair of arms 33 a on both sides, which face each other. The arms 33 a resiliently hold the Endab section of the movable contact device 31st In other words, this means that the arms are in sliding contact with the movable contact device 31 . The movable contact device 31 and the arms 33 a have through openings (not shown) which are aligned with one another and into which a shaft or an axis 35 is inserted, as shown in FIG. 1.

A recess 36 a for receiving the movable Kontaktin device 31 is formed out in a resin molded holder 36 . Both ends of the axis 35 are inserted in the side walls of the recess 36 a respectively. In particular, coil springs or compression springs 37 are mounted on the axis 35 on both sides of the arms 33 a in such a way that the inner walls of the arms 33 a are pressed against the side walls of the movable contact device 31 . The holder 36 is connected via switching axes 38 which are formed in one piece with the holders of the right and left poles. The holders are gela on the housing 1 via the switching axes 38 freely movable. When they are driven by the switching device 16 , the movable contact device 31 is pivoted about the connection axis 38 , and at the same time the right and left movable contact devices (not shown), which are carried by the holders (not shown), also around the connection axis 38 pivoted.

The overload release devices 9 in the conventional disconnector, which is shown in Fig. 13, and in the disconnector ter according to the invention, which is shown in Fig. 1, are designed as directly heatable parts such that the current to the bimetallic part 9 a yourself. However, there is also egg ne overload release device, in which he is heated indirectly and in which the current is applied to a heating conductor, so that the heat generated thereby is transferred to the associated bimetal part. Fig. 2 shows a circuit breaker which has such an overload release device and which is a second preferred embodiment according to the invention. The second preferred embodiment of the invention coincides essentially with that of FIG. 1, except that the Ver connecting conductor 33 is formed in one piece with a heating conductor 39 .

FIGS. 3 and 4 are sectional views showing the circuit breaker having the movable contactor 31 and the connecting conductor 33, as shown in FIG. 1. In Fig. 3 the disconnector is closed. In Fig. 4 it is open. In the circuit breaker, the current flows from the stationary contact device 3 via the stationary contact 4 , the movable contact 8 to the movable contact device 31 and it can flow directly to the connecting line ter 33 because the side walls of the movable contact device 31 are in sliding contact with the inner walls of the arms 33 a are. Then the current flows through the bimetallic part 9 a and the flexible conductor 15 to the terminal 13 . A contact spring 40, which is formed by a compression spring and is interposed between the housing 1 and the movable contactor 31 a, is designed so as to clock means 31 in the direction of the stationary conductor 3 presses the movable Kon. As a result, a suitable contact pressure is exerted on the movable contact device 31 . The other design details and the mode of operation are the same as those of the conventional disconnector described above.

Figs. 5 to 9 show a third preferred execution form according to the invention, which advantageously is configured as the first and second preferred embodiments described above.

Fig. 5 shows a movable contact device and a connecting conductor which are held in sliding contact with each other. In particular, FIGS . 5A, 5 B and 5 C each show a plan view in which an upper part of a copper plate 44 (which will be described later) is partly omitted, a side view in which a side plate of the copper plate is partially on the front is omitted, and a rear view to illustrate the individual components. In Fig. 5, reference numeral 41 denotes the movable contact device which is formed by a punched-out copper plate. With 42 a movable contact is designated, which is welded to the end of the movable contact device 41 by means of a flame. With 43 the connecting conductor is designated, which is formed by bending a copper plate. With 44 a U-shaped holding part is designated, which is formed by bending a thin, elastic steel plate's, and with 45 a claw made of a steel plate is designated. The claw 45 forms a current limiting device.

The connecting conductor 43 has a base part 43 a with a through opening 46 and it is firmly connected to the disconnector switch housing 1 by means of a screw which is inserted into the through opening 46 provided . A pair of arms 43 b, which extend from the base 43 upward, are provided such that they are opposite to each other. The arms 43 b are, as shown in Fig. 5, bent to such an extent that the distance between them is slightly smaller than the thickness of the movable contact device 41 so that they resiliently hold the rear end portion of the movable contact device 41 , the is inserted between them in the clamped state. This means that a sliding contact with the side walls of the movable contact device 41 is present. As additionally shown in Fig. 5A, in the base portion 43a, a slit 43 c formed of 46 of the center line thereof is cut in such a way, starting from a left end in Fig. 5A to an adjacent portion of the through hole along that the arms 43 b can easily deform in the transverse direction.

