KR20180085586A - Direct Current Relay - Google Patents

Abstract

The present invention relates to a direct current (DC) relay, and more specifically, to a DC relay which allows sliding between a stationary contact and a movable contact by a certain distance during supply, thereby preventing a contact failure and improving current supply performance. According to one embodiment of the present invention, a DC relay comprises: a pair of fixed contacts fixedly installed on a portion of an arc chamber; a movable contact disposed below the pair of fixed contacts to be able to linearly move and capable of being in contact with or separated from the pair of fixed contacts; a coil fixedly installed on a lower portion of the movable contact; a yoke installed around the coil to form a magnetic path by a magnetic field generated when current flows through the coil; a movable core installed at a central portion of the coil and moving vertically; a shaft installed on an upper portion of the movable core; and a contact spring installed between the shaft and the movable contact to provide contact pressure to the movable contact, wherein the fixed contacts have contact surfaces formed to be convex and the movable contact has a contact surface formed as an inclined surface.

Description

Direct Current Relay

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a DC relay, and more particularly, to a DC relay in which a sliding contact is generated between a stationary contact and a movable contact at the time of closing, thereby preventing contact failure and improving current carrying performance.

In general, direct current relay or magnetic switch is a kind of electric circuit switching device which transmits mechanical signal and current signal by using the principle of electromagnet. It is installed in various industrial equipments, machines and vehicles do.

Particularly, an electric vehicle is provided with an electric vehicle relay for supplying and disconnecting electric power of a battery to a power generating device and a front end portion. Such an electric vehicle relay is very useful for electric vehicles It is one of the important core parts.

1 and 2 are longitudinal sectional views of an electromagnetic switch according to the prior art. Fig. 1 shows an open state (cut-off state), and Fig. 2 shows a put-in state (energized state).

1, the conventional electromagnetic switch includes an upper frame 1 and a lower frame 2, an arc chamber 1a, a fixed contact 3 and a movable contact 4, and an actuator 5 .

The upper frame 1 and the lower frame 2 are coupled to each other to form a box, and an inner space is formed. Inside the upper frame 1, an arc chamber 1a is provided. The stationary contact 3 is fixed to the arc chamber 1a and the movable contact 4 is provided to be contactable or detachable with respect to the stationary contact 3 and an actuator 5 is installed inside the lower frame 2 .

The actuator 5 includes a coil 5a, yokes 5c and 5d, a movable core 5e, and a shaft 7. The coil 5a is wound around a cylindrical bobbin 5b having a plurality of flanges and the movable core 5e and the shaft 7 are inserted into the through hole formed at the center of the bobbin 5b. Here, the shaft 7 is assembled in such a manner that it is mounted on the upper portion of the movable core 5e.

The yokes 5c and 5d are provided to surround the bobbin 5b and the coil 5a and form a magnetic path when a current flows through the coil 5a.

A return spring 8 is provided at the upper end of the shaft 7, and a contact spring 9 is provided at the intermediate portion. The contact spring 6 provides a contact pressure so that the movable contact 4 elastically contacts the fixed contact 3.

DC relay has high voltage and low voltage. The high voltage HV is used for energizing or opening the main circuit through a wire or a bus bar connected to the fixed contact 3 and the low voltage LV is connected to a driving unit to turn the electromagnetic switch on and off.

Referring to FIGS. 1 and 2, the operation of the electromagnetic switch according to the related art will be described as follows.

When a low voltage is applied to the coil 5a in the open state as shown in FIG. 1, the yokes 5c and 5d and the movable core 5e are circulated by the magnetic field generated around the coil 5a, . The movable core 5e is advanced upward along the magnetic path and the shaft 7 placed on the upper portion of the movable core 5e is pushed up by the movable core 5e. As a result, the contact spring 6 pushes the movable contact 4 and contacts the fixed contact 3, so that the main circuit is in the energized state (On state, High voltage) (see Fig. 2).

