KR20200099031A - Interlock Device of Electro-magnet Contactor - Google Patents

Abstract

The present invention relates to an interlock device of an electromagnetic contactor. More particularly, provided is the interlock device of an electromagnetic contactor having a mechanical interlock function. The interlock device of an electromagnetic contactor includes a first magnetic contactor and a second magnetic contactor arranged side by side, and an interlock unit coupled between the first and second magnetic contactors.

Description

Interlock Device of Electro-magnet Contactor

The present invention relates to an interlock mechanism of an electromagnetic contactor, and more particularly, to an interlock mechanism of an electromagnetic contactor having a mechanical interlock function.

In general, an electromagnetic contactor is a type of electrical circuit switching device that transmits a current signal and mechanical drive using the principle of an electromagnet, and is installed in various industrial facilities, machines, and vehicles.

In particular, the motor protection wiring breaker (MMS; Manual Motor Starters) supplies power to the load and cuts off the circuit when an overcurrent flows to prevent damage to the load-side motor. The circuit breaker for motor protection also has short circuit, overload and phase loss protection functions.

When a plurality of such magnetic contactors are connected and configured, an interlock mechanism (interlock device) may be provided in order to operate exclusively between the magnetic contactors. For example, in a system in which two magnetic contactors are connected, the interlock device may operate so that when one of the magnetic contactors is inserted, the other magnetic contactor is prevented from being inserted. Such an interlock device is also called a mechanical interlock device.

On the other hand, in order to safely use the magnetic contactor and increase its utilization, an electrical interlock is also used by adding an auxiliary contact (NC contact) inside the interlock device.

1 shows an electromagnetic contactor and an interlock unit according to the prior art. Two magnetic contactors are provided, and an interlock unit is provided between them.

An interlock unit 121 is installed between the first magnetic contactor 101 and the second magnetic contactor 111. The interlock unit 121 is fixedly installed on the side surfaces of the first magnetic contactor 101 and the second magnetic contactor 111. The interlock unit 121 is formed by inserting fixing protrusions 122 and 123 protruding from both sides of the interlock unit 121 into the fixing grooves 102 and 103 respectively formed on the side surfaces of the first magnetic contactor 101 and the second magnetic contactor 111. ) Is fixed between the first magnetic contactor 101 and the second magnetic contactor 111.

Crossbars 124 protruding from both sides of the interlock unit 121 are inserted into openings 104 formed on the side surfaces of the first and second magnetic contactors 101 and 111.

If the first holder 105 of the first magnetic contactor 101 is pressed, the first magnetic contactor 101 turns on and operates the crossbar 124 of the interlock unit 121. In addition, when the second holder 115 of the second magnetic contactor 111 is pressed, the second magnetic contactor 111 is turned on and operates the crossbar 124 of the interlock unit 121.

2 shows an internal structure diagram of the interlock unit 121 according to the prior art. When the first magnetic contactor 101 or the second magnetic contactor 111 is turned on, the crossbar 124 of the interlock unit 121 is pressed in connection therewith, and accordingly, the auxiliary movable contacts 106 and 107 descend together. Separated from the auxiliary fixed contacts (108, 109), the auxiliary contact is placed in an open state. That is, an electrical interlock function is achieved.

However, in the prior art, for customers who do not need such an auxiliary contact, it is mechanically and economically wasteful. Accordingly, there is a need for an interlock unit that does not have an auxiliary contact and has only a mechanical interlock configuration.

The present invention was conceived to solve the above-described problem, and its object is to provide an interlock mechanism for an electromagnetic contactor that performs only a mechanical interlock function and does not have an electrical interlock function.

The interlock mechanism of the magnetic contactor according to an embodiment of the present invention includes a first magnetic contactor and a second magnetic contactor arranged side by side, and an interlock unit coupled between the first and second magnetic contactors. An apparatus, wherein the interlock unit comprises: an enclosure; Each movable member installed in the case to be vertically movable and movable in connection with the input/blocking operation of each of the magnetic contactors; And each interlock member that is rotatably installed in the enclosure and moves in conjunction with each of the moving members, and when any one of the first magnetic contactor and the second magnetic contactor is inserted, the It is characterized in that one interlock member restricts the motion of the other interlock member to prevent the other magnetic contactor from being inserted.

