KR200456668Y1 - Apparatus for Electron Contact - Google Patents

Abstract

The present invention has an upper frame having a fixed contact point, a crossbar coupled to the upper frame, a crossbar coupled to a movable contact point, a coil frame having a moving core and a fixed core to magnetize and move the crossbar, and coupled to the upper frame. An electronic contactor having a lower frame, the damper coupled to the fixed core and absorbing the shock generated when the mobile core is in close contact with the upper end of the fixed core by magnetization of the fixed core and the mobile core.

Magnetic contactor, moving core, damper

Description

Electronic contactor {Apparatus for Electron Contact}

The present invention relates to an electromagnetic contactor, and more particularly, to an electromagnetic contactor having a shock absorbing member for absorbing the shock generated when the mobile core is in close contact with the fixed core by magnetization of the moving core and the fixed core during current interruption.

In general, the magnetic contactor is a switch that is opened and closed by the operation of the electromagnet to perform a remote operation, is used in the circuit of the AC motor, it is used in the water level control or temperature control of the water tank.

As shown in FIG. 1, the conventional electronic contactor includes an upper frame 11, a fixed contact 17 coupled to the upper frame 11, a crossbar 13 coupled to the upper frame 11, and a crossbar. The movable contact 18 coupled to the 13, the movable core 16 positioned at the lower end of the crossbar 13, the fixed core 15 positioned at the lower end of the movable core 16, and the fixed core 16. Coil frame 14 is coupled to surround the, and the lower frame 12 is coupled to the upper frame (11).

When the power source is applied to the fixed core and the mobile core, the conventional magnetic contactor is magnetized to the fixed core, the moving coil, and the coil frame so that the fixed core and the mobile core are attached to each other. In detail, the mobile core moves to the fixed core and is in contact with it. At this time, when the magnetized moving core moves toward the fixed core, the crossbar also overcomes the force of the spring, and is moved so that the fixed contact and the moving contact come into close contact with each other, thereby conducting electricity.

However, such a conventional contactor is in close contact with the mobile core and the fixed core, the impact is generated, this shock is transmitted to the lower frame has a problem that the vibration occurs.

The present invention is designed to solve the above problems, when the fixed core and the magnetic core of the mobile core is in close contact with each other to the impact on the fixed core, the impact is transmitted to the lower frame through the fixed core The present invention relates to an electromagnetic contactor in which a damper is coupled to a lower end of a fixed core to prevent vibration generated.

The present invention has an upper frame having a fixed contact point, a crossbar coupled to the upper frame, a crossbar coupled to a movable contact point, a coil frame having a moving core and a fixed core to magnetize and move the crossbar, and coupled to the upper frame. An electronic contactor having a lower frame, comprising: a damper coupled to the fixed core, the damper absorbing an impact generated when the mobile core is in close contact with an upper end of the fixed core by magnetization of the fixed core and the mobile core. It is preferable.

Wherein the damper, the shock absorbing member for absorbing the shock delivered to the fixed core; And it is preferable to include a connecting rod for connecting each of the shock absorbing member.

The shock absorbing member is inserted into the connecting rod, it is preferable to have a groove that is formed in the English "H" shape to assist the shock absorption. In addition, the shock absorbing member is preferably formed of a rubber material for shock absorption.

The present invention absorbs the shock generated by the moving core impacting the fixed core in the damper when it is in close contact with the moving core and the fixed core due to magnetization, thereby preventing the shock from being transmitted to the lower frame and generating vibrations throughout the electromagnetic contactor. It is effective.

Hereinafter, an embodiment of an electromagnetic contactor according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a perspective view for explaining an embodiment of the electrical contact according to the invention, Figure 3 is a partially exploded perspective view of the embodiment shown in Figure 2, Figure 4 illustrates a damper of an embodiment of the electrical contact according to the invention 5 is a partial perspective view showing the embodiment shown in FIG. 4, and FIG. 6 is a front view showing the shock absorbing member of the embodiment shown in FIG. 4.

As shown in FIG. 2 or FIG. 4, the present embodiment includes an upper frame 140, a middle frame 150 coupled to a lower end of the upper frame 140, a moving core 132 magnetized when power is applied, and The fixed core 130 and the coil frame 154 coupled to wrap between the mobile core 132 and the fixed core 130 and the damper 101 coupled to the lower end of the fixed core 130 to absorb shocks. And a crossbar (not shown) that moves up and down due to the magnetization of the moving core 132, the fixed core 130, and the coil frame 154, and a moving contact (not shown) coupled to the crossbar (not shown). , A fixed contact (not shown) coupled to the upper frame 140, and a lower frame 160 coupled to the upper frame 140.

