KR20160036980A - Bi-Stable Relay - Google Patents

Abstract

The present invention relates to a latching relay, and more particularly to a latching relay that guarantees consistency of performance by constantly maintaining an operation distance of a movable contactor. The latching relay according to an embodiment of the present invention includes: a frame; a bobbin embedded in the frame and around which a coil is wound, first and second yokes legs of which are coupled to both sides of the bobbin and which are made of magnetic materials; a rotator made of magnetic materials and rotated in a clockwise or counterclockwise direction between the head parts of the first and second yokes; a transfer lever, one end of which is coupled to one side of the rotator to be moved upwards and downwards; and a resilient member that allows a movable contactor to make contact with or be separated from a first fixed contactor while being moved by the other end of the transfer lever. A horizontal slot is formed in the transfer lever, and a shaft member slidably coupled to the horizontal slot is installed on one side of the rotator.

Description

Bi-Stable Relay < RTI ID = 0.0 >

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a latch relay, and more particularly, to a latch relay that maintains a constant operating distance of a movable contactor to achieve performance consistency.

In general, a relay or an electro-magnetic contactor is a type of an electric circuit switching device that transmits mechanical signals and current signals using the principle of an electromagnet, and is installed in various industrial facilities, machines, and vehicles

Among the relays, in particular, the latch relay has a characteristic that the switched state is maintained even when a considerable amount of energy is not supplied after the operation, and the structure is generally constructed by a permanent magnet and a solenoid actuator.

1 and 2 show a latch relay disclosed in Korean Patent No. 10-1362910. The present invention relates to a latch relay in which contact portions are firmly brought into contact with each other to enhance the stability of contact of contacts, comprising: a base (10) having a guide support wall (10w); A bobbin 21 provided at an upper portion of the base 10 and provided with a plurality of coil terminals 20t connected to the coil 21c wound around the bobbin 21 and two yokes 22, 23; < / RTI > A movable contact 30 disposed on one side of the electromagnetic driving part 20 and connected to an external device, the movable contact 30 contacting the fixed contact 40; A stationary contact (40) installed at one side of the movable contact (30) and connected to the external device and contacting the movable contact (30); An actuator 50 having an armature 50a for transmitting the magnetic force of the permanent magnet 50m so as to be pulled by the yokes 22 and 23 of the electromagnetic driving unit 20 and rotating around the rotation axis 50s; A handle 70 for horizontally moving by the rotation of the actuator 50 to move the movable contact 30 and a housing 80 for covering the upper portion of the base 10.

The actuator 70 is vertically moved in accordance with the rotation of the actuator 50 in the clockwise or counterclockwise direction about the rotary shaft 50s in accordance with the direction of the magnetic field generated in the electromagnetic actuator 20, Is brought into contact with or disconnected from the fixed contact 40, thereby energizing or interrupting the circuit.

In the present invention, the rotational force of the actuator 50 is transmitted to the handle 70 by the actuating projection 50d, and the actuating projection 50d is moved in a simple manner by fitting in the through hole 70h of the handle 70. [ Respectively. Accordingly, there is a problem in that the operating projection 50d, which performs a circular motion in the clockwise direction or the counterclockwise direction about the rotary shaft 50s, does not smoothly contact the handle 70 which is to be linearly moved. In addition, since the movement distance of the handle 70 may be changed according to the intensity of the current or the aging of the product, there is a problem that the consistency of performance in contact separation between the movable contact 30 and the fixed contact 40 may be deteriorated.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a latch relay that exhibits a constant contact performance between a fixed contact and a movable contact regardless of the motion characteristics of the rotary mover.

A latch relay according to an embodiment of the present invention includes a frame; A bobbin embedded in the frame and having a coil wound thereon; First and second yokes each of which is connected to both sides of the bobbin and formed by a magnetic body; A rotating member made of a magnetic material and rotating clockwise or counterclockwise between the head portions of the first and second yokes; A feed lever whose one end is coupled to one side of the rotary mover and which moves up and down; And an elastic member for contacting or separating the movable contactor with the first fixed contactor while moving by the other end of the transmission lever, wherein the transmission lever is provided with a horizontal slot, and at one side of the rotary mover, And a shaft member that is coupled to the shaft.

Here, the movable contactor is installed at one end to a second stationary contactor, which is installed apart from the first stationary contactor.

In addition, a lever hole is formed at a central portion of the second stationary contactor so that the lever can be operated through the transmission lever.

Further, the elastic member is constituted by a leaf spring.

In addition, a mounting portion, on which the shaft member can be installed, is protrudingly formed on one side of the rotary mover.

Further, the shaft member is formed of a pin or a rivet.

In addition, the frame may have first, second, and third support portions protruding from the frame to support the lever so that the lever is not swayed from side to side.

Further, an insertion groove into which a leaf spring can be inserted is formed at the other end of the lever.