At this time, the movable core 5e is moved further than the gap between the movable contact 4 and the fixed contact 3 (normally, such excess travel distance is referred to as Over Travel) so that the contact spring 9 contacts the movable contact 4 The contact pressure is applied. This contact pressure maintains the energized state and improves the energizing performance.

2, when the power source applied to the coil 5a is cut off, the magnetic field generated around the coil 5a disappears and the movable core 5e and the shaft 7 mounted thereon are returned to the return spring 8 The movable contact 4 is disconnected from the fixed contact 3 and the main circuit is in the open state (see FIG. 1).

However, in the DC relay according to the related art (particularly in the case of the low-current DC relay), both the stationary contact point 3 and the movable contact point 4 are made of plain tips. Since the energizing area is enlarged by using the contact point at the contact point, it is considered that the energizing performance is advantageous at a glance, but in actuality, the performance variation according to the state of the contact surface is very large. That is, when there is a foreign substance on the surface of the contact point, a case where the energization fails is likely to occur.

In order to ensure stable performance, it is recommended to drive the DC relay in the state where the load is connected to the main circuit. However, there is a case where it is not observed in actual use, and the DC relay operates in no-load state, May not be achieved. Particularly, if there is a minute foreign substance on the contact point, it has a great influence on the current carrying performance, and it can be connected to the conduction failure and the starting failure. It has been confirmed that foreign substances having a size of 0.2 mm or more may have such an influence.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and its object is to provide a DC relay which prevents sliding contact between a stationary contact and a movable contact at the time of closing, thereby preventing contact failure and improving current carrying performance.

A DC relay according to an embodiment of the present invention includes a pair of fixed contacts fixedly installed in a part of an arc chamber; A movable contact which is installed to be linearly movable below the pair of fixed contacts and can be brought into contact with or separated from the pair of fixed contacts; A coil fixed to a lower portion of the movable contact; A yoke provided around the coil to form a magnetic path by a magnetic field generated when a current flows through the coil; A movable core installed at a central portion of the coil and moving up and down; A shaft installed on an upper portion of the movable core; And a contact spring provided between the shaft and the movable contact to provide a contact pressure to the movable contact, wherein the fixed contact has a contact surface formed to be convex, and the contact surface of the movable contact has an inclined surface .

Here, the contact surface of the stationary contact is formed as a spherical surface.

Further, the movable contact is constituted by a movable plate and a pair of contact portions.

The contact portion may include a contact contacting portion contacting the fixed contact and a contact connecting portion coupled to the movable plate.

Further, the contact contact portion is characterized by being formed in a rectangular shape or a square shape.

The movable plate may be provided with a rotation support portion formed in a groove or a hole in a central portion thereof, and a protrusion that can be fitted to the rotation support portion is formed in a part of the shaft.

The contact point contact portion is inclined toward the front surface or the rear surface.

According to the DC relay of the embodiment of the present invention, the contact surface of the stationary contact is formed as a curved surface, and the contact surface of the movable contact is formed as an inclined surface. As a result, slippage (sliding) occurs between the stationary contact and the movable contact at the time of closing, thereby preventing the defective contact due to foreign matter and improving the electrification performance.

Further, due to the above-described shape of the fixed contact and the movable contact, the overtravel distance increases and the contact pressure increases. That is, the electrification performance is improved.

1 and 2 are longitudinal cross-sectional views of a conventional DC relay. 1 is an open state, and Fig. 2 is an energized state.
3 and 4 are longitudinal cross-sectional views of a DC relay according to an embodiment of the present invention. Fig. 3 is an open state, and Fig. 4 is an energized state.
5 is a side cross-sectional view of a contact portion of a DC relay according to an embodiment of the present invention shown in FIG.
6 and 7 are perspective views of a fixed contact and a movable contact applied to a DC relay according to an embodiment of the present invention.
Fig. 8 and Fig. 9 are operational diagrams of a DC relay according to an embodiment of the present invention, wherein Fig. 8 shows a contact initial state and Fig. 9 shows a contact complete state (energized state). Only the contact portion is shown and the sectional view is a side view.
10 is an exploded view of the contact pressure at contact in FIG.
11 is a perspective view of a movable contact applied to a DC relay 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.

