FI20185385A1 - Switching device - Google Patents

Abstract

Coupling device comprising a body part (2), a working shaft (4) arranged to pivot in relation to the body part (2) around a pivot shaft (41) between a first position and a second position in order to move a contact system from a closed position to an open position, a drive spring system comprising at least one drive spring (11), the drive spring system has a tuned position and a released position such that the drive spring system is arranged to move from the tuned position to the triggered position in an opening event. to swing the working shaft (4) to the second position. The coupling device comprises a limiting system which is arranged in connection with the opening event to cause a first limiting event, in which the limiting system restricts the movement of the working shaft (4) from the second position back to the first position, the limiting system comprising a limiting nose (6) which has been created in relation to the working shaft (4), and a constraint spring (8) arranged to cooperate with the constraint nose (6) in order to effect a first constraint event.

Description

The switch device

Background of the invention

The invention relates to a switching device comprising a drive spring system adapted to move from an excited state to a triggered state in an opening operation in order to turn the working axis of the switching device to a position corresponding to the open position of the contacts.

The problem with the switching device described above is that, in connection with the opening operation, the working shaft tends to move backwards from the position corresponding to the open position of the contacts back towards the closed position of the contacts 10 due to the service spring system. This rebound phenomenon results in the movable contact temporarily returning to a position where its distance from the corresponding fixed contact is less than the opening interval, thus extending the arc duration and shortening the contact life.

Brief description of the invention

The object of the invention is to develop a switching device with which the above-mentioned problem can be solved. The object of the invention is achieved by a switching device which is characterized by what is stated in the independent claim. Preferred embodiments of the invention are the subject of dependent claims.

The invention is based on the fact that the switching device is provided with a restraint system 20 which, in connection with the opening event, is adapted to limit the movement of the working shaft from the position corresponding to the open position of the contacts back towards the position corresponding to the closed position of the contacts. The restraint system comprises a restraint cam provided immovably relative to the working shaft and a restraint spring adapted to cooperate with the restraint cam to provide a restraint event.

The switching device according to the invention has the advantage of shortening the duration of the arc during the opening event, and due to the shortening of the duration of the arc, a longer service life of the contacts.

Brief description of the figures

The invention will now be described in more detail in connection with preferred embodiments, with reference to the accompanying drawings, in which:

Fig. 1 shows a switching device according to an embodiment of the invention, seen from the side and cut open in a situation in which the working axis of the switching device is from a position corresponding to the open position of the contacts;

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Fig. 2 shows the switching device of Fig. 1 in a situation in which the working axis of the switching device is in a position corresponding to the closed position of the contacts;

Fig. 3 shows the switching device of Fig. 1 and the contact system connected thereto as an axonometric projection;

Fig. 4 shows the switching device of Fig. 2 and the contact system connected thereto as an axonometric projection;

Fig. 5 shows a side view of the working axis of the switching device of Fig. 1;

Fig. 6 shows the working axis of Fig. 5 as an axonometric projection;

Fig. 7 is a side view of the stop spring of the coupling device of Fig. 1; and

Fig. 8 shows the limiting spring of Fig. 7 as an axonometric projection.

Detailed description of the invention

Fig. 1 shows a side view and an open section of a coupling device comprising a body part 2, a guide shaft 101, a work shaft 4, a drive spring system 15 comprising a first drive spring 11 and a second drive spring, and a restraint system comprising a stop cam 6 and a stop spring 8. The work shaft 4 is adapted to pivot relative to the body portion 2 about a pivot axis 41 between a first position and a second position, for moving the contact system from a closed position to an open position. The service spring system has a tuned state and a triggered state so that the operating spring system is adapted in the opening event to move from the tuned state to the triggered state in order to turn the working shaft 4 to another position.

In Fig. 1, the working shaft 4 of the switching device is in its second position, which corresponds to the open position of the contact system. In Fig. 2, the working shaft 4 of the switching device is in its first position, which corresponds to the closed position of the contact system. The second drive spring 12 of the service spring system is partially shown in Figure 2.