Here, each of the movable members is characterized in that the holder connection portions are formed to protrude from the outer surfaces of each of the moving members, and operate in conjunction with each holder provided in the respective magnetic contactors.

In addition, each of the movable members is characterized in that the pressing portions are respectively protruding from the inner surface to operate the respective interlock members.

In addition, each of the interlock members has a claw-shaped locking portion and a groove-shaped locking receiving portion into which the locking-engaging portion is inserted, so that the locking-engaging portion of the one interlock member is a locking receiving portion of the other interlock member. When inserted into, it characterized in that the motion of the other interlock member is restricted.

In addition, each of the interlock members is characterized in that the contact portions protrude in opposite directions on the side surfaces of the interlock members to operate in conjunction with the pressing portions.

In addition, a return spring for providing a force for returning each of the interlock members to their original position is provided inside the enclosure.

In addition, a terminal closing member is provided in each of the terminal grooves of the interlock unit.

In addition, the terminal closing member is formed in a'b' shape, a first closing protrusion is formed at an upper end, and a second closing protrusion is formed at a lower end.

According to the interlock mechanism of the magnetic contactor according to an embodiment of the present invention, a mechanical interlock function is performed so that when one of the magnetic contactors is turned on in an adjacent magnetic contactor, the other magnetic contactor cannot be switched to the on state. do.

Further, in the interlock mechanism, the terminal portion is closed to prevent electrical interlocking.

In addition, since the enclosure of the conventional interlock mechanism can be applied as it is, the common use of parts is realized, and the product is not dualized.

1 is a perspective view showing a coupling relationship between an electromagnetic contactor and an interlock mechanism according to the prior art.
2 is an internal structure diagram of an interlock mechanism in FIG. 1.
3 is a perspective view showing a coupling relationship between an electromagnetic contactor and an interlock mechanism according to an embodiment of the present invention.
4 is an exploded perspective view of the electromagnetic contactor in FIG. 3.
5 is an internal structure diagram of the interlock mechanism in FIG. 3.
6 shows a state in which the holder is partially cut in FIG. 5.
7 is a side view of a crossbar applied to an electromagnetic contactor according to an embodiment of the present invention.
8 is a functional diagram of an interlock unit according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings, but this is for explaining in detail enough that a person of ordinary skill in the art can easily carry out the invention. It does not mean that the technical spirit and scope of the invention are limited.

An electromagnetic contactor according to each embodiment of the present invention will be described in detail with reference to the drawings.

The interlock mechanism of the magnetic contactor according to an embodiment of the present invention includes a first magnetic contactor 10 and a second magnetic contactor 30 and the first magnetic contactor 10 and the second magnetic contactor 30 arranged in parallel. Including an interlock unit 50 provided between,

3 is a perspective view showing a coupling relationship between an electromagnetic contactor and an interlock mechanism according to an embodiment of the present invention, FIG. 4 is an exploded perspective view of the electromagnetic contactor in FIG. 3, and FIG. 5 is an internal structure diagram of the interlock mechanism in FIG. 6 shows a state in which the holder is partially cut in FIG. 5. 7 is a side view of a moving member applied to an electromagnetic contactor according to an embodiment of the present invention.

Two magnetic contactors are provided. This will be classified as a first magnetic contactor 10 and a second magnetic contactor 30.

Electro-magnetic contactor is a type of electrical circuit switching device that transmits a current signal and mechanical drive using the principle of an electromagnet, and is installed in various industrial facilities, machines, and vehicles.

In particular, the motor protection wiring breaker (MMS; Manual Motor Starters) supplies power to the load and cuts off the circuit when an overcurrent flows to prevent damage to the load-side motor. The circuit breaker for motor protection also has short circuit, overload and phase loss protection functions.