3 and 4 are longitudinal cross-sectional views of a DC relay according to an embodiment of the present invention. Fig. 3 is an open state, and Fig. 4 is an energized state. 5 is a side cross-sectional view of a contact portion of a DC relay according to an embodiment of the present invention shown in FIG. 6 and 7 are perspective views of a fixed contact and a movable contact applied to a DC relay according to an embodiment of the present invention. The DC relay according to each embodiment of the present invention will be described in detail with reference to the drawings.

A DC relay according to an embodiment of the present invention includes a pair of fixed contacts 20 fixedly installed on a part of an arc chamber; A movable contact (30) installed on the lower side of the pair of fixed contacts (20) so as to be linearly movable and capable of being contacted with or separated from the pair of fixed contacts (20); A coil 17 fixed to the lower portion of the movable contact 30; A yoke 18 provided around the coil 17 to form a magnetic path by a magnetic field generated when a current flows through the coil 17; A movable core 40 installed at a central portion of the coil 17 and moving up and down; A shaft 45 installed on the upper portion of the movable core 40; And a contact spring (28) provided between the shaft (45) and the movable contact (30) to provide contact pressure to the movable contact (30), wherein the fixed contact (20) And the contact surface of the movable contact 30 is formed as an inclined surface.

The DC relay according to the present embodiment may include the frames 10 and 11 and the arc chamber 12, the stationary contact 20 and the movable contact 30, the actuator 15 and the contact spring 50. The DC relay according to the present embodiment can be applied particularly to electric vehicles.

The frame 10 may include an upper frame 10a and a lower frame 10b. The upper frame 10a and the lower frame 10b are formed in a box-like shape in which faces facing each other are opened, and the inner spaces are coupled to each other to provide one accommodation space.

An arc chamber 12 is provided in the upper frame 10a. A fixed contact 20 is fixed to the inside of the arc chamber 12 and a movable contact 30 is installed to be contactable with or detachable from the stationary contact 20. The movable contact 30 may be composed of a movable plate 35 and a movable part 31. The contact part will be described again.

An actuator 15 is installed in the lower frame 10b. The actuator 15 includes coil assemblies 16 and 17 and a yoke 18 and a movable core 40 that are installed to surround the coil assemblies 16 and 17. The coil assembly includes a bobbin (16) and a coil (17) wound on the bobbin (16).

A central hole penetrating vertically is formed in a central portion of the bobbin 16. A movable core (40) and a shaft (45) are vertically movable in the center hole.

The yoke 18 is installed so as to surround the bobbin 16 and the coil assemblies 16 and 17, and forms a magnetic path when a current flows through the coil 17.

A movable core 40 and a shaft 45 are inserted into a center hole of the bobbin 16. Here, the shaft 45 is assembled in such a manner that it is mounted on the upper portion of the movable core 40. The shaft 45 is provided with a first bearing portion 46 and a second bearing portion 47.

A contact spring 50 is provided between the movable contact 30 and the first pedestal 46 so as to provide a contact pressure such that the movable contact 30 elastically contacts the fixed contact 20 when the movable contact 30 is inserted.

A return spring 55 for returning the movable core 40 downward is inserted between the upper end of the arc chamber 12 and the second receiving portion 47 of the shaft 45.

The shaft 45 is provided so as to be movable up and down in a through hole formed at the center of the yoke 18. [ The lower end of the shaft 45 may be mounted on the movable core 40 in a state in which it is mounted on the movable core 40. A contact spring 50 is provided on the first bearing portion 46 of the shaft 45 so as to push the movable contact 30 upward during the closing operation. A return spring 55 is provided on the second bearing portion 47 of the shaft 45 to return the shaft 45 and the movable core 40 to the downward direction when the shaft 45 is interrupted.