Further, the second fixed contact is characterized in that a portion where the movable contact is engaged is bent upward.

According to the latch relay of the embodiment of the present invention, there is an effect that constant contact performance is exhibited between the fixed contact and the movable contact regardless of the motion characteristics of the rotary mover.

In addition, there is an effect that the engagement force between the rotary movement member and the transmission lever stably acts. Thus, there is an effect that the stable performance is maintained and the useful life of the product is increased.

1 is an exploded perspective view of a latch relay according to the prior art.
FIG. 2 is an exploded perspective view of the main part of FIG. 1; FIG.
3 is an internal structural view of a latch relay according to an embodiment of the present invention.
4 is an exploded perspective view of FIG.
5A and 5B are functional diagrams of latch relays in accordance with one 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 is an internal structural view of a latch relay according to one embodiment of the present invention, and Fig. 4 is an exploded perspective view of Fig. The latch relay according to each embodiment of the present invention will be described in detail with reference to the drawings.

A latch relay according to an embodiment of the present invention includes a frame 110; A bobbin 120 built in the frame 110 and having a coil 121 wound thereon; First and second yokes (130, 135), each of which is coupled to both sides of the bobbin (120) and is formed of a magnetic material; A rotary movement member 140 made of a magnetic material and rotating clockwise or counterclockwise between the head portions 132 and 137 of the first and second yokes 130 and 135; A transfer lever 150, one end of which is coupled to one side of the rotary movement member 140 and moves up and down; And an elastic member 175 for moving or separating the movable contactor 170 from the first fixed contactor 160 while being moved by the other end of the transmission lever 150. The transmission lever 150 is horizontally extended And a shaft member (149) slidably coupled to the horizontal slot (151) is formed at one side of the rotary movement member (140).

 The frame 110 is formed in a shape that can embed and support the latch mechanism. The frame 110 may be formed of an insulating synthetic resin or the like. A cover (not shown) may be coupled to the frame 110 to protect the internal components.

A first fixing part 111 for providing a space for installing the second fixed contactor 165 and the movable contactor 170 may be protruded from the upper part of the frame 110. [ The first and second seating parts 111a and 112 are formed on the frame 110 so that the first and second fixed contacts 160 and 165 can be spaced apart from each other. The first seating part 111a may be formed inside the first fixing part 111 to provide the second fixed contact 165 and the movable contactor 170 or the like. A second seating portion 112, which can be provided with a first fixed contact 160, may protrude from the upper surface of the frame 110. The lower surface 111b of the first seating portion 111a and the lower surface of the first fixing portion 111 may be inclined. This is to provide a space in which the movable contact 170 and the elastic member 175 can operate.

First, second, and third supporting portions 113, 114, and 115 may be formed inwardly of the frame 110. [ The first support portion 113 supports the second fixed contact 165 and supports the transmission lever 150, which will be described later. The second and third support portions 114 and 115 support the transmission lever 150 on the opposite side of the first support portion 113.

A second fixing portion 116 may be formed at a lower portion of the frame 110 to provide a space for installing the terminal block 180. The second fixing portion 116 is formed with an insertion groove 117 into which the terminal block 180 can be inserted.

At the center of the frame 110, there is formed an axial groove 118 in which a later-described swing motion member 140 can be rotatably installed.

A coil 121 is wound around the bobbin 120 and installed at a lower portion of the frame 110. On both sides of the bobbin 120, there are formed yoke grooves 122 through which the first and second yokes 130 and 135, which will be described later, can be inserted. On one side of the bobbin 120, a terminal pin 123 capable of supplying current to the coil 121 is provided.

The first and second yokes 130 and 135 may be formed in a substantially asymmetrical 'C' shape as a magnetic body. That is, the head portions 132 and 137 of the first and second yokes 130 and 135 may be shorter than the leg portions 131 and 136, respectively. Each of the first and second yokes 130 and 135 is symmetrically installed on each side of the bobbin 120. The legs 131 and 136 of the first and second yokes 130 and 135 are inserted into the through hole 124 formed through the central axis of the bobbin 120 and are fixedly installed in the yoke groove 122. The first and second yokes 130 and 135 have mutually opposite magnetic poles depending on the direction of the current flowing through the coil 121.

 The rotary movement member 140 is formed in an 'H' shape as a whole. The rotary motion member 140 has a box-shaped body portion 141 in which permanent magnets 142 are embedded. First and second magnetic plates 143 and 144 are coupled to the upper and lower surfaces of the permanent magnet 142, respectively. The first and second magnet plates 143 and 144 are partially exposed to the left and right sides of the body portion 141, respectively. The exposed portions of the first and second magnet plates 143 and 144 are magnetized by the permanent magnets 142 to form poles S and N, respectively. A rotary shaft 145 protrudes forward and rearward from the center of the rotary movement member 140. The rotary shaft 145 is fitted in the shaft groove 118 of the frame 110 and the rotary movement member 140 can rotate clockwise or counterclockwise around the rotary shaft 145.