First, let's look at the configuration of the magnetic contactor. The configuration of the first magnetic contactor 10 will be described. The second magnetic contactor 30 may also have the same basic configuration as the first magnetic contactor 10.

The upper frame 11 and the lower frame 12 are provided. The upper frame 11 is an upper part of the frame including a movable part, a contact part, and an arc extinguishing part, and the lower frame 12 is a lower part of the frame including a coil and a fixed core.

An arc chamber 13 including an extinguishing part for blocking arc when On/Off is provided on the upper frame 11.

A safety cover 14 may be provided on an upper portion of the arc chamber 13 as a safety device that prevents pressing of the holder 17 arbitrarily.

Inside the upper frame 11, a fixed contact 15 forming a fixed part of the main circuit is provided, and a terminal part is coupled around the fixed contact 15. The terminal part is a lug terminal kit (16a), which is a fastener for connecting lug-type wires, or a screw terminal kit (16b), which is a fastener for connecting O-type terminals and Y-type terminals. ) Is provided.

The holder 17 installed in the upper frame 11 so as to move up and down is assembled with the movable core 18 and the movable contact 19 to open and close when ON/OFF, and an interlock unit (interlock Mechanism) 50 is operated. The button 17a provided at the upper end of the holder 17 protrudes upward from the arc chamber 13 to allow the user to perform an on/off operation.

The moving contact 19 becomes a moving part of the main circuit terminal. When the movable contact 19 contacts the fixed contact 15, the main circuit is energized, and when the movable contact 19 is separated from the fixed contact 15, the main circuit is cut off.

When the control power (coil power) is supplied to the coil of the coil assembly 20, the moving core 18 is sucked by a fixed core 21 that becomes an electromagnet. The movable core 21 moves the holder 17 and the movable contact 19 together while moving.

When power is supplied to the coil assembly 20, a magnetic field is formed around the coil so that the movable core 18 and the fixed core 21 become electromagnets and are sucked.

When the power to the coil assembly 20 is cut off, the return spring 22 releases the movable core 18 and the holder 17 of the movable part to return to the original position.

When power is supplied to the coil assembly 20, the fixed core 21 becomes an electromagnet and sucks the movable core 18.

The magnetic contactor includes the above configuration. However, it is not necessarily limited to this embodiment. An electromagnetic contactor of various embodiments including a configuration for energizing or blocking a circuit including a movable part and a fixed part may be applicable.

A plurality of first lower grooves 23 and first upper grooves 24 are formed in the upper frame 11 and lower frame 12 of the first magnetic contactor 10 to fix the interlock unit 50. .

In addition, a first operation groove 25 is formed in the upper frame 11 of the first magnetic contactor 10 to connect the first holder 17 and the interlock unit 50.

The first lower groove 23, the first upper groove 24, and the first operation groove 25 as described above may be formed on both sides of the first magnetic contactor 10, respectively.

The second magnetic contactor 30 may also have the same configuration as the first magnetic contactor 10.

The second lower groove 43 and the second upper groove 44 to fix the interlock unit 50 to the upper frame 31 and the lower frame 12 to the lower frame 32 of the second magnetic contactor 30. Each of these is formed in plural.

A second operation groove 45 is formed in the upper frame 31 of the second magnetic contactor 30 to connect the second holder and the interlock unit 50.

The second lower groove 43, the second upper groove 44, and the second operation groove 45 as described above may be formed on both sides of the second electromagnetic contactor 30, respectively.

An interlock unit 50 is provided. The interlock unit 50 is provided to implement a mechanical interlock between the first magnetic contactor 10 and the second magnetic contactor 30.

The enclosure 51 of the interlock unit 50 may be formed of a synthetic resin material. The enclosure 51 may be formed in two stages by forming a stage. That is, the enclosure 51 of the interlock unit 50 may be formed in an uneven shape.

