JP2002525796A - switch - Google Patents

Abstract

(57) Abstract: The present invention relates to a method for controlling a contact between a switching shaft (3) for operating a contact (1) and a ratchet lever (10) for controlling disconnection in case of overload. It relates to a switch fitted with an actuating lever (13) which can be actuated by an actuating handle (17) which engages in a toggle joint (6, 7) by means of a movable spring (18) causing an interaction. The switch also has a catch lever (20) that interacts with the actuating lever (13), thereby preventing the actuating lever (13) from moving to the disconnected position when the contact (1) is blocked. Thus, when the contact (1) is closed, the catch lever (20) can be automatically brought into the catch position with respect to the actuating lever by rotation of the switch shaft (3).

Description

DETAILED DESCRIPTION OF THE INVENTION

The present invention relates to a switch according to the preamble of claim 1. In particular, the present invention relates to a low voltage switch having a locking member that prevents the actuation handle from moving to a switch off position when a switch contact is blocked.

[0002] Print publication DE 38 02 184 C2 discloses a low-voltage switch with a locking member formed as a locking link. In particular, the low-voltage switch can be moved by an actuation handle and has an actuation lever acting on a toggle joint by an actuation spring. One end of this toggle joint is connected to the contact carrier shaft and the other end is a ratchet
Supported by lever. The ratchet lever controls the elimination of excess current in the low voltage switch. The toggle coupling includes a toggle coupling link located at the same level as the locking link such that one end of the locking link is rotatably mounted on the latch casing and the other end is coupled to the actuating lever. I have. This means that when the contacts are welded, only the actuating lever to which the locking link is coupled can be moved until the locking link contacts the toggle joint link. If the actuation handle is moved further in the switch-off direction, the locking link is a toggle joint link in the switch-off direction in the sense that the actuation handle can only be moved in the switch-off direction when the welding of the contacts breaks at the same time. Momentum. In this way, this design mechanically prevents the actuation handle from moving to the OFF position when the contacts are welded, so that the person controlling the low voltage switch can easily identify this situation. Appropriate repair actions can be performed.

[0003] It is an object of the present invention to provide a low-voltage switch that, when the contacts are welded, can more safely prevent the operating handle from moving to the switch-off position when the contacts are welded. is there.

[0004] This object is achieved by combining the features defined in claim 1. Advantageous further developments of the invention are set out in the dependent claims.

Hereinafter, the present invention will be described in more detail by an embodiment with reference to the drawings.

As shown in FIG. 1, a movable contact 1 of a low-voltage switch is rotatably supported on a shaft 2 of a switch shaft 3. The switch shaft 3 itself is supported in a central casing, not shown. The switch shaft 3 has two satellite axes 4, 5 on opposing sides. These satellite axes also rotate when switch shaft 3 rotates about axis 2. The shaft 4 is an attachment point of the toggle joint link 6, and the other end of the toggle joint link 6 is connected to a toggle joint shaft 7
Is movably connected to a second toggle joint link formed in the shape of the triangular element 8. By means of an axis 9 the triangular element 8 is movably connected at a second corner to a ratchet lever 10. The ratchet lever 10 is rotatably supported on a fixedly arranged shaft 11 and serves to release the excess current of the switch latch.

As can be seen in detail from FIGS. 2 and 3, the triangular element 8 consists of two symmetrical plates extending parallel to each other, between which the ratchet lever 1 is located.
0 is mounted and supported on a joint shaft 9 which rigidly connects the plates to one another. The plates are connected by pins 12 in the region of the third corner of the triangular element 8. This pin 12 comes into contact with the ratchet lever 10 to limit the movement of the triangular element 8.