The stationary contact 20 may have a predetermined thickness and may include a stationary contact portion 21 to be brought into contact with the movable contact 30 and a stationary engagement portion 22 to be coupled to the arc chamber 12. The fixed joint portion 22 may be formed in a 'T' shape in cross section. A power supply terminal or a load terminal is coupled to the fixed connection portion 22 and is connected to the main circuit. A high voltage is applied to the fixed engagement portion 22.

The fixed contact surface 21a of the fixed contact portion 21 is formed as a curved surface. Here, the curved surface may be formed as a spherical surface having a predetermined radius. At this time, it is preferable that the radius is formed to be considerably larger than the width (diameter) of the fixed contact portion 21.

Alternatively, the fixed contact surface 21a may have a curvature radius different from that of the central portion and the outer portion. For example, the radius of curvature of the central portion may be smaller than the radius of curvature of the outer portion. That is, the central portion can be formed more gently than the outer portion.

The movable contact 30 may be composed of the movable plate 35 and the pair of contact portions 31 as described above. The contact portion 31 may have a contact contact portion 32 having a predetermined thickness and brought into contact with the fixed contact 20 and a contact coupling portion 33 coupled to the movable plate 35. The contact connecting portion 33 may have a T-shaped cross section.

The contact contact portion 32 may be formed in a rectangular shape or a square shape in plan view. The movable contact surfaces 32a and 32b of the contact contact portion 32 are formed as inclined surfaces when viewed from the side. That is, the movable contact surfaces 32a and 32b are formed to have a predetermined inclination angle A on the side surface. In order to make the movable contact surfaces 32a and 32b have an inclination angle, at least one of the contact contacting portions 32 and the contact connecting portions 33 may be formed to have an inclination angle. Preferably, the contact connecting portion 33 formed of a relatively hard material may be formed to have an inclination angle. Here, when the inclination angle is excessively large, the contact of the contact portion during slipping may slip and be displaced. Therefore, it is preferable that the inclination angle is formed at a gentle angle to the extent that it can be prevented. For example, the inclination angle A can be set within a range between 0 and 30 degrees.

The movable plate 35 is provided with a plurality of leg portions 36 to prevent the rotation of the movable plate 35 in a clockwise or counterclockwise direction about an axis perpendicular to the end face . The leg portion 36 is extended to reach the shaft 45 to prevent the rotation phenomenon.

The operation of the DC relay according to an embodiment of the present invention will be described with reference to FIGS. 5 and 8 to 10. FIG. Fig. 8 shows an initial state in which the movable contact 30 is in contact with the fixed contact 20, and Fig. 9 shows a state in which the contact between the movable contact 30 and the fixed contact 20 is completed, that is, the energized state. Fig. 10 is an exploded view of the contact pressure at contact in FIG.

When a low-voltage control current flows through the coil 17 in the open state as shown in FIG. 5, a magnetic field is generated and a magnetic path is formed through which the yoke 18 circulates. At this time, the magnetic path is a direction in which the yoke 18 ascends on the inner side portion of the yoke 18, and the outer side portion of the yoke 18 is in the downward direction. The movable core 40 disposed at the center of the yoke 18 moves upward along the magnetic path and the shaft 45 is pushed up by the movable core 40. [ As a result, the movable contact 30 provided at the upper end of the shaft 45 rises and comes into contact with the fixed contact 20 as shown in Fig.

At this time, the portion initially contacting is assumed to be the point p of the fixed contact 20 and the point a of the movable contact 30. The p-point and the a-point are located on the left side from the center portion (the center of the contact portion, point b) in the drawing. The distance from the center portion to the p point or the point a is set by the shape of the curved surface of the fixed contact 20 (the size of the radius in the case of having the same radius) and the inclination angle of the movable contact 30.

FIG. 10 shows an exploded view of the contact pressure at the time of contact at the contact. The contact pressure F by the movable contact 30 at the contact point a is divided into a force F1 that slides along the inclined surface and a force F2 that raises the fixed contact. That is, the movable contact 30 is slipped to the left by the force F1, and the fixed contact 20 is raised by the force of F2.