The movable contact device 41 and the arms 43 b ha ben through openings that are aligned with each other and in which an axis 47 is used relatively loosely. The springs 49 and 49 , which comprise compression springs, are mounted on the axis 47 un with the interposition of washers 48 and 48 on both sides of the arms 43 b. Then the two ends of the axis 47 are connected to the side walls of the holding part 44, for example by caulking. Thus, the movable contact device 41 is pivotable about the axis 47 , and the arms 43 b are pressed in a suitable manner against the movable contact device 41 .

FIG. 9A is a side view of the connecting conductor 43 , and FIG. 9B is a sectional view along the line BB in FIG. 9A. As shown in Fig. 9, annular projections 43 d are formed around the through holes 50 into which the axis 47 is inserted, so that the annular projections are in contact with the movable contact device 41 . This means that the contact area of the movable contact device 41 with the arms 43 b is limited to the small ring-shaped projections. Therefore, the on the movable contact device 41 by the frictional force at the braking torque is small, and the contact pressure is favorable. Even if the switching operation is repeated before, the movable contact and the arms are kept in stable contact with each other, since the contact area is richly stable.

Referring again to FIG. 5, the claw 5 is supported by means of the holding part 44 about an axis 51 rotatably. The two ends of the same are firmly connected to the side walls of the holding part in a similar manner as in the axis 47 described above. The claw 45 is a fork-shaped, hard component which is bent in the vicinity of the axis 51 in the form of the letter "U". The claw 45 has a step 45 a, which cooperates with a bolt 52 which is embedded in the movable contact device 41 in such a way that it extends away from the movable contact device 41 on both sides. A pair of tension springs 53 is provided as an intermediate connection between the upper end portion of the claw and the upper end portion of the holding part such that the claw is always pressed against the bolt 52 . On the other hand, the movable contact device 41 is acted upon by the spring 53 via the bolt 52 with a compressive force such that it rotates about the axis 47 in the counterclockwise direction in FIG. 5B such that a torque is applied to the movable contact device 41 . When the circuit breaker is composed (as will be described in more detail below, the movable Kon clock means 41 in the direction of the stationary contact means 3 is pressed by the torque. Thus, the spring 53 also functions as a contact spring.

The holding member 44 has engaging pieces 44 a and 44 b that are formed in that the upper and lateral Plattensei th each be cut. The arrangement of the movable contact device 41 and the connecting conductor 43 is attached to the engagement pieces 44 a and 44 b on the holder. The holder is described in more detail below.

Fig. 6 is a plan view of the center pole holder, and Fig. 7 is a sectional view taken along the line VII-VII in Fig. 7. As shown in Fig. 6, the holders 54 of the three poles are connected to each other via the shift shaft 55 connected. The interphase separating parts 55 a are formed in one piece with the switching shaft 55 . The holder 54 are rotatably mounted on the connecting shaft 55 , the housing 1 used in the bearing recesses of the intermediate-phase partitions 1 a (shown with a broken line with two dots and dashes). Recesses 54 are formed on both side walls of the center pole holder 54 to connect the tracks of an open-closed device.

The arrangement shown in FIG. 5 is attached to the holder 54 as shown in FIG. 7. A recess 56 is formed in the holder 54 such that the arrangement can be inserted into the holder from behind. A window 57 is formed in the front wall of the holder. The movable contact device 41 is inserted into the window 57 of the type that it can be pivoted to carry out a switching operation. Fitting surfaces 56 a are formed in the right and lin ken walls of the recess 56 with a holding part 44 speaking width. The front edges 56 b of the mating surfaces 56 a are designed similar to the contour of the front wall of the holding part 44 . A stage 56 c is provided in the upper wall of the recess 56 with assignment to the engagement pieces 44 a. In addition, steps 56 d are formed in the right and left walls of the recess such that they run along the lower part of the front edge 56 b of the mating surface.

The arrangement shown in Fig. 5 is pressed in the holder such that the engagement pieces 44 a and 44 b of the holding part 44 are resiliently deformed inward until the front wall of the holding part 44 against the front edges 56 b of the mating surfaces of the right and left Walls. In this operating state, the engagement pieces ke 44 a and 44 b are reset by the spring forces and work with the stages 56 c and 56 d in each case, so that they are fixed, as is shown in FIGS . 7 and 8 in a perspective view is shown, which show the holder 54 with the movable contact device 41 fastened in the manner described above. However, through openings 54 b are provided to introduce pins for connecting the tracks of the open-closed device.

Fig. 12 is a vertical sectional view showing the center pole of the circuit breaker, which is closed, where the holder 54 holds the arrangement shown in Fig. 5 in the assembled state. The base part 43 a of the connec tion conductor 43 and the bimetallic part 9 a overlap each other and are firmly connected to the housing 1 . In the state shown in Fig. 12, the connecting conductor 41 is pressed by pressing toward the stationary contact device 3 , so that the connecting conductor 41 is slightly rotated to rotate about the axis 47 in the clockwise direction. In response to this movement, the claw 45 is rotated about the bolt 52 against the spring 53 , so that it rotates about the axis 51 . As a result, contact pressure is obtained between the contacts 4 and 42 due to the fact that the spring 53 applies a torque to the movable contact device 41 in the counterclockwise direction in FIG .

The holder 54 and the movable contact device 41 in the disconnector are rotatable about the central axis A ( FIG. 7) of the connecting shaft 55 . However, the central axis B of the shaft 47 is shifted by a distance r from the central axis A of the connecting shaft 55 , and therefore the shaft 47 is rotated about the axis A with the radius r. To enable the shaft 47 to rotate in this way, the through holes 50 into which the axis of the shaft 47 is set are elongated, as shown in FIG. 9A. As previously stated, the central axis B of the shaft 47 is displaced by a distance r from the central axis A of the connecting shaft 55 , so that the movable contact device 41 is moved slightly back and forth (in FIG. 12 in the direction to the left and right) . As a result, the contacts 4 and 42 are slidably moved to avoid oxidation of the contact surfaces thereof.

A current limitation interruption by the action of the claw 45 will be briefly described below. As shown in Fig. 12, 3 comprises the stationary contact means comprises a head portion 3 b, which is parallel to the conductor of the movable contact means 5. If the current in the Leiterab section 3 b and the movable contact device 31 flows through the contacts 4 and 42 , the current in the conductor section 3 b and in the movable contact device 31 is directed in different directions, so that an electric motor repulsive force is induced therebetween becomes. As a result, the movable contact device 31 is kept pressed in such a way that it is moved away from the stationary contact device.

When a large current such as a short circuit current, in the circuit breaker flows, and the movable contact means 41 assumes the position shown in Fig. 5B, the movable Kon clock means 41 so strong driven such that it overflows the pawl 45 against the spring force of the springs 53 and is pivoted clockwise around the axis or shaft 47 , so that the bolt 52 is caused to run on the wall 45 b ( FIG. 7) of the claw 45 . As a result, the spring force of the springs 53 causes the movable contact device to be quickly moved away from the stationary contact device before a switching operation takes place. Thus, the arc voltage suddenly increases, so that the so-called "current limit interruption" is carried out. Fig. 7 shows the result of the current limit interruption that was undertaken.

On the other hand, when in the case shown in Fig. 10A, the movable contact device 41 is in sliding contact with the connecting wire 43 , current flows through a plurality of contact points P in the contact area, as shown in Fig. 10B, which is an enlarged view for clarifying a B section in Fig. 10A. As indicated by the arrows (i) in FIG. 10B, the current is brought together so that it passes through the contact point P, and after passing through the contact point P the current profile is divergent. This means that the current flow before the passage through the contact point P has a different direction to the current flow after the passage through the contact point P. Thus, an electromagnetic repulsive force is generated, which acts between the movable contact device 41 and the arms 43 b of the connecting conductor 43 .

The strength F _{1 of} the electromagnetic repulsive force results from the following equation:
F ₁ = Σ 5 I _j ² × 10 ^-2 (kg) (j = 1 to n)
where I _j (kA) is the current passing through a contact point P and n is the number of contact points P.

The electromagnetic repulsive force F ₁ increases abruptly as the current through the circuit breaker increases, and thus the current through each contact point P increases. As a result, the spring force of the springs 49 is reduced, so that the number of contact points P consequently becomes smaller, whereby the current passing through the remaining contact points P becomes extremely large. Thus, arcing or welding at the remaining contact points can occur.