The moving core 132 is positioned at the lower end of the crossbar (not shown) coupled to the middle frame 1150 and is magnetized when power is applied.

The fixed core 130 is positioned at the lower end of the mobile core 132 and is magnetized when power is applied to move the mobile core 132 up and down.

4 to 6, the damper 101 is coupled to the lower end of the fixed core 130, the shock absorbing member 110 for absorbing the shock generated by the moving core 132 and the fixed core 130 And a connecting rod 120 connecting the respective shock absorbing members 110 to each other.

The shock absorbing member 110 is formed of a rubber material, and includes a groove 111 having an English "H" shape so as to insert the connecting rod 120 in the longitudinal direction in the center portion.

The groove 111 is inserted into the connecting rod 120, the shock absorbing member 110 is coupled to the fixed core 130 to assist the shock absorption when absorbing the shock.

In detail, the connector 120 includes an insertion part 112 into which the connector 120 is inserted, and an absorption part 114 that remains as an empty space after inserting the connector 120 into an empty space when an impact occurs. The remaining absorbed portion 114 is contracted to assist the shock absorption.

As shown in FIG. 5, the coil frame 154 is coupled to surround the fixed core 130 and increases magnetic force by mutual induction during magnetization of the fixed core 130 and the moving core 132.

The middle frame 150 includes a crossbar (not shown) that is moved up and down by the moving core 132.

The crossbar (not shown) is coupled to be inserted into the middle frame 150, and moves up and down along the middle frame 150, and includes a moving contact (not shown) for opening and closing a current.

A moving contact (not shown) is coupled to the coil frame 154 to open and close current. Since the movable contact (not shown) and the moving contact (not shown) are known in the general, detailed description thereof will be omitted.

With reference to the accompanying drawings will be described the operating relationship of the embodiment of the present invention.

2 to 4, when power is applied to the mobile core 132 and the fixed core 130, the mobile core 132 and the fixed core 130 are magnetized and pulled together. And the coil of the coil frame 154 increases the magnetic force of the fixed coil and the movable coil by the magnetic induction action.

At this time, as the mobile core 132 and the fixed core 130 are pulled together, the mobile core 132 is seated on the fixed core 130, and an impact is generated. It is transmitted to the damper 101 connected to the lower end.

The shock transmitted in this way is absorbed by the damper 101 to prevent the shock is transmitted to the lower frame (160).

The magnetized moving core 132 moves downward, and the crossbar (not shown) moves downward by the movement of the moving coil.

At this time, the movable contact coupled to the crossbar (not shown) is coupled to the upper frame 140 so that the fixed contact positioned on the vertical line with the movable contact is in close contact. The current flows through the close contact with the movable contact.

On the other hand, when the flow of current is blocked, the power is cut off to the moving core 132 and the fixed core 130, the crossbar (not shown) by the force of the spring (not shown) coupled to the upper end of the crossbar (not shown) is upwards Will be moved to.

1 is a cross-sectional view illustrating a conventional electrical contactor.

2 is a perspective view for explaining an embodiment of the electrical contact according to the present invention.

3 is a partially exploded perspective view of the embodiment shown in FIG. 2.

4 is a perspective view for explaining the damper of the embodiment of the electrical contact according to the present invention.

FIG. 5 is a partial perspective view of the embodiment shown in FIG. 4.

6 is a front view showing the shock absorbing member of the embodiment shown in FIG.

<Description of the symbols for the main parts of the drawings>

101: damper 110: shock absorbing member

111: groove 120: connecting rod

130: fixed core 132: moving core

140: upper frame 150: middle frame

160: lower frame

Claims (4)

An upper frame having a fixed contact point, a crossbar coupled to the upper frame, a crossbar coupled to a movable contact point, a coil frame having a moving core and a fixed core magnetized to move the crossbar, and a lower frame coupled to the upper frame In the electronic contactor having: And a damper coupled to the fixed core and absorbing shock generated when the mobile core is in close contact with the upper end of the fixed core by magnetization of the fixed core and the mobile core, wherein the damper is transferred to the fixed core. A shock absorbing member for absorbing shock and a connecting rod connecting each of the shock absorbing members; The shock absorbing member is formed in the "H" shaped grooves to support the absorption of the shock generated when the mobile core is in close contact with the upper end of the fixed core, the English "H" shaped grooves are the connecting rod And an insertion portion to be inserted, and an absorption portion to assist shock absorption while remaining empty after inserting the connecting rod. delete delete The method of claim 1, The shock absorbing member, the electromagnetic contactor, characterized in that formed of a rubber material for shock absorption.

Images