KR830002919Y1 - Vacuum switch - Google Patents

Abstract

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Description

Vacuum switch

1 and 2 are side views each showing a schematic configuration of a conventional vacuum switching device.

Figure 3 is a side view showing an embodiment of a vacuum opening and closing device according to the present invention.

4 is a front view showing the vacuum opening and closing device of FIG.

Figure 5 (a) (b) shows an embodiment of the box-shaped support frame which is the main part according to the present invention, (a) is a side view, (b) is a front view.

The present invention relates to a configuration for reducing the operating power of the vacuum opening and closing device.

In general, the electrode of the vacuum switch is a butt type, and when the switchgear is in the closed state, a large contact pressure of 200 to 4000 N is required to obtain a low contact resistance by making sufficient contact with both electrodes. Applying such a contact pressure causes a large deformation in the support of the frame or mechanism of the switchgear. If the elastic modulus of the frame or the like is E and the stress per unit area with respect to the distortion factor x and the contact pressure F is f, then f = Ex. At this time, the strain energy U per unit volume occurring in a frame or the like is U = 1/2. It can be represented as Ex ² .

This strain energy U is a kind of potential energy, which is absorbed by the frame of the switchgear and the support of the mechanism, so that it is a loss of operating power. However, in general, the material used for the strength is steel, and the structural material of the vacuum switchgear is used as well as steel, but the modulus of elasticity is generally constant, and there is no extreme difference depending on the type of steel. Therefore, the strain energy stored in the frame or the like is determined according to the magnitude of the distortion rate x. Moreover, the distortion rate x can be made smaller by reducing the external force, or by increasing the rigidity by increasing the rigidity of the structure. However, while the vertical distortion has been described above, in practice, the force given to the support of the frame or mechanism of the vacuum switching device is complicated because it acts as a bending moment, but the above-described principle is adapted, and if the arm is shortened for the same force, The bending moment can be made small, which is advantageous than making the structure larger by increasing the cross-sectional area.

1 is a schematic configuration showing an example of a conventional vacuum switch, wherein a vacuum switch (vacuum valve) 1 is fixed to a support insulator 2, and the support insulator 2 holds the whole apparatus ( It is installed in 3). The movable electrode bar 4 protruding from the upper part of the vacuum switch 1 is connected to one end of the operating lever 5, and the lever 5 is insulated from the vox 7 which stores the operating mechanism 6. Is rotatably supported by the pin 10 of the support plate 9 which is fixed via the < RTI ID = 0.0 > The other end of the lever 5 is connected to the operating rod 13 via the insulating rod 11 and the contact spring 12. (14) and (15) are contact terminals with an external circuit, and (16) is a flexible conductor connecting the movable electrode bar 4 and the terminal 14 to each other. The open / close contact portions 17 of each phase concentrated in this way are connected to one operation mechanism 6 via an operation shaft (not shown) to be opened and closed.

The operating power in the direction of arrow P given by the operating mechanism 6 is converted from the operating rod 13 to the lever Q in the direction of the arrow Q via the contact spring 12 and the insulating rod 11 and moves to the movable electrode rod 4. Is passed on. The force in the direction of the arrow Q is a necessary contact pressure, and acts on most of the support 3 via the fixed electrode and the support insulator 2. In addition, the reaction force acts on the pin 10 supporting the lever 5 in the direction of the arrow R, and the straight line and the box portion in the R direction including the pin 10 in the box portion 7 via the insulator 8. It acts as a bending moment in relation to the distance l ₁ from (7). Here, most of the support 3 to which the force in the direction of the arrow Q acts can use a thick and solid material relatively easily, and it is also possible to reduce the distortion. However, the bending moment acting in the direction of the arrow R is mainly related to the stiffness of the insulator 8, the part fixing the insulator 8 to the box portion 7, and these attachment bolts. It is inevitably determined in the structural strength, and it is difficult to make it solid by using a large material only for the purpose of reducing the distortion.

4 is an example of another vacuum opening and closing device. In this case, the box portion 7 is attached to the box portion 7 using the bolt 18. The vacuum switch 1 is supported by the insulating frame 19 of the shape. In addition, the lever 5 connected to the end of the insulating rod 11 fixed to the movable electrode 4 is connected to the pin 10 of the support plate 9 fixed to the box 7 for storing the operation mechanism 6. It is supported rotatably. The other end of the lever 5 is connected to the operating mechanism 6 via a contact spring not shown, such as the opening and closing device shown in FIG. In this hole, the contact pressure in the direction of the arrow Q acts as a bending moment relating to the distance l ₁ between the center line of the vacuum switch 1 and the attachment portion of the insulating frame 19, so that the strain energy is the insulating frame 19, It relates to the rigidity of the box portion 7 and the attachment bolt 18. The reaction force in the direction of the arrow R due to the contact pressure in the direction of the arrow Q is a bending moment related to the distance l ₃ between the straight line in the R direction including the pin 10 and the adhesion portion to the box portion 7 of the support plate 9. The strain energy is related to the stiffness of the pin 10, the support plate 9, the box portion 7 and these attachment bolts. However, in order to increase the rigidity of these parts, if the cross-sectional area thereof is increased, each part becomes large and influences to an irrelevant part, so that the shape of the whole becomes large. Particularly, in the portion where the bending moment occurs, the longer the arm, the larger the bending moment, which is the product of the force and the arm, becomes so large that there is a drawback to increase the distortion occurring in the portion, but it is difficult to shorten the pressure in this configuration. As described above, the conventional method for attaching a vacuum valve has the drawback that the deformation energy increases if the material is not made large and rigid, and the loss of operating power is large. Moreover, in the conventional structure, since the structure of the opening-and-closing contact part is not concentrated, it is impossible to assemble each phase integrally, and each component of each phase was couple | bonded individually with one operation mechanism.

