DE102006004401B3 - Contact system for an electrical switch with double contact has connecting springs that are movable by switch shafts to make or break the circuit - Google Patents

Abstract

A contact system (1) for an electrical switch comprises at least two contacts (3,5) with contact arms (2,4) in contacting positions if there is no short circuit. A closed current path is formed through contact spring elements (22) and to break the contact in case of a short these are movably arranged with a coupling piece that is connected to one or more switching shafts (27,28).

Description

The The invention relates to a contact system for an electrical switching device.

electrical switchgear with the most diverse contact systems are in large numbers known from the prior art. Among them are so-called Double Breaker contact systems, in case of a short circuit interrupting the current path with the help of a two-contacts, rotatable on one Shift shaft mounted switching arm in two places at the same time he follows. As a result, a comparatively fast opening can be ensured in the event of a short circuit become.

From It is always important that the opening process carried out safely and completely finished becomes. In other words, the switch once opened must not be switched on again fall. In many prior art double breaker contact systems this is only with elaborate Auxiliary devices possible.

A The object of the present invention is to provide a solution find, with a safe opening a contact system with at least two contacts is achieved.

These The object is achieved by a contact system according to claim 1. After that is a contact system for an electrical switching device provided with a arranged on a first contact arm first Contact and with a arranged on a second contact arm second Contact, where the two contact arms, if there is no short circuit, are arranged in a contact position in which the two contacts to form a closed current path, the two Contact arms over one or more spring elements connected to each other and to interrupt of the current path in a short circuit case movable on a coupling member are arranged, which connected to one or more switching shafts is.

A The core idea of the invention is, in a double breaker contact system assign each contact a separate contact arm. This allows a particularly advantageous arrangement of the contact arms to each other, the realized thereby according to the invention is that the two contact arms via spring elements with each other connected and beyond are movably arranged on a coupling member. This results a variety of constructive solutions to a safe opening process of the switch in the event of a short circuit. In particular, can through the constructive and functional interaction of contact arms, Spring elements and coupling member are ensured that the opening process is also completed safely and once a switch is not open again falls.

advantageous Embodiments of the invention are specified in the subclaims.

In a preferred embodiment the invention it is provided, the contact arms in such a way on the coupling member to arrange that a movement of the contact arms in the event of a short circuit from the contact position to an open position a displacement of the points of the spring elements and thus a Reduction of the torque acting on the switching shafts Episode has. In other words, the constructive elements of the Contact system preferably formed and arranged to each other, that when opening arising and the opening movement opposing torque decreases more and more, the farther the opening process progresses. An accidental closing of the switch is thereby considerably more difficult. At the same time, this is the prerequisite for a secure Trigger of the switch lock. Furthermore is it possible by the invention the contact arms opposite lead the solutions known from the prior art smaller trainees. Next A saving of material also means that the to be moved Masses are lower, what for the operation of the contact system is of considerable advantage.

According to one another preferred embodiment the invention, the spring elements are directly on the contact arms attached. It is particularly advantageous if the spring elements are integrated directly into the contact arms. This has the advantage that no extra Components are needed. The for the contact system according to the invention required space is therefore very low. It stands thus more space for other modules of the switching device to disposal. At the same time, they are decreasing other solutions the material, manufacturing and assembly costs, so that total a cost-effective solution can be provided.

The Invention will be described below with reference to an exemplary embodiment, that with the help of drawings closer explained becomes. This show in simplified, z. T. schematic representations:

1 a contact system in a contact position,

2 the contact system 1 in an open position when the switch lock is not triggered,

3 the contact system 1 in an open position when the switch lock is released, and

4 a coupling member, as in a contact system according to 1 is used.

An electrical switching device comprises a contact system 1 with one on a first contact arm 2 arranged first movable contact 3 and with one on a second contact arm 4 arranged second movable contact 5 , see. 1 , The two contact arms 2 . 4 extend substantially along a common longitudinal axis 6 , In the in 1 shown contact position (no short circuit) are the contact arms 2 . 4 arranged such that the two movable contacts 3 . 5 to form a closed current path. For this they are on corresponding fixed contacts 7 . 8th on, to designated contact carriers 9 . 10 are attached.

Every contact arm 2 . 4 has essentially the shape of a wedge extending from its foot 12 starting in the direction of the headboard 13 rejuvenated. This is the foot end 12 formed fork-shaped, wherein the fork shape by two stop elements 14 . 15 is formed. The one stop element 14 the fork is the contact arm top 16 and the other stop element 15 the fork of the contact arm base 17 assigned. Each stop element 14 . 15 has an inwardly directed abutment surface 18 . 19 on. The stop surfaces 18 . 19 a fork facing each other and are arranged at an acute angle to each other. They form between them a groove-shaped recording 21 out.

In the contact position take the two contact arms 2 . 4 a position in which in the area of the head ends facing away from each other 13 the contact arms 2 . 4 on the contact arm top 16 arranged movable contacts 3 . 5 lie parallel to each other. Here are the contact arms 2 . 4 along its longitudinal axis 6 arranged rotated by 180 ° from each other, so that the two moving contacts 3 . 5 pointing in opposite directions.