As already mentioned above, the toggle coupling links 6 are each provided on both sides of a triangular element 8 for symmetry, between which a ratchet lever 10 is located and connected to each other by a shaft 7. Actuating lever 1 partially shown in three dimensions in FIG.
3 consists of two plates, which at each level extend from two side plates 15 of the actuation / drive casing. Actuating lever 1
3, the lower part 13a is provided on the side of the working casing, as shown in FIG.
Each support portion 14 of the plate 15 is movably supported. In this embodiment, the operating lever 13 is formed of a single plate bent in a U-shape, and the connection portion is provided with a bolt 16 and an operating handle 17 protruding from the operating casing. Each side of the triangular element 8 has one actuating spring 1
8 is arranged between the toggle joint bolt acting as shaft 7 and the bolt 16 of the actuating lever 13. The casing side plate 15 and the lower part 13 a of the actuating lever 13 are arranged on both sides of the triangular element 8.

The release means is shown in FIG. By this release means,
The release of the ratchet lever 10 is controlled in a manner known per se.

In the ON position shown in FIGS. 1 and 4, the operating handle 17 is in a position inclined to the left such that the line of dynamic effect of the spring 18 extends to the left of the shaft 9. In the ON position, the ratchet lever 10 is engaged with the release means 19 and cannot be moved counterclockwise upwards by the spring force applied via the triangular element 8 and the shaft 9.
Thus, the spring force changes to rotate the triangular element 8 and the shaft 9 clockwise. At that time, the shaft 7 is intersected with the line connecting the shaft 9 and the shaft 4, so that when the ratchet lever 10 is blocked as described above, the toggle joint link 6
It will act on the switch shaft 3 in the closing direction of the movable contact 1.

FIG. 5 shows the operating position and the released position. The low-voltage switch reaches this operating position after the ratchet lever 10 has been released by the release means 19. In this operating position, the operating handle 17 assumes the position shown in FIG. In this position, axis 7
Due to the spring force applied to the triangular element 8, the triangular element 8 is pulled upward with the ratchet lever 10 and the toggle joint link 6 mounted to rotate on it,
As a result, the switch shaft 3 turns and the movable contact 1 separates.

In some cases, welding occurs during operation, so that the contact 1 cannot be separated simply by applying a tensile force by the spring 18. Such a state in which the release means 19 is open is shown in FIG. When this situation occurs, it cannot be determined from the position of the operating handle 17 whether or not the contact is separated. The switch design exhibits several special features described below so that the actual operating state of the contact 1 can be determined only by the position of the operating handle 17.

As already known from FIGS. 1 and 4, a locking lever 20 is arranged outside one or both of the side plates 15 of the working casing, and one end of the locking lever 20 is The switch shaft 3 is mounted for rotation on the satellite axis 5 and the other end is mounted for rotation on a fixed pin 21. The pin 21 is fixed to the side plate 15 and is guided in a long hole 22 formed in the locking lever 20. A protruding portion 23 is formed at an end of the locking lever 20 on the long hole side, and the protruding portion 23 can be engaged with a receiving position 24 formed in the operating lever 13. Thanks to this design, the final OFF position of the actuation handle 17 shown in FIG. 7, which shows that the contacts 1 are clearly separated, is prevented in the following manner.

First, the operating handle 17 is moved clockwise until the positions 24 and 23 are engaged. Attempting to move the actuation handle 17 in this direction results in thrust being applied directly from the actuation handle 17 via the actuation lever 13 to the locking lever 20, thereby clocking the switch shaft 3 via the shaft 5. A torque acting in the direction is generated. Due to the relatively short distance between the shafts 2 and 5, this torque is so small that the separation resistance caused by micro-welding on the contact 1 can be clearly seen on the actuation handle 17. Thus, anyone attempting to switch the switch off can immediately recognize that the actuation handle 17 will not enter the final OFF position.

If the welding of the contact 1 does not take place, the locking lever 20 assumes the position shown in FIG. 5, so that the operating handle 17 together with the operating lever 13 is free to the final OFF position shown in FIG. Can move. In this manner, the pin 25 applied to the operating lever 13 engages the ratchet lever 10 and
Until the lever 10 reaches the catch position in the release means 19, the ratchet lever 1
Press 0 clockwise downward.