Therefore, if the movable contact device 41 is in sliding contact with the connecting conductor 43 , the short-circuit current which can be applied is limited to a certain value. The limit value can be increased by increasing the spring force of the springs 49 . However, this proceeding is fraught with a difficulty that can be seen in that the movable contactor 41 normally moves at a low speed due to the fact that the frictional force increases. This difficulty can be overcome by the method described below. As shown in FIG. 5C and FIG. 9B, have the arms 43 b sections 58 in the vicinity of the contact portions of the arms 43 with the movable contact means 41, which are designed such that the distance between the portions 58 is smaller than the distance between the contact sections. The effect of sections 58 is described below with reference to FIG. 10A.

It is assumed that the section 58 of the arms has a length of 1 and that these are arranged at a distance S from one another. It is also assumed that a current of I (kA) flows in each arm 43 b. The currents I flowing in the arms 43 b have the same direction. The following electromagnetic attraction force F _{2 is} thus induced between the arms 43 b in:
F ₂ = 2.04 kl / S: I ² (where k is constant).

If the distance S is determined such that the electromagnetic attraction force F _{2 is} greater than the above-mentioned electromagnetic repulsive force F ₁ , then the short-circuit current which can be applied can be increased, the spring force of the springs 49 remaining unchanged. Fig. 11 is a graphical representation to illustrate the changes in the electromagnetic repulsive force F ₁ and the electromagnetic attraction force F ₂ depending on the short-circuit current passing through the circuit breaker. In addition, a contact force shown in FIG. 10A is directed to a force obtained by a resilience of the spring 49 and the connecting conductor 43 .

As shown in Fig. 9B, the circular projections ge 43 c, which are ausgebil det on the contact portions of the arms 43 b, serve as spacers to space the arms 43 from the movable contact means 41 , thereby reducing the distance between the currents flowing in opposite directions before and after the contact area is increased. As a result, the electromagnetic repulsive force F _{1 is} further reduced.

It is desirable that at least one of the sliding contact surface the movable contact device and the connecting conductor with a combination of silver (Ag) and carbon (C) plat is to overcome the difficulty that the Kon tact surfaces grind or weld when the separation switch is operated repeatedly in the de-energized state or if a high voltage interruption is made. Here is the electrical performance of the separation improved switch.  

Experimental examples of the circuit breaker were prepared in which the movable contact device 41 and the connecting conductor 43 , as shown in Fig. 5, are plated in the manner described above. The disconnectors were manufactured and tested according to the information below.

Test Example 1 - A thin layer of Ag - 6% C (volume%) was applied to the movable contact device 41 and the connecting conductor 43 with a thickness of 7 μm by means of electroplating. In this case, the carbon particles dispersed in the silver particles had a large diameter of 0.5 to 2 1 m and 0.2 to 0.5 µm.

Experimental Example 2 - In a similar manner, a thin layer of Ag - 3% C (volume%) was applied to the movable contact device 41 and the connecting conductor 43 with a thickness of 7 µm by means of electroplating. In this case, the carbon particles dispersed in the silver particles had a major diameter of 0.8 to 5 µm and 0.3 to 1 µm.

As a comparative example, a thin layer of Ag on the movable contactor and connector conductor with a thickness of 7 µm by means of electroplating upset.

These movable contact devices and connecting conductors were used to form disconnectors. There were a no-load switching test and a test with a Stark power interruption with the disconnectors manufactured in this way performed. The results obtained here are in the Table 1 below.  

Table 1

As can be seen from Table 1, the separating scarf ter with the movable contact device and the connector conductor, which is an Ag-C composite material in a thin Layer compared to the circuit breaker that was plated with Ag in the usual way, the copper hardly exposed. Although the two experimental examples were described percentages (%) and grain size of C (carbon) does not apply to the above te limited, since the effect according to the invention of the Properties of the carbon depends. The damage or the welding of the sliding contact section depends on the area and the applied surface pressure. Consequently the area and the surface pressure must be taken into account to adjust the volume percentage and grain size of the Koh to determine lenstoffs. However, it is not preferred that  Volume percentage to choose higher and the grain size of the Carbon (C) to choose excessively large, because despite the The fact that carbon (C) is conductive, this is the egg a few hundred or a few thousand times of resistance compared to silver (Ag). This relatively high cons stand accelerates the heat generation at the sliding contact section so that the connection temperature of the disconnector increases.