The two contact arms 2 . 4 are over two spring elements 22 connected in the form of prestressed helical tension springs. In this case, a spring element is on each side of the contact arm arrangement 22 intended. In the 1 to 3 Only the spring element of a page is visible. The spring elements 22 are each between those stop elements 14 the two contact arms 2 . 4 attached to the contact arm tops 16 assigned. Instead of the two separate spring elements 22 It is also possible to use a single spring element in the form of a double spring.

In the contact position, the two contact arms are based 2 . 4 with their directed towards each other and fork-shaped foot ends 12 on a coupling link 23 off, as it is in 4 is shown in a perspective view. These are the respective Kontaktarmoberseiten 16 associated stop elements 14 over the spring elements 22 connected to each other in such a way that the at the contact arms 2 . 4 attached moving contacts 3 . 5 on the fixed contacts 7 . 8th be pressed. In other words, the spring elements provide 22 on the one hand for the necessary contact pressure and on the other hand bind the contact arms 2 . 4 in the coupling link 23 ,

The coupling link 23 as well as the contact arms 2 . 4 is made of copper, for example, consists essentially of two identical, plate-shaped side parts 24 . 25 made of an electrically conductive material, which has two cylindrical guide sleeves 26 connected to each other. In the guide sleeves 26 are two mutually parallel switching shafts 27 . 28 a, corresponding to a rotation of the coupling member 23 around a rotation axis 29 are movable. This resulting axis of rotation 29 of the coupling member 23 runs at a central point of the coupling member 23 parallel to and between the guide sleeves 26 , In other words, the coupling element 23 with two switching shafts 27 . 28 coupled, which finally open the contact system after the release of the switching mechanism by a rotary motion. The insides of the guide sleeves 26 are made of an electrically insulating material, so that the metallic switching shafts 27 . 28 isolated from the individual current paths. The rest of the guide sleeves 26 is electrically conductive, since they serve as part of the circuit to guide the current through the switching device in the closed state. The coupling link 23 however, may also be in the form of a solid block of material in which two insulated holes extend.

In the contact position are the groove-shaped recordings 21 at the foot ends 12 the contact arms 2 . 4 on the guide sleeves 26 of the coupling member 23 at. At the same time, the spring-loaded stop elements are located 14 associated stop surfaces 18 at appropriately trained counter-attacks 31 on the side panels 24 . 25 of the coupling member 23 and depend on it.

In the contact position are the axes of the switching shafts 27 . 28 in a plane 32 (Coupling limb bene) parallel to the contact arm tops 16 corresponding - levels 33 (Contact levels) is arranged, in each of which the movable contacts 3 . 5 are arranged. The first counter-attacks 31 extend at an acute angle to the coupling element plane 32 ,

The U-shape of the contact carrier 9 . 10 and the arrangement of the contact arms 2 . 4 relative to the contact carriers 9 . 10 As a result, directly between the contact carriers 9 . 10 and the associated contact arms 2 . 4 the current flows in the opposite direction. As a result, occur in the contact arms 2 . 4 on the one hand and in the contact carriers 9 . 10 the fixed contacts 7 . 8th On the other hand, oppositely directed magnetic fields on which the magnetic contact arms 2 . 4 in the direction of an opening movement (direction of rotation 34 ) apply a repulsive magnetic force. In normal operation (no short circuit), however, the resulting magnetic force is smaller than the resulting contact force, on the one hand by the coupling member 23 attached spring elements 22 and on the other hand by not further described spring elements in the switch lock (not shown) is applied.

The embodiment according to the invention with two on a coupling member 23 supporting contact arms 2 . 4 also has the consequence of a movement of the individual contact arms 2 . 4 is independently possible, as is desirable under certain conditions. For example, the opening movement in a short circuit case for the contact arms 2 . 4 be different.

In the event of a short circuit, this increases due to the contact carriers 9 . 10 the fixed contacts 7 . 8th flowing electricity. The now much stronger oppositely directed magnetic fields cause that at the contact arms 2 . 4 attached moving contacts 3 . 5 against the spring force of the above spring elements of the fixed contacts 7 . 8th abruptly loosen and settle around as pads and turning surfaces for the contact arms 2 . 4 serving guide sleeves 26 at the coupling link 23 Turn away from its contact position about the axis of rotation of the coupling member (direction of rotation 34 ), see. 2 , In other words, the first contact arm rotates 2 in the direction of rotation 34 around the first guide sleeve 26 as a rotation axis and the second contact arm 4 turns in the same direction 34 around the opposite second guide sleeve 26 as a rotation axis. On the way the contact arms 2 . 4 Quenching plates or the like (not shown) are arranged at a suitable location, which as a means of extinguishing the between the movable contacts 3 . 5 and the fixed contacts 7 . 8th Share resulting arcs in many individual sheets.