An actuating lever 13 is attached to the switch, and the actuating lever 13 can be actuated by an actuation handle 17 and acts on the toggle joints 6, 7, 8 by an actuation spring 18, and the toggle joints 6, 7 , 8 are a switch shaft 3 for actuating the contact 1 and a ratchet lever 1 for controlling the elimination of excess current.
An operation connection is established between the communication device and the "0". The switch also has a locking lever 20, which interacts with the actuation lever 13 and prevents the actuation handle 17 from moving to the switch-off position when the contact 1 is blocked, The rotation of the switch shaft 3 when 1 is closed allows the locking lever 20 to automatically enter the locking position in relation to the actuating lever.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view of a low-voltage switch according to an embodiment in a switch-on state with an operating handle in an ON position.

FIG. 2 shows the low voltage switch shown in FIG. 1 in which a spring is stretched between a shaft fixed to the operating lever and the toggle joint shaft to simultaneously operate the toggle joint link and the ratchet lever. FIG. 4 is an enlarged perspective view of the internal assembly.

FIG. 3 is an enlarged perspective view of the assembly shown in FIG. 2, further illustrating the mounting of the side plates of the working casing and the release means interacting with the ratchet lever;

FIG. 4 is a perspective view of the low-voltage switch shown in FIG. 1;

FIG. 5 is a cross-sectional view of the low-voltage switch in a switch-off state with an operating handle in an inoperative position.

FIG. 6 is a cross-sectional view of the low-voltage switch in a transient operating position, still in a switched-on state due to welding of the contacts, and preventing shifting of the operating handle to an OFF position.

FIG. 7 is a cross-sectional view of a low-voltage switch in a switch-off state in which an operation handle can freely assume an OFF position.

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Claims (7)

[Claims] An actuation lever (1) which can be actuated by an actuation handle (17) and which acts on a toggle joint (6, 7, 8) by an actuation spring (18).
3) wherein the toggle joints (6, 7, 8) include a switch shaft (3) for operating the contact (1) and a ratchet lever ( An actuating lever (13) for establishing an operative connection between the actuating lever (13) and the actuating handle (17) when the contact (1) is blocked and the actuation handle (17) is switched off. Locking to prevent movement to position
A switch including a lever (20), wherein movement of the switch shaft (3) closing the contact (1) causes the locking lever (20) to be associated with the actuation lever (13). Switch that can be automatically put into the locked position by pressing 2. The locking device according to claim 1, wherein one end of said locking lever (20) is movably mounted on a first mounting part (5) of said switch shaft (3) and comprises a guide element (22). Switch according to claim 1, characterized in that the other end of the lever (20) is supported by a bearing (21). 3. The switch according to claim 2, wherein the bearing (21) is formed as a guide pin and is fixed to the casing-side plate (15). 4. The toggle coupling includes two toggle coupling links (6, 8), the toggle coupling links (6, 8) being connected to each other by a toggle coupling shaft (7), and the first toggle coupling. A link (8) is movably connected to the ratchet lever (10), and the second toggle coupling link (6) is located on the switch shaft (3) and the first eccentric shaft (5). ) And a second eccentric shaft (
The switch according to claim 2, wherein the switch rotates in 4). 5. Toggle joint shaft (9) for two identical triangular plates extending parallel to one another, said ratchet lever (10) being arranged between the plates.
A switch according to claim 4, characterized in that said first toggle coupling link (8) is formed by a triangular plate connected in at least one area of the corner by a pin acting in the manner described above. 6. The operating lever (13) is provided on a casing side plate (15).
Formed at the same level as the plate, said plate being in an open position () for receiving a projection (23) of said locking lever (20).
24) and an open portion (14) of the casing side plate (15).
Switch according to claim 1, characterized in that it is supported by a support part (13a) deviating from said actuation handle (17). 7. A part of the casing side plate (15) adjacent to the operating handle (17) has a projection (15a) on which the operating lever (13) can be supported in a switched-on state. The switch according to claim 6, wherein the switch comprises: