KR101717658B1 - Auxiliary Contactor of Electgromagnetic Contactor - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an auxiliary contact mechanism of an electromagnetic contactor, and more particularly, to an auxiliary contact mechanism capable of supplying power for an exciter until a main contact point is closed in an exciting coil for opening and closing a main contact.
The auxiliary contact mechanism of the electromagnetic contactor according to an embodiment of the present invention includes a case formed in a box shape; An auxiliary sliding member installed on the case and moving up and down under pressure by the main contact sliding member; An elastic member accommodated in the auxiliary sliding member; A pressing member inserted into the lower portion of the auxiliary sliding member and moving up and down by an elastic force of the elastic member; And a micro switch which is turned on / off by the pressing member.

Description

[0001] The present invention relates to an auxiliary contactor of an electromagnetic contactor,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an auxiliary contact mechanism of an electromagnetic contactor, and more particularly, to an auxiliary contact mechanism capable of supplying power for an exciter until a main contact point is closed in an exciting coil for opening and closing a main contact.

Generally, an electromagnetic contactor is a kind of electric circuit switching device that transmits mechanical signals and current signals using the principle of an electromagnet, and is installed in various industrial equipments, machines, and vehicles.

The electromagnetic contactor may include a main contactor mechanism capable of supplying or blocking power to the load and a secondary contact mechanism composed of normally closed contacts for supplying or blocking power to the excitation coil of the main contact mechanism have.

1 is a perspective view showing a schematic configuration of an electromagnetic contactor according to the prior art. The electromagnetic contactor 100 according to an example of the prior art includes a main contact mechanism and a subsidiary contact mechanism 3. The main contact mechanism includes a main contact slide support member 1 and a magnetic coil 2. The main contact slide supporting member 1 is provided with an auxiliary contact pressing portion 1a formed in a part thereof so as to extend and protrude toward the auxiliary contact mechanism 3 side. The auxiliary contact pressing portion 1a moves upward and downward together with the main contact slide supporting member 1 to operate the auxiliary contact mechanism 3. [

FIG. 2 is a view showing the construction of the auxiliary contact mechanism of the coplanar contactor in FIG. 1, showing the closed state, and FIG. 3 showing the opened state. The detailed configuration and operation of the auxiliary contact mechanism 3 of the electromagnetic contactor according to the prior art will be described with reference to FIGS. 2 and 3. FIG.

The auxiliary contact mechanism 3 of the electromagnetic contactor according to the embodiment of the related art includes a contact support member 3a, a slide movement supporter 3b, a fixed contact 3c, a movable contact 3d, an auxiliary contact spring 3e, And a return spring 3f.

The contact supporting member 3a is fixedly installed inside the coil assembly accommodating case 4. [ A fixed contact 3c is fixed to the contact support member 3a and a shaft groove 3a1 into which the slide movement support 3b is inserted is formed.

The slide moving supporter 3b ascends and descends in the vertical direction through the shaft groove portion 3a1 of the contact supporting member 3a and the movable contact 3d is coupled to the central portion.

The fixed contacts 3c are formed as a pair and are provided on the contact supporting member 3a and each include a terminal portion exposed to the outside and a contact portion placed inside. One of the fixed contacts 3c may be connected to an external power source, and the other one may be connected to the excitation coil 2 of the main contact mechanism.

The movable contact 3d ascends and descends along the slide movement supporter 3b and can contact or separate from the fixed contact 3c.

The auxiliary urging spring 3e is provided between the bottom central portion of the movable contact 3d and the spring supporting protrusion formed at the lower portion of the slide moving supporter 3b and has an elastic force for pressing the movable contact 3d toward the fixed contact 3c to provide.

The return spring 3f is provided between the lower end of the slide movement supporter 3b and the bottom of the contact support member 3a and provides an elastic force for moving the slide movement supporter 3b upward.

The operation of the electromagnetic contactor to the closed position (On position) will be described.

When external control power is supplied to the auxiliary contact mechanism 3 in a state where the fixed contact 3c and the movable contact 3d are in contact with each other as shown in Fig. 2, a current flows in the excitation coil 2 of Fig. When a magnetic force is generated in the excitation coil 2, a main contact movable contactor (not shown) coupled to the main contact slide support member 1 by sucking the movable core (not shown) and the main contact slide support member 1 downward The main circuit is brought into the closed state by contacting the lower main contact fixed contact (not shown).

At this time, the auxiliary contact pressing portion 1a integrally connected to the main contact slide supporting member 1 is lowered and presses the upper end of the slide moving support 3b downward as shown in FIG. The slide moving supporter 3b and the movable contact 3d overcome the elastic force of the auxiliary contact spring 3e and the return spring 3f and move downward together. The movable contact 3d of the auxiliary contact mechanism 3 is disconnected from the fixed contact 3c and thus the control power supplied to the main contact mechanism via the auxiliary contact mechanism 3 is shut off. Thereafter, the main contact maintains the closed state through the holding current flowing in the exciting coil 2 separately.

On the other hand, the operation of the electromagnetic contactor to the open position (OFF position) will be described.

When the external control power supply is completely stopped, no current flows through the fixed contactor 3c even if the movable contact 3d contacts the fixed contact 3c as shown in Fig. 2, so that no current flows to the excitation coil 2 do. As a result, the magnetic attraction force when the movable core and the main contact slide supporting member 1 are sucked down is extinguished and the main contact slide supporting member 1 is moved upward by the elastic force of the return spring (not shown) It is placed in the open position.

At this time, the auxiliary contact pressing portion 1a also rises together with the main contact slide supporting member 10, and the pressure that presses the upper end of the sliding movement supporting portion 3b downward is extinguished. The slide moving supporter 3b and the movable contact 3d are moved upward together by the elastic force of the auxiliary urging spring 3e and the return spring 3f. The movable contact 3d of the auxiliary contact mechanism 3 comes into contact with the fixed contact 3c and waits for supply of the next control power.

However, the fixed contact 3c receives the acting load of the auxiliary contact pressing portion 1a directly through the slide moving supporter 3b. That is, the moving distance of the slide moving supporter 3b is formed to be the same as the moving distance of the main contact slide supporting member 10, and the contact time of the auxiliary contact pressing portion 1a with the slide moving supporter 3b is longer 3c and the movable contact 3d.

In this case, if the operation time is set at the beginning of the main contact mechanism operation time, the control power supply to the excitation coil 2 is stopped as the auxiliary contact mechanism is opened before the operation of the main contact mechanism to the closed position is completed, The operation of the contact mechanism to the closed position can not be completed.

If the operation time is set after the main contact mechanism operation time, the application of the current through the auxiliary contact mechanism to the excitation coil 2 is continued until the operation of the main contact mechanism to the closed position is completed, ) May be damaged.

Meanwhile, in the auxiliary contact mechanism of the electromagnetic contactor according to the related art, the auxiliary contact spring 3e and the return spring 3f are formed of compression springs, so that contact and separation of the fixed contact 3c and the movable contact 3d Time and load appear almost the same. That is, the load required for separating the movable contactor 3d from the fixed contactor 3c is almost equal to the load required for the movable contactor 3d to contact the fixed contactor 3c. Thus, there is a disadvantage that different operating points can not be set for the closed state and the open state of the main contact.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and an object of the present invention is to provide an electromagnetic contactor which is as close as possible to the main contact point opening / closing exciting coil at the time when the operation of the main contact point sliding member is completed so as to stably close the main contact point The auxiliary contact mechanism of the electromagnetic contactor is capable of supplying the control power until the voltage reaches a predetermined value.

The auxiliary contact mechanism of the electromagnetic contactor according to an embodiment of the present invention includes a case formed in a box shape; An auxiliary sliding member installed on the case and moving up and down under pressure by the main contact sliding member; An elastic member accommodated in the auxiliary sliding member; A pressing member inserted into the lower portion of the auxiliary sliding member and moving up and down by an elastic force of the elastic member; And a micro switch which is turned on / off by the pressing member.

Here, the elastic member is formed of a compression spring.

In addition, the auxiliary sliding member is formed with a latching piece protruding inwardly at a lower portion thereof, and a latching groove is formed at an upper portion of the pressing member so as to engage with the latching piece.

Further, the outer diameter of the pressing member is formed to be smaller than the inner diameter of the insertion groove.

The micro switch may include: a housing; A pair of terminal portions fixed to the inside of the housing and partially exposed to the outside of the housing; A leaf spring for connecting and separating the pair of terminal portions; And a contact button for applying a force to the plate spring by the pressing member.

Here, the minimum operating load of the elastic member is formed to be smaller than a load required for closing the leaf spring.

Further, the maximum operating load of the elastic member is formed to be larger than a load required for opening the leaf spring.

Further, the gap between the opening and closing operation sections of the auxiliary sliding member is formed to be larger than the operation gap of the contact button.

According to the auxiliary contact mechanism of the electromagnetic contactor according to the embodiment of the present invention, the operation timing of the auxiliary contact mechanism can be arbitrarily set within the operation time range of the main contact mechanism. That is, a micro switch including a leaf spring is applied to the auxiliary contact mechanism, so that the opening and closing timing of the auxiliary contact circuit are set differently, so that the operation gap can be formed. That is, when the main contact mechanism is closed, the auxiliary contact circuit can be kept at the closed position as much as possible until the operation of the main contact mechanism to the closed position is completed.

Thus, there is an effect that the phenomenon that the operation of the main contact mechanism to the closed position is incompletely completed is prevented. In addition, damage that may occur in the excitation coil of the main contact mechanism is prevented, and the chattering phenomenon is prevented.

In addition, the above-described opening interval of the opening and closing operation can be further extended as the elastic member is included in the auxiliary sliding member.

1 is a perspective view showing a schematic configuration of an electromagnetic contactor according to the prior art.
Fig. 2 is a view showing the configuration of the auxiliary contact mechanism of the coplanar contactor in Fig. 1, showing the closed state.
FIG. 3 is a view showing the configuration of the auxiliary contact mechanism of the coplanar contactor in FIG. 1, and shows an open state.
4 is a perspective view showing a schematic configuration of an electromagnetic contactor including an auxiliary contact mechanism according to an embodiment of the present invention.
5 is a front view of the auxiliary contact mechanism of the electromagnetic contactor in Fig.
6A and 6B show the operating states of the auxiliary contact mechanism of the electromagnetic contactor in FIG. 5, in which FIG. 6A shows that the auxiliary contact circuit is in the closed state, and FIG. 6B shows that the auxiliary contact circuit is in the open state.
7 is a front view of the auxiliary contact mechanism of the electromagnetic contactor according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings, which are intended to illustrate the present invention in a manner that allows a person skilled in the art to easily carry out the invention. And does not mean that the technical idea and scope of the invention are limited.

FIG. 4 is a perspective view showing a schematic configuration of an auxiliary contact mechanism of the electromagnetic contactor according to an embodiment of the present invention, and FIG. 5 is a front view of the auxiliary contact mechanism of the electromagnetic contactor in FIG. The auxiliary contact mechanism of the electromagnetic contactor according to each embodiment of the present invention will be described in detail with reference to the drawings.

The auxiliary contact mechanism of the electromagnetic contactor according to an embodiment of the present invention includes a case 10 formed in a box shape; An auxiliary sliding member (20) which moves upward and downward under pressure by the main contact sliding member (1); An elastic member (30) received in the auxiliary sliding member (20); A pushing member (40) inserted into the lower portion of the auxiliary sliding member (20) and moving up and down by an elastic force of the elastic member (30); And a micro switch (50) which is turned on / off by the pressing member.

The case 10 is roughly box-shaped. The front portion of the case 10 can be opened. A support portion 11 capable of supporting an auxiliary sliding member 20, which will be described later, may protrude from the upper portion of the case 10. A sliding hole (12) is formed through the support portion (11) at a central portion thereof.

The auxiliary sliding member 20 may be roughly shaped like a piston. The auxiliary sliding member 20 is inserted into the sliding hole 12 of the supporting portion 11. [ Inside the auxiliary sliding member 20, an insertion groove 21 into which an elastic member 30 to be described later can be inserted is formed. A projection 22 is formed on the upper portion of the insertion groove 21 so that the upper end of the elastic member 30 can be fixed. The lower end portion 23 of the auxiliary sliding member 20 is bent outward so that it can be caught by the lower portion of the support portion 11. [

The elastic member 30 is inserted into the insertion groove 21 of the auxiliary sliding member 20. Here, the elastic member 30 may be formed of a compression spring. The upper end of the elastic member 30 is fixed to the projection 22 of the auxiliary sliding member 20 and the lower end of the elastic member 30 is fixed to the upper portion of the pressing member 40 to be described later.

The pressing member 40 may be formed in a rod shape. The engaging portion 41 may be formed at the upper end of the pressing member 40 to be fixed to the lower end of the elastic member 30. Since the engaging portion 41 at the upper end of the pressing member 40 is fixed to the lower end of the elastic member 30 and the upper end of the elastic member 30 is fixed to the projection 22 of the auxiliary sliding member 20, The member 40 is suspended from the auxiliary sliding member 20 without being detached. At this time, the outer diameter of the pressing member 40 is formed smaller than the inner diameter of the insertion groove 21 of the auxiliary sliding member 20. The inner diameter of the insertion groove 21 and the outer diameter of the pressing member 40 can be appropriately adjusted so that the pressing member 40 can be slidably operated while maintaining an appropriate frictional force in the insertion groove 21. [ Lubricant may be applied between the insertion groove 21 and the pressing member 40 as required.

The micro switch (50) is installed at the lower part of the case (10). The micro switch 50 includes a housing 51 and a pair of terminal portions 52 and 53 fixed to the inside of the housing 51 and partially exposed to the outside of the housing 51, And a contact button 55 that presses the leaf spring 54. The contact spring 55 is formed of a plate spring, Such a microswitch 50 may be an off-the-shelf product.

5, when the contact button 55 is in the non-pushed state, the leaf spring 54 is connected to the left terminal portion 52 and the right terminal portion 53, so that the auxiliary contact circuit is in the closed state When the contact button 55 of the microswitch 50 is pressed as shown in FIG. 6B, the leaf spring 54 is separated from the right terminal portion 53, so that the auxiliary contact circuit is in the open state. Here, the operation of the microswitch 50 is different due to the characteristics of the leaf spring 54 and the load required for opening and closing operations. For example, the load required for the opening operation of the auxiliary contact circuit may be larger than the load required for the closing operation.

The operation of the auxiliary contact mechanism of the electromagnetic contactor according to the embodiment of the present invention is as follows. 5 shows a case where the auxiliary contact circuit is in the closed state. At this time, when the closing operation of the main contact mechanism proceeds and the auxiliary sliding member 20 is pressed by the auxiliary contact mechanism pressing portion 1a, the auxiliary sliding member 20 is lowered together with the elastic member 30, The same state is reached. When the pressing member 40 touches the contact button 55 of the micro switch 50, the pressing force of the auxiliary contact pressing portion 1a compresses the elastic member 30. When the pressing force exceeds the load of the elastic member 30, the pressing member 40 presses the pressing member 40 to actuate the contact button 55 (see FIG. 6B). As the contact button 55 is depressed, the auxiliary contact circuit is placed in the open state.

During the opening operation of the main contact mechanism, the auxiliary contact mechanism press portion 1a is raised, the pressure on the elastic member 30 is reduced, and the press member 40 is also raised. Thus, the contact button 55 is returned, The circuit is placed in the closed state and is then waiting for the next control power.

Here, a detailed example will be given as follows. The operation of the micro switch 50 has been described above in which the load required for opening and closing the auxiliary contact circuit can be formed differently depending on the characteristics of the leaf spring 54. The load required for opening is 120 g or more, Is set to 80 g or less and the operating load of the elastic member 30 is set to a minimum of 50 g to a maximum of 150 g.

First, let's take a look at the opening operation of the auxiliary contact mechanism (when the main contact mechanism is closed). When the load acting on the auxiliary sliding member 20 by the auxiliary contact pressing portion 1a is 0 to 50 g, the auxiliary sliding member 20 does not operate. That is, the auxiliary sliding member 20 remains in the position of (a) in FIG. 6A. When the load acting on the auxiliary sliding member 20 exceeds 50 g, the auxiliary sliding member 20 starts to descend, and when the working load reaches 120 g, the position of the auxiliary sliding member 20 moves to the position (c) And the contact button 55 of the micro switch 50 is operated. Therefore, the control power supplied to the main contact mechanism is cut off. When the working load reaches 150 g, the auxiliary sliding member 20 is placed at the position (d). Here, it can be seen that the operating range of the micro switch 50 at the open time is a period between (c) and (d). Fig. 6B corresponds to a point between (c) and (d) when the auxiliary contact circuit is in the open state.

On the other hand, the operation of closing the auxiliary contact mechanism (when the main contact mechanism is opened) will be described. When the control power supplied to the exciting coil 2 is completely cut off, the working load by the auxiliary contact pressing portion 1a starts to decrease. Here, the contact button 55 of the microswitch 50 maintains the open state as shown in FIG. 6B while a load of 80 to 150 g is applied to the auxiliary sliding member 20. When the working load reaches 80 g, the auxiliary sliding member 20 operates to be in the position of (b) in Fig. 6 (a). When the load acting on the auxiliary sliding member 20 is reduced to 80 g or less, the contact button 55 is raised and the microswitch 50 is placed in the closed state. Therefore, the auxiliary contact mechanism is closed and waits for the next control power source. Here, it can be seen that the operating range of the micro switch 50 at the time of closing is a section between (a) and (b).