By the rotation of the two contact arms 2 . 4 there is a change in the stop of the foot ends 12 on the coupling member 23 , While in the contact position, the spring-loaded stop elements 14 associated first stop surfaces 18 at first counter-attacks 31 of the coupling member 23 support, now support the first stop surfaces 18 opposite second stop surfaces 19 the other stop elements 15 at second counter attacks 35 starting on those sides of the side panels 24 . 25 of the coupling member 23 are provided, the first counter-attacks 31 lie opposite. The coupling link 23 In other words, each has two pairs of stops 31 . 35 and 31 ' . 35 ' , see. 4 , each one of the contact arms 2 . 4 assigned. Here are both first counter attacks 31 . 31 ' as well as the second counter-attacks 35 . 35 ' each parallel to each other. The second counter-attacks 35 are at an angle to the first counter-attacks 31 arranged such that the second counter-attacks 35 the longitudinal edges of the side parts 24 . 25 match during the first counter-attacks 31 by triangular, on the longitudinal edges of the side parts 24 . 24 patched and obliquely from the coupling member plane 32 away-pointing noses are formed.

Overall, there is thus a shift of the two contact levels 33 relative to the still unchanged position coupling member plane 32 , The stop surfaces 19 the stop elements 15 as well as the corresponding counterstops 35 of the coupling member 23 are matched to one another in such a way that the contact planes 33 no longer parallel to each other, but now include an acute angle. Here are the second counter attacks 35 still - as already in the contact position - parallel to the coupling element plane 32 ,

During this rotation of the contact arms 2 . 4 not only is a tensioning of the spring elements 22 , At the same time move the points of the spring elements 22 on a rotation track more and more on the plane of the two switching shafts 27 . 28 (Coupling member level 32 ) too. This means that the generated counter torque with increasing rotational movement is getting smaller, since the length of the effective lever arm is continuously reduced. The opening and the opening movement of the contact arms 2 . 4 opposing torque thus decreases more and more, the further the opening process progresses. As for a limitation of the rotational movement of the switching shafts 27 . 28 no fixed stop or the like is provided, the switching shafts move 27 . 28 in comparison to the known from the prior art solutions beyond the usual extent in the direction of rotation on, resulting in an additional tensioning of the spring elements 22 leads. Despite the increase in Fe However, the voltage is the torque on the switching shafts 27 . 28 According to the invention always smaller.

In other words, the bearing of the contact arms 2 . 4 on the coupling member 23 carried out such that when the contacts spring open 3 . 5 . 7 . 8th by the magnetic field, the distances between the points of attack of the spring elements 22 on the contact arms 2 . 4 on the one hand and the switching shafts 27 . 28 on the other hand, are getting smaller. The further the contacts 3 . 5 . 7 . 8th open, so the smaller is the resulting torque. As a result, the switch can open faster.

After a certain, due to the mechanical delay, the switch lock releases through the magnetic release and the switching shafts 27 . 28 be moved. As a result, the coupling member rotates 23 around its central axis of rotation 29 in the direction of rotation 36 , the direction of rotation 34 the contact arms during opening corresponds. The spring elements 22 relax and the contact arms 2 . 4 lie again with their first stop surfaces 18 at the first counter-attacks 31 of the coupling member 23 on, cf. 3 , This means that also the coupling element plane 32 again parallel to the contact planes 33 lies. The second counter-attacks 35 lie again parallel to the contact planes 33 , The switch is now open (triggered) and the opening process is safely completed without the risk of springing back into the contact position. Falling of the switch, for example, with a decrease in the short-circuit current is thus reliably prevented.

When closing the switch, the coupling member moves 23 a little way over the contact level 33 out. The resulting tension of the spring elements 22 causes the required contact force with which the moving contacts 3 . 5 in the closed state of the switch on the fixed contacts 7 . 8th to press.

Claims (3)

Contact system ( 1 ) for an electrical switching device, with one on a first contact arm ( 2 ) arranged first contact ( 3 ) and with one on a second contact arm ( 4 ) arranged second contact ( 5 ), whereby the two contact arms ( 2 . 4 ), if there is no short circuit, are arranged in a contact position in which the two contacts ( 3 . 5 ) to form a closed current path, wherein the two contact arms ( 2 . 4 ) via one or more spring elements ( 22 ) connected to each other and for interrupting the current path in a short circuit case movable on a coupling member ( 23 ) arranged with one or more switching shafts ( 27 . 28 ) connected is. Contact system ( 1 ) according to claim 1, characterized in that the contact arms ( 2 . 4 ) on the coupling element ( 23 ) are arranged such that a movement of the contact arms ( 2 . 4 ) in the event of a short circuit from the contact position to an open position, a displacement of the points of application of the spring elements ( 22 ) and thus a reduction of the on the switching shafts ( 27 . 28 ) has resulting torque. Contact system ( 1 ) according to claim 1 or 2, characterized in that the spring elements ( 22 ) directly on the contact arms ( 2 . 4 ) are attached.