In the case 51, a first terminal groove 52 may be formed on the first end, and a second terminal groove 53 may be formed on the second end.

A guide portion 54 for guiding the vertical movement of the moving member 60 is formed on the inner surface of the enclosure 51. The guide portion 54 may be provided in a pair that is symmetrical.

The enclosure 51 is provided with a shaft protrusion 55 serving as a rotation shaft of the interlock members 70 and 80. The shaft protrusions 55 may be provided in a symmetrical pair.

A spring support 56 supporting the return spring 90 is protruded from the enclosure 51.

On the outer surface of the enclosure 51, a first lower groove 23 and a lower protrusion 57 and an upper protrusion 58 that are fitted into the first upper groove 24 of the magnetic contactor are protruded.

A moving member 60 is provided. The moving member 60 is also referred to as a crossbar. When any one of the magnetic contactors is turned on, the moving member 60 performs an interlock function to prevent the other magnetic contactor from being turned on.

The moving member 60 is composed of a first moving member 60a working with the first magnetic contactor 10 and a second moving member 60b working with the second magnetic contactor 30. The first moving member 60a and the second moving member 60b are disposed to face each other. The first moving member 60a and the second moving member 60b may have a part (middle part) formed symmetrically, and a part (upper part, lower part) may be formed asymmetrically.

A first auxiliary contact insertion portion 61 is provided at the upper end of the moving member 60 (first moving member 60a). The first auxiliary contact insertion part 61 may be provided with a first auxiliary movable contact and a first auxiliary spring. When the electrical interlock function is eliminated, the first auxiliary movable contact and the first auxiliary spring are not provided.

An interlock member insertion portion 62 is formed under the first auxiliary contact insertion portion 61 in the moving member 60. Interlock members 70 and 80 are inserted into the interlock member insertion portion 62 to operate.

In the moving member 60, a support part 63 is formed under the interlock member insertion part 62.

A second auxiliary contact insertion portion 64 is formed on the moving member 60 (the second moving member 60b). The second auxiliary contact insertion part 64 may be provided with a second auxiliary movable contact and a second auxiliary spring. When the electrical interlock function is deleted, the second auxiliary movable contact and the second auxiliary spring are not provided.

Holder connection portions 65a and 65b are formed to protrude outside the moving member 60, respectively. The holder connection portions 65a and 65b contact the holder 17 of the magnetic contactor through the operating grooves 25 and 45 of the magnetic contactor 10 and 30. Accordingly, when the holder 17 descends, it descends together to move the moving member 60 downward.

Upper pressing portions 66a and 66b and lower pressing portions 67a and 67b are respectively protruded from the inner surface of the lower portion of the interlock member insertion portion 62. Here, the distance between the upper pressing portions 66a and 66b and the lower pressing portions 67a and 67b is formed larger than the diameter of the contact portions 75 and 85 of the interlock members 70 and 80.

Interlock members 70 and 80 are provided. The interlock members 70 and 80 may include a first interlock member 70 and a second interlock member 80 that are symmetrical to each other. Here, the first interlock member 70 acts in response to any one of the adjacent magnetic contactors (for example, the first magnetic contactor 10), and the second interlock member 80 is among the adjacent magnetic contactors. It may act in response to another magnetic contactor (for example, the second magnetic contactor 30). This depends on which side the interlock unit 50 is installed. What is provided on the side of the first magnetic contactor 10 is referred to as a first interlock member 70, and that provided on the side of the second magnetic contactor 30 is referred to as a second interlock member 80.

The interlock members 70 and 80 may be formed in a hook shape.

The interlock members 70 and 80 are rotatably installed inside the enclosure 51. Shaft holes (not shown) are formed at the lower ends of the interlock members 70 and 80 and are fitted to the shaft protrusions 55. The interlock members 70 and 80 rotate based on the shaft protrusion 55.

Hook-shaped locking portions 72 and 82 are provided on the interlock members 70 and 80.