The restraint system is adapted in connection with the opening event to provide a first restraint event in which the restraint system restricts the movement of the working shaft 4 from the second position backwards towards the first position. The stop cam 6 of the restraint system is provided stationary relative to the working shaft 4, and the stop spring 8 is adapted to cooperate with the stop cam 6 to effect the first restraint event.

In connection with the switching event, i.e. when turning the working shaft 4 from the second position to the first position, the reciprocating phenomenon of the contact system recovery 35 practically does not occur due to the internal friction of the contact system. Thus, there is typically no need to adapt the restraint system to the coupling method

20185385 prh 24-04-2018 in connection with the core to limit the movement of the working shaft caused by the service spring system from the position corresponding to the closed position of the contacts backwards towards the position corresponding to the open position of the contacts.

Fig. 3 shows the switching device of Fig. 1 and the contact system connected thereto as an axonometric projection. In Fig. 3, the working shaft 4 is in its second position, and the contact system is in the open position. Fig. 4 shows the switching device of Fig. 2 and the contact system connected thereto as an axonometric projection. In Fig. 4, the working shaft 4 is in its first position, and the contact system is in the closed position. Moving from the situation of Figure 3 to the situation of Figure 4, the working shaft 4 10 rotates clockwise. In Figures 3 and 4, the body part 2 of the switching device is cut open more than in Figures 1 and 2.

The contact system has a first fixed contact 51, a second fixed contact 52, a first movable contact 71 and a second movable contact 72, each of which is made of a highly conductive material 15. The first fixed contact 51 and the second fixed contact 52 are fixedly mounted relative to the body portion 2, spaced apart. The first movable contact 71 and the second movable contact 72 are in electrically conductive communication with each other.

The first movable contact 71 is fixedly mounted relative to the working shaft 4 so that in the first position of the working shaft 4 shown in Fig. 4 the first movable contact 71 is in electrically conductive communication with the first fixed contact 51, and in the second position of the working shaft 4 shown in Fig. 3 the first movable contact 71 is a fixed contact 51. The second movable contact 72 is fixed 25 with respect to the working shaft 4 such that in the first position of the working shaft 4 shown in Fig. 4 the second movable contact 72 is in electrically conductive communication with the second fixed contact 52, and in the second position of the working shaft 4 shown in Fig. 3 is at the opening distance from the second fixed contact 52.

In an alternative embodiment, the contact system comprises only one movable contact, said single movable contact being electrically conductive to connect the first fixed contact and the second fixed contact. In such an embodiment, one arc is formed in connection with the opening event in an embodiment with less than two movable contacts. The second movable contact can be replaced, for example, by a flexible copper braid.

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The guide shaft 101 is adapted to rotate the working shaft 4 between the first position and the second position. The guide shaft 101 is adapted to be connected to a handle (not shown) which, by turning it, allows the user to turn the working shaft 4 between the first position and the second position. The guide shaft 101 is not adapted to pivot the work shaft 4 directly, but via a service spring system to ensure a reliable and rapid transition between the first position and the second position of the work shaft 4. A reliable and fast transition between the first position and the second position is particularly important in embodiments where the switching device is used to cut off the high voltage direct current. In these embodiments, the restraint system of the invention is particularly useful.

Fig. 5 shows the working shaft 4 seen from the side, and Fig. 6 shows the working shaft 4 as an axonometric projection. The stop cam 6 of the working shaft 4 comprises a first cam surface 61 and a second cam surface 62 located on different sides of the radially outermost point of the stop cam 6. The working shaft 4 is adapted to be connected to the contact system by means of a connecting system comprising a first connecting member 441 at the first end of the working shaft 4 and a second connecting member 442 at the second end of the working shaft 4.

The stop cam 6 is provided on the work shaft 4. The stop cam 6 is an integral part of the work shaft 4, and is made of the same material as the body of the work shaft 4, from which the stop cam 6 projects in the radial direction.

In Figs. 3 and 4, the working shaft 4 is connected to the contact system via a first connecting member 441 such that the first connecting member 441 is fixedly connected to the contact system roller 75. The first movable contact 71 and the second movable contact 72 are mounted on the roller 75 and immovable relative to the roller 75.