When the elevation is completed, the movable contact 30 slides to the left, so that the point c is in contact with the point p of the stationary contact 20 as shown in Fig. At this time, the over travel distance increases by the length of the height difference h between the point b which is the center point of the movable contact 30 and the point c which is the contact point. Therefore, the contact pressure to the contact portion rises and contributes to the improvement of the electrification performance.

Another embodiment will be described with reference to FIG.

The movable plate (35) is provided with a rotation support portion (37) formed at the center thereof with a spherical groove or hole. The rotation support portion 37 is fitted in a protrusion (not shown) formed at the lower portion of the second support portion 47 of the shaft 45 and supports the movable contact 30 so as to be rotatable in the lateral direction. That is, it is rotatable about the axis of the shaft 45. Accordingly, the movable contact 30 can be rotated at a predetermined angle around the rotation supporting portion 37 when the contact portion 31 slips.

On the other hand, the movable plate 35 may be provided with the contact portions 31 symmetrically. In view of the side, the pair of contact portions 31 are provided so as to have an inclination opposite to each other. That is, one of the movable contact surfaces 31a is inclined toward the front (or rear), and the other movable contact surface 31b is inclined toward the rear (or front). Accordingly, when the sliding contact of the contact portion 31 occurs, the movable plate 35 can be rotated by a predetermined angle.

According to the DC relay of the embodiment of the present invention, the contact surface of the stationary contact is formed as a curved surface, and the contact surface of the movable contact is formed as an inclined surface. As a result, slippage (sliding) occurs between the stationary contact and the movable contact at the time of closing, thereby preventing the defective contact due to foreign matter and improving the electrification performance.

Further, due to the above-described shape of the fixed contact and the movable contact, the overtravel distance increases and the contact pressure increases. That is, the electrification performance is improved.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the scope of the present invention but to limit the scope of the technical idea of the present invention. That is, the scope of protection of the present invention should be construed according to the following claims, and all technical ideas which are within the scope of the same should be interpreted as being included in the scope of the present invention.

10 frames 12 arc chambers
15 actuator 16 bobbin
17 Coil 18 York
20 Fixed contact 21 Fixed contact
21a fixed contact surface 22 fixed joint portion
30 Movable contact 31 Contact part
32 contact points 32a and 32b,
33 contact connecting portion 35 movable plate
40 movable core 45 shaft
46 first receiving portion 47 second receiving portion
50 contact spring 55 return spring

Claims (7)

A pair of fixed contacts fixedly installed on a part of the arc chamber;
A movable contact which is installed to be linearly movable below the pair of fixed contacts and can be brought into contact with or separated from the pair of fixed contacts;
A coil fixed to a lower portion of the movable contact;
A yoke provided around the coil to form a magnetic path by a magnetic field generated when a current flows through the coil;
A movable core installed at a central portion of the coil and moving up and down;
A shaft installed on an upper portion of the movable core;
And a contact spring provided between the shaft and the movable contact to provide a contact pressure to the movable contact,
Wherein the fixed contact has a contact surface formed to be convex, and the contact surface of the movable contact is formed as an inclined surface. The direct current relay according to claim 1, wherein the contact surface of the stationary contact is formed as a spherical surface. The direct current relay according to claim 1, wherein the movable contact comprises a movable plate and a pair of contact portions. The direct current relay according to claim 3, wherein the contact portion comprises a contact contact portion contacting the stationary contact and a contact connecting portion coupled to the movable plate. The direct current relay according to claim 4, wherein the contact contact portion is formed in a rectangular shape or a square shape. [4] The DC relay of claim 3, wherein the movable plate is provided with a rotation support portion formed in a groove or a hole at a central portion thereof, and a protrusion that can be fitted to the rotation support portion is formed in a part of the shaft. 5. The DC relay according to claim 4, wherein the contact portion is inclined toward the front surface or the rear surface.

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