The interlock members 70 and 80 are provided with locking receiving portions 73 and 83 in a groove shape. The locking receiving portions 73 and 83 are formed in a shape corresponding to the locking engaging portions 72 and 82 to accommodate the locking engaging portions 72 and 82.

For example, the first locking portion 72 of the first interlock member 70 may be fitted to the second locking receiving portion 83 of the second interlock member 80. In this case, the second interlock member 80 is fixed and cannot rotate. Accordingly, since the second interlock member 80 restrains the second movable member 60b, input of the second magnetic contactor 30 is prevented.

On the contrary, when the second locking coupling portion 82 of the second interlock member 80 is fitted into the first lock receiving portion 73 of the first interlock member 70, the first interlock member 70 is fixed. Can't rotate Accordingly, since the first interlock member 70 restrains the first moving member 60a, the first magnetic contactor 10 is prevented from being inserted.

Spring fixing portions 74 and 84 are formed on the interlock members 70 and 80.

Contact portions 75 and 85 are protruded from the interlock members 70 and 80, respectively. Each of the contact portions 75 and 85 protrudes in opposite directions. The first contact portion 75 is formed to protrude in the direction of the first upper pressing portion 66a and the first lower pressing portion 67a, and the second contact portion 85 is in a direction opposite to the first locking portion 72 It protrudes in the direction of the second upper pressing portion 66b and the second lower pressing portion 67b.

The contact portions 75 and 85 are disposed between the upper pressing portions 66a and 66b and the lower pressing portions 67a and 67b. When the moving member 60 descends, the upper pressing portions 66a and 66b press the contact portions 75 and 85, and the interlock members 70 and 80 rotate. When the movable member 60 rises, the lower pressing portions 67a and 67b press the contact portion 75 so that the interlock members 70 and 80 rotate in reverse. In this case, the movement of the interlock members 70 and 80 may be smoothly performed by the return spring 90. Further, the interlock members 70 and 80 receive an upward force by the return spring 90.

A return spring 90 is provided. The return spring 90 is installed between the spring fixing portions 74 and 84 of the interlock members 70 and 80 and the spring support 56 of the enclosure 51.

Each terminal groove (52, 53) is provided with a terminal closing member (95). The terminal closing member 95 may be formed in a "L" shape by bending a plate-shaped member.

The terminal closing member 95 may have a first closing protrusion 96 inserted into the terminal grooves 52 and 53 at an upper portion and a second closing protrusion 97 formed at a lower end thereof.

A terminal closing member 95 is provided to close each of the terminal grooves 52 and 53, so that foreign substances such as dust are not inserted. In addition, since the conventional enclosure 51 can be applied as it is, there is no need to develop a new component.

5 and 8, the operation of the interlock unit 50 is as follows.

A state in which the first magnetic contactor 10 is put will be described. When the user presses the button 17a of the first holder 17 of the first magnetic contactor 10, the first magnetic contactor 10 is turned on (On). The first holder 17 lowers the first moving member 60a by pressing the first holder connecting portion 65a of the first moving member 60a of the moving member 60. Accordingly, the first upper pressing portion 66a of the first moving member 60a presses the first contact portion 75 of the first interlock member 70 so that the first interlock member 70 rotates (in FIG. Clockwise). The first locking engaging portion 72 of the first interlock member 70 is fitted into the second locking receiving portion 83 of the second interlock member 80. Accordingly, since the rotation of the second interlock member 80 is restricted, the movement of the second moving member 60b is restricted, and the input of the second magnetic contactor 30 is prevented.

On the other hand, at this time, since each of the terminal grooves 52 and 53 is closed, introduction of foreign substances or unnecessary connection is prevented.

When the second magnetic contactor 30 is inserted, a method in which the first magnetic contactor 10 is prevented is applied in the same manner, so a detailed description thereof will be omitted.