Fig. 7 shows the stop spring 8 seen from the side, and Fig. 8 shows the stop spring 8 in axonometric projection. The stop spring 8 comprises a base part 80, a first stop part 815 and a second stop part 825. The base part 80 comprises a first end part 801 and a second end part 802, which in the rest position of the stop spring are substantially planar parts and extend in the same plane. The first end portion 801 communicates with the second end portion 802 via a first restriction portion 815 and a second restriction portion 825.

The stop spring 8 is a bent flat spring which, in the first and second stop events, is adapted to spring in a direction perpendicular to the outward direction 35 of the working shaft 4 with respect to the pivot axis 41. The first end portion 801 and the second end portion 802 of the base portion 80 are supported substantially relative to the body portion 2.

20185385 prh 24-04-2018 stationary so that in the first and second restraining events the restraining spring 8 bends in an arc with respect to its rest position, whereby energy is stored in the restraining spring 8. The stop spring 8 bends in an arc because the first end portion 801 and the second end portion 802 of the base portion 80 cannot move vertically. An event in which energy is stored in the limiting spring 8 resists the rotation of the working shaft 4.

The stop spring 8 is made of a plate-like blank by bending. In an alternative embodiment, the stop spring is made of a wire of suitable stiffness. The stop spring can be made of, for example, metal 10 or plastic.

The first restraining portion 815 of the restraining spring 8 has a first restraining surface 81, and the second restraining portion 825 has a second restraining surface 82. The first restraining surface 81 extends at a first restraining angle α1 with respect to the base portion 80. The second abutment surface 82 extends at a second abutment angle α2 with respect to the basic portion 80. The first restraint angle α1 is about 70 °, and the second restraint angle α2 is about 20 °. Accordingly, the first cam surface 61 extends at an angle of about 70 °, and the second cam surface 62 extends outwardly at an angle of about 20 ° with respect to a plane perpendicular to the radial direction of the working shaft 4. In an alternative embodiment, the first restraint angle is 50 ° to 80 °, and the second restraint angle is 10 ° to 35 °.

The first restraining surface 81 is adapted to cooperate with the first cam surface 61 to produce a first restraining event, i.e. to restrain the movement of the working shaft 4 from the second position backwards towards the first position. It can be seen from Figure 1 that the first abutment surface 25 is in contact with the first cam surface, and thus limits the rotation of the working shaft 4 clockwise.

The second restraining surface 82 is adapted to cooperate with the second cam surface 62 to provide a second restraining event in which the restraint system restricts the movement of the work shaft 4 in the direction of the second position. The stop cam 6 30 and the stop spring 8 are arranged such that the first stop event limits the rotation of the working shaft 4 by a greater torque than the second stop event. The higher constraint of the first constraint event is due to the fact that the first constraint angle is significantly larger than the second constraint angle.

In an alternative embodiment, where it is desired that the torque of the first restraint event and the moment of the second restraint event be less different, the first restraint angle is 20 ° to 30 ° greater than the second restraint angle.

20185385 prh 24-04-2018 the restriction angle. In another alternative embodiment, the torque of the second constraint event is greater than or equal to the torque of the first constraint event.

The switching device of Figure 1 is a control module of a modular switching device assembly which does not include a contact system but is adapted to be connected to one or more pole modules by means of a connection system, wherein the one or more pole modules include a contact system. The control module can be connected to one pole module via the first connecting member 441, and to the second pole module via the second connecting member 442. In one embodiment 10, each pole module is adapted to comprise a connection system similar to the control module of Figure 1, wherein the shaft of the pole module can be connected to the shaft of the second module from both its first axial end and its second axial end.

Figures 3 and 4 show a contact system 15 of one pole module comprising a first fixed contact 51, a second fixed contact 52, a first movable contact 71 and a second movable contact 72. The body part of the pole module is not shown at all in Figures 3 and 4 in order to make the contact system as good as possible. visible. Modular switching devices comprising a control module and one or more pole modules, and optionally one or more accessory modules, are well known in the art and their construction will therefore not be described in more detail here.