In the experimental examples described above, applied the electroplating method. However, they can movable contact device and the connecting conductor too be plated using other methods. It is here with only essential that it with an Ag-C-Verbundma be coated material.

The sliding contact portion is chafing or ver weld through the carbon layer formed thereon hindered. Therefore you can get essentially the same effect obtained by the thin Ag-C layer on one of the Parts comprising the movable contact device and the Connection conductor is formed. In this case the other part must be plated with silver (Ag). There however, carbon has an antioxidant effect, the silver plating does not necessarily need to be pre to be seen. This means that with regard to the elec trical properties in some cases can that no silver layer is provided. It is not always required the movable contact device and the connecting line as a whole with the thin layer cover. It is sufficient if the sliding surfaces with this thin layer are coated.

Furthermore, it is desirable to disperse the following hard particles as third particles in the Ag-C composite material to increase the hardness of the thin layer, so that sliding contact portions are obtained which are wear-resistant and therefore have a long service life. These are the following hard particles: SiC, WC, ZrB, Al ₂ O ₃ , ZrO ₂ , Cr ₂ O ₃ , TiO ₂ , R ₂ O ₃ , ThO ₂ , Y ₂ O ₃ × MoO ₃ , W ₂ C , TiC, B ₄ C and CrB ₂ .

As previously stated, the movable contact can be direction with the connecting conductor electrically without the Ver application of a flexible conductor in the invention connect laying. Therefore, the separation scarf according to the invention high operational reliability and excellent un refractive properties, and it can with respect to its Dimensions can be designed smaller. The disconnector has an increased service life because the sliding contact surfaces the movable contact device of the connecting conductor a silver and carbon composite material according to the inven are plated.

Although the invention has been described above with reference to preferred ones Embodiments have been explained in more detail themselves understandably numerous changes and modifications possible Lich, which the specialist will meet if necessary, without to leave the inventive idea.

Claims (5)

1. Disconnect switch in which a movable Kontaktin device is held by means of a holder made of electrically insulating material, which is rotatably mounted about a switching shaft on a housing, and in which the movable contact device is driven by a switching device such that they together around the switching shaft is pivotable with the holder for performing a switching operation, characterized in that the movable contact device ( 31 , 41 ) is slidably electrically connected to a connecting conductor ( 33 , 43 ) which is fixedly provided on the housing. 2. Disconnector according to claim 1, characterized in that the connecting conductor ( 33 , 43 ) has a pair of arms ( 33 a, 43 b) at the connection end, via which the connecting conductor ( 33 , 43 ) electrically with the movable contact device ( 31 , 41 ) is connected in such a way that the movable contact device ( 31 , 41 ) lies between the arms ( 33 a, 43 b), and that two springs ( 37 , 40 , 49 ) on both sides of the arms ( 33 a, 43 b) are arranged in such a way that the arms can be pressed against the side walls of the movable contact device ( 31 , 41 ). 3. Disconnector according to claim 2, characterized in that the arms ( 33 a, 43 b) of the connecting conductor ( 33 , 43 ) have inwardly curved sections in the vicinity of the contact surfaces of the arms with the movable contact device ( 31 , 41 ) in each case that the inwardly curved sections are opposite each other and the distance (S) between the inwardly curved sections is smaller than the distance between the contact surfaces. 4. Disconnector according to one of claims 1, 2 and 3, characterized in that the movable Kontaktinrich device ( 31 , 41 ) on a holding part ( 44 ) with engagement pieces ( 44 a, 44 b) is fixed by cutting a thin plate are formed, and that the holding part ( 44 ) by means of a press fit in a holder ( 36 , 54 ) with a recess ( 36 a) is provided, the engagement steps ( 45 a, 56 c, 56 d) corresponding to the engagement pieces in such a way that the movable contact device ( 31 , 41 ) is held by means of the holder ( 36 , 54 ). 5. Disconnector according to one of claims 1 to 4, characterized in that the sliding contact surfaces at least one of the parts comprising the movable Kontaktin direction ( 31 , 41 ) and the connecting conductor ( 33 , 43 ) is plated with a silver and carbon composite material.