Therefore, there is a drawback that the work efficiency is low and the production cost is increased because the assembly work cannot be divided.

The object of the present invention is to eliminate the above-mentioned drawbacks, and to provide a small and light vacuum opening and closing device with a small loss of operating power, and easy to assemble.

The object of the present invention is to provide a support, an operation mechanism provided on the support and the operation rod protruding vertically upwards, a box-shaped support frame placed on the support side by side with the operation mechanism, and the box support frame. A vacuum switch installed vertically with a support insulator on a lower side portion in close contact with the support of the supporter, an insulating rod extending vertically upward from a movable electrode rod at the top of the vacuum switch, and one end attached to the insulating rod The other end is attached to the operating rod, and an intermediate lever is rotatably supported on the upper side of the box-shaped support frame, and an external connection terminal of the vacuum breaker supported by the insulator on the box-shaped support frame. It is achieved by constructing.

Next, the present invention will be described in detail with reference to the accompanying drawings.

In FIGS. 3 and 4, the vacuum switch 1 has a support insulator 2 mounted vertically on and fixed on the lower base of the box-shaped support frame 20 in which the four sides are firmly occluded. It is. The movable electrode bar 4 protruding above the vacuum switch 1 is connected to one end of the lever 5 via the insulating rod 11. The other end of the lever 5 is connected to the operating rod 13 via the contact spring 12. The lever 5 is rotatably attached to the pin 10 of the support plate 9 fixed to the upper side of the box-shaped support frame 20, and the 14 and 15 are external connection terminals and the terminal 14 Is fixed by the insulator 8 attached to the box-shaped support frame 20 and is connected to the movable electrode bar 4 by the flexible conductor 16. The terminal 15 is connected to the fixed electrode.

The box-shaped support frame 20 is firmly fixed to the large part and the box part 7 of the support 3 using the bolt by the attachment plate 21 or the like. When the force in the direction of arrow P is applied to the operating rod 13 in the operating mechanism 6, the lever 5 rotates by using the pin 10 as a point, and moves to the movable electrode 4 via the insulating rod 11. Contact pressure is applied to the arrow Q direction. Also, the reaction force is generated in the direction of the arrow R. None of these forces are generated in the box-shaped support frame 20. The two days 20 are completely solid and are therefore very solid. Moreover, the structure is simple, and by simply thickening it, it is less disturbing to the surrounding structure, and the rigidity can be increased without much appearance. Therefore, large deformation does not occur. In addition, because the configuration according to the present invention is possible to reduce the distance ℓ ₄ of the reaction force and the arrow R direction acting on the force and the pin 10 in the arrow Q direction acting on the electrodes (4), those of power and ℓ ₄ The bending moment, which is a rising value of, becomes small, and in this respect, the deformation can be made small, and as a whole, the deformation energy can be greatly reduced.

In addition, the box-shaped support frame 20 is a strut parallel to the side portion 20c between the upper side portion 20a and the lower side portion 20b of the box-shaped support frame 20 as shown in FIG. By inserting 21), the stiffness of the whole frame can be increased to reduce the strain energy by reducing the strain energy. In this embodiment, the vacuum switch 1, the support insulator 2, the insulating rod 11, the lever 5, the contact spring 12, the operating rod 13, etc., which are divided for each phase, are common. Since it is attached to one box-shaped support frame 20, it is only necessary to connect these to the operation mechanism 6 after assembling them integrally, so that work can be divided and performed, thereby improving efficiency.

As described above, the vacuum switch on each of the vacuum switchgear according to the present invention is integrally coupled to the inside of the box-shaped support frame in which the four sides are tightly occluded and connected between the vacuum switch and the operation mechanism. The lever is rotatably attached to a support plate fixed to the box support frame. Therefore, the strong contact pressure and the reaction force applied to the movable electrode of the vacuum switch are all received by the ideal-shaped support frame.

Therefore, the deformation occurring in the structural member in accordance with the opening and closing operation of the device is small, the deformation energy is small. Thus, the loss of operating power becomes small, and it is possible to assemble the whole in a compact and lightweight. Furthermore, since the vacuum switch is assembled separately from the operation mechanism side, each phase can be combined with the operation mechanism, so that the assembly work is easy and the manufacturing cost can be reduced.

Claims (1)

A support stand 3, an operating mechanism 6 installed on the support stand 3, and an operating rod 13 protrudes vertically upward, and installed upright on the support stand 3 in parallel with the operation mechanism 6; The vacuum switch 1 installed vertically via the support insulator 2 on the box-shaped support frame 20 and the lower side portion 20b in close contact with the support 3 of the box-shaped support frame 20. And an insulating rod 11 extending vertically upward from the movable electrode rod 4 at the upper end of the vacuum switch 1, and one end of which is attached to the insulating rod 11, and the other end of the operation rod 13; The operating lever 5 attached to the center portion and rotatably supported by the upper side portion 20a of the box-shaped support frame 20, and the insulator 8 through the box-shaped support frame 20. Vacuum opening and closing device, characterized in that consisting of the external connection terminal (14) (15) of the vacuum switch (1) supported.