In an alternative embodiment, the contact system is provided in the same body part as the work shaft and the service spring system. In another alternative embodiment, the body portion of the coupling device comprises a plurality of body sub-modules such that the service spring system is located in a different body module than the restraint system. For example, the embodiment shown in Figures 3 and 4 can be modified so that the stop cam and the stop spring are located in the pole module instead of the control module, whereby the stop cam is provided on the roller of the pole module.

It is obvious to a person skilled in the art that the basic idea of the invention can be implemented in many different ways. The invention and its embodiments are thus not limited to the examples described above but may vary within the scope of the claims.

Claims (9)

The claims A switching device comprising: body portion (2); a working shaft (4) adapted to pivot relative to the body portion (2) about a pivot axis (41) between the first position and the second position to move the contact system from the closed position to the open position; a drive spring system comprising at least one drive spring (11), the drive spring system having a tuned state and a tripped state such that the drive spring system is adapted in the opening event to move from the tuned state 10 to the triggered state to turn the working shaft (4) to another position in connection with the opening event, provide a first restraining event in which the restraint system restricts the movement of the work shaft (4) back from the second position back to the first position, the restraint system comprising a restraining cam (6) provided immovably relative to the work shaft (4) and a restraining spring (8) adapted to co-operate with the restriction cam (6) to effect the first restriction event. Coupling device according to claim 1, characterized in that the stop cam (6) comprises a first cam surface (61) and a stop spring (8) 20 comprises a first restraining surface (81) such that the first restraining surface (81) is adapted to cooperate with the first cam surface (61) to cause a first restraining event. Coupling device according to claim 2, characterized in that the stop cam (6) comprises a second cam surface (62), and the stop spring (8) comprises 25 a second restraining surface (82) such that the second restraining surface (82) is adapted to cooperate with the second cam surface (62) to provide a second restraining event in which the restraining system restricts movement of the work shaft (4) toward the second position. Coupling device according to Claim 3, characterized in that the stop cam (6) and the stop spring (8) are arranged such that the first stop event limits the rotation of the working shaft (4) by a greater torque than the second stop event. Coupling device according to Claim 4, characterized in that the stop spring (8) is a bent flat spring which is arranged in the first and second 35 in the restraining event to resiliently outwards in a direction perpendicular to the pivot axis (41) of the working shaft (4), and the restraining spring (8) comprises a base part 20185385 prh 24-04-2018 (80), the first restraining portion (815) and the second restraining portion (825) such that the first restraining surface (81) is the surface of the first restraining portion (815) and extends at a first restraining angle (α1) relative to the base portion (80) , and the second restraining surface (82) is the surface of the second restraining portion (825), and extends in the second restraining angle (α2) with respect to the base portion (80), and the first restraining angle (α1) is larger than the second restraining angle (α2). Coupling device according to claim 5, characterized in that the base part (80) of the stop spring comprises a first end part (801) and a second end part (802) which are substantially planar parts and extend in the same housing, and the first end part (801) communicates with the second end part (802) via the first restriction portion (815) and the second restriction portion (825). Switching device according to Claim 5 or 6, characterized in that the first limiting angle (α1) is at least 20 ° greater than the second limiting angle (α2). 15 Switching device according to Claim 5 or 6, characterized in that the first limiting angle (α1) is 50 ° to 80 ° and the second limiting angle (α2) is 10 ° to 35 °. Coupling device according to one of the preceding claims, characterized in that the stop cam (6) is provided on the working shaft (4). Switching device according to one of the preceding claims, characterized in that the switching device comprises a contact system having a first fixed contact (51) made of a highly electrically conductive material and fixedly mounted relative to the body part (2) and a first movable contact ( 71) made of a highly electrically conductive material and mounted immovably relative to the working shaft (4) such that in the first position of the working shaft (4), the first movable contact (71) is in electrically conductive communication with the first fixed contact (51); ) in the second position, the first movable contact (71) is at the opening distance from the fixed contact (51).