The operation when the first magnetic contactor 10 is blocked (off) is as follows. When the holder 17 of the first magnetic contactor 10 is turned off, that is, when it is returned upward, the force for restraining the first moving member 60a disappears. Accordingly, the return spring 90 rotates the first interlock member 70 reversely (counterclockwise in FIG. 8 ). The first contact portion 75 of the first interlock member 70 pushes up the first upper pressing portion 66a of the first moving member 60a to return the first moving member 60a upward.

Even when the second electromagnetic contactor 30 is blocked, a detailed description will be omitted since it can be applied in the same manner.

According to the interlock mechanism of the magnetic contactor according to an embodiment of the present invention, a mechanical interlock function is performed so that when one of the magnetic contactors is turned on in an adjacent magnetic contactor, the other magnetic contactor cannot be switched to the on state. do.

Further, in the interlock mechanism, the terminal portion is closed to prevent electrical interlocking.

In addition, since the enclosure of the conventional interlock mechanism can be applied as it is, the common use of parts is realized, and the product is not dualized.

The embodiments described above are embodiments for implementing the present invention, and those of ordinary skill in the art to which the present invention pertains will be able to make various modifications and variations without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain the technical idea, and the scope of the technical idea of the present invention is not limited by these embodiments. That is, the scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

10,30 Magnetic contactor 11,31 Upper frame
12,32 lower frame 13 arc chamber
15 Fixed contact 17 Holder
17a button 18 moving core
19 Moving contact 20 Coil assembly
21 Fixed core 23,43 Lower groove
24,44 Upper groove 25,45 Operating groove
50 interlock unit 51 enclosure
52,53 Terminal groove 54 Guide part
55 Shaft 56 Support
57 Lower protrusion 58 Upper protrusion
60a,60b moving member 61 first auxiliary contact insertion part
62 Interlock member insertion part 63 Support part
64 Second auxiliary contact insertion part 65a,65b Holder connection part
66a,66b upper pressing part 67a,67b lower pressing part
70,80 Interlock member 72,82 Locking part
73,83 Lock receiving part 74,84 Spring fixing part
75,85 contact 90 return spring
95 Terminal closing member 96,97 Closing protrusion

Claims (8)

In the interlock mechanism of an electromagnetic contactor comprising a first magnetic contactor and a second magnetic contactor arranged side by side, and an interlock unit coupled between the first and second magnetic contactors,
The interlock unit,
Enclosure;
Each movable member installed in the case to be vertically movable and movable in connection with the input/blocking operation of the respective magnetic contactors; And
Including; each interlock member is installed in the case to be rotatable and moves in association with each of the moving members,
When any one of the first and second magnetic contactors is inserted, the one interlock member restricts the motion of the other interlock member to prevent the other magnetic contactor from being inserted. Interlock mechanism of the magnetic contactor. The interlock mechanism of claim 1, wherein each of the movable members has a holder connecting portion protruding from an outer surface of each of the movable members so as to operate in conjunction with each holder provided in each of the magnetic contactors. The interlock mechanism of claim 1, wherein each of the movable members has a pressing portion protruding from an inner surface thereof to operate each of the interlock members. The method of claim 1, wherein each of the interlock members has a hook-shaped locking engaging portion and a groove-shaped locking receiving portion into which the locking engaging portion is inserted,
The interlock mechanism of an electromagnetic contactor, characterized in that when the locking coupling portion of the one interlock member is inserted into the lock receiving portion of the other interlock member, the motion of the other interlock member is restricted. The interlock mechanism according to claim 3, wherein the contact portions on the side surfaces of the interlock members protrude in opposite directions to operate in conjunction with the pressing portion. The interlock mechanism of claim 1, wherein a return spring is provided inside the enclosure to provide a force for returning the interlock members to their original position. The interlock mechanism of claim 1, wherein a terminal closing member is provided in each of the terminal grooves of the interlock unit. [8] The interlock mechanism of claim 7, wherein the terminal closing member has a'L' shape, a first closing protrusion is formed at an upper end, and a second closing protrusion is formed at a lower end.

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