Therefore, the operation intervals (b) to (c) are formed between the open time operation periods (c) to (d) of the auxiliary contact circuit and the close operation time periods (a) to (b). As described above, the operation of the auxiliary contact mechanism can be maintained until the time when the closing operation of the main contact mechanism is completed due to the existence of the operation interval at the opening and closing of the auxiliary contact circuit.

The clearances ((b) to (c)) can be extended due to the configuration of the elastic member 30. [ That is, the operation intervals ((b) to (c)) between the opening and closing operation sections of the auxiliary sliding member 20 are formed to be larger than the operation interval of the contact button 55. Therefore, the opening operation time and the closing operation time can be set differently.

One of the effects that occurs in this case is that the opening operation of the auxiliary contact mechanism is kept as long as possible until the closing operation of the main contact mechanism is completed, thereby preventing the main contact mechanism from being damaged or chattering.

7 shows an auxiliary contact mechanism of the electromagnetic contactor according to another embodiment of the present invention. In this embodiment, the auxiliary sliding member 20 is formed with a latching piece 24 protruding inward at its lower end. Further, the pressing member 40 is formed with a latching groove 42 along a longitudinal direction in a part thereof. The engaging piece 24 of the auxiliary sliding member 20 is inserted into the engaging groove 42 of the pressing member 40 so that the pressing member 40 does not separate from the auxiliary sliding member 20 and performs the sliding movement stably .

According to the auxiliary contact mechanism of the electromagnetic contactor according to the embodiment of the present invention, the operation timing of the auxiliary contact mechanism can be arbitrarily set within the operation time range of the main contact mechanism. That is, a micro switch including a leaf spring is applied to the auxiliary contact mechanism, so that the opening and closing timing of the auxiliary contact circuit are set differently, so that the operation gap can be formed. That is, when the main contact mechanism is closed, the auxiliary contact circuit can be kept at the closed position as much as possible until the operation of the main contact mechanism to the closed position is completed.

Thus, there is an effect that the phenomenon that the operation of the main contact mechanism to the closed position is incompletely completed is prevented. In addition, damage that may occur in the excitation coil of the main contact mechanism is prevented, and the chattering phenomenon is prevented.

In addition, the above-described opening interval of the opening and closing operation can be further extended as the elastic member is included in the auxiliary sliding member.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it will be apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the invention, It is obvious that the claims fall within the scope of the claims.

1 main contact sliding member 1a auxiliary contact mechanism pressing part
2 case coil 10 case
11 Support portion 12 Sliding hole
20 auxiliary sliding member 21 insertion groove
22 Projection 23 Lower end
24 Retaining member 30 Elastic member
40 pressing member 41 engaging portion
42 latching groove 50 micro switch
51 housing 52, 53 terminal portion
54 leaf spring 55 contact button

Claims (8)

A box-shaped case;
An auxiliary sliding member installed on the case and moving up and down under pressure by the main contact sliding member;
An elastic member accommodated in an insertion groove formed in the auxiliary sliding member;
A pressing member inserted into the lower portion of the auxiliary sliding member and moving up and down by an elastic force of the elastic member; And
And a micro switch which is turned on / off by the pushing member,
The micro switch includes: a housing; A pair of terminal portions fixed to the inside of the housing and partially exposed to the outside of the housing; A leaf spring for connecting and separating the pair of terminal portions; And a contact button for applying a force to the plate spring by the pressing member,
Wherein a minimum operating load of the elastic member is formed to be smaller than a load required for closing the leaf spring, and a maximum operating load of the elastic member is formed to be larger than a load required for opening the leaf spring. Instrument.
The auxiliary contact mechanism of an electromagnetic contactor according to claim 1, wherein the elastic member is a compression spring.
The auxiliary contact mechanism of the electromagnetic contactor according to claim 1, wherein the auxiliary sliding member is formed with a latching piece protruding inwardly at a lower portion thereof, and a latching groove is formed in an upper portion of the pressing member to engage with the latching piece.
4. The auxiliary contact mechanism of the electromagnetic contactor according to claim 3, wherein an outer diameter of the pressing member is smaller than an inner diameter of the insertion groove.
delete delete delete The auxiliary contact mechanism of an electromagnetic contactor according to claim 1, wherein an interval between the opening and closing operation sections of the auxiliary sliding member is formed to be larger than an operation interval of the contact button.

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