A mounting portion 146 capable of mounting the shaft member 149 is formed at an upper portion of one side of the rotary movement member 140. A mounting groove 147 for fitting the shaft member 149 is formed in the mounting portion 146. Here, the shaft member 149 may be formed of a pin, a rivet, or the like.

The transfer lever 150 is formed as a generally rectangular piece. Horizontal slots 151 are formed in the lower portion of the transfer lever 150. And a shaft member 149 of the rotary movement member 140 is slidably installed in the horizontal elongated hole 151. As the shaft member 149 is sandwiched by the horizontal elongated hole 151, the force in the horizontal direction of the force transmitted from the rotary motion member 140 to the transmission lever 150 is caused to slide, and the force in the vertical direction is transmitted The lever 150 is moved in the vertical direction.

A guide hole 152 is formed at the center of the transmission lever 150 along the longitudinal direction. The guide hole 152 is fitted in a support guide formed on a part of the frame 110, though not shown, to guide the movement in the vertical direction.

On the upper portion of the transfer lever 150, a fixing groove 153 into which the movable contact 170 and the elastic member 175 can be fitted is formed. At the upper end of the transmission lever 150, a pressing protrusion 154 capable of receiving downward pressure is formed.

The first fixed contact 160 is installed on the second seating part 112 and one end of the first fixed contact 160 is exposed to the right side of the frame 110 and the first terminal part 161 is connected to the main circuit at one end. A fixed contact 162 is coupled to the other end of the first fixed contact 160. The fixed contacts 162 may be composed of a plurality of fixed contacts.

A second fixed contact 165 is provided on the first seating part 111a and one end is exposed on the right side of the frame 110 and a second terminal part 166 connected to the main circuit is provided at one end. The other end 167 of the second fixed contact 165 is bent upward. This is to provide a space in which the movable contact 170 and the elastic member 175 can act. A plurality of coupling protrusions 168 for fixing the movable contact 170 and the elastic member 175 are formed at the other end of the second fixed contact 165. A lever hole 169 is formed at the center of the second fixed contact 165 to allow the transmission lever 150 to penetrate.

The movable contactor 170 may be formed as a flat plate. The movable contactor 170 may be constructed by stacking a plurality of plates. The movable contact 170 can be coupled with the movable contact 172 which can be contacted with or separated from the fixed contact 162. [ The movable contacts 172 may be composed of a plurality of movable contacts.

The elastic member 175 may be a flat plate having a stepped surface. The elastic member 175 may be formed of a leaf spring.

The movable contact 170 and the elastic member 175 may be formed with engaging grooves 171 and 176 that can be fitted to the engaging projections 168 of the second fixed contacts 165, respectively.

5A and 5B, the operation of the latch relay according to an embodiment of the present invention will be described.

The first yoke 130 is magnetized to the S pole as shown in FIG. 5A when a current flows through the coil 121 in one direction (or switched on) by an external power source connected to the terminal block 180, (It is a well-known fact that such polarity may be reversely formed depending on the direction of the current or the characteristics of the coil.) Accordingly, when the first magnet plate 143 is N And the rotary motion member 140 having the S pole of the second magnet plate 144 rotates in the counterclockwise direction around the rotation shaft 145. [ Therefore, the shaft member 149 also rotates in the counterclockwise direction around the rotation shaft 145. The horizontal movement force is converted into a slipping motion in the horizontal slot 151 of the transmission lever 150 and the vertical movement force moves the transmission lever 150 upward. The elastic member 175 pushes up the movable contact 170 and the movable contact 172 to come into contact with the fixed contact 162. As a result, Accordingly, in the main circuit, the first terminal portion 161 and the second terminal portion 162 are connected to each other and energization occurs.

On the contrary, when a current flows in the opposite direction to the coil 121 (or switch off) by an external power source connected to the terminal block 180, the first yoke 130 is magnetized to the N pole as shown in FIG. 5B , And the second yoke 135 is magnetized to the S-pole. Thus, the rotary movement member 140 rotates in the clockwise direction around the rotation shaft 145. Therefore, the shaft member 149 also rotates in the clockwise direction about the rotation shaft 145. [ The horizontal movement force is converted into a slipping motion in the horizontal slot 151 of the transmission lever 150 and the vertical movement force moves the transmission lever 150 downward. The movable contact 172 and the movable contact 172 are separated from the fixed contact 162 as the transfer lever 150 is lowered. Thus, the main circuit is disconnected by breaking the connection between the first terminal portion 161 and the second terminal portion 162.

According to the latch relay of the embodiment of the present invention, the horizontal movement force of the rotary mover is consumed as a slip motion, and only the vertical movement force is transmitted to the movable contactor through the transmission lever so that the movable contactor always maintains a constant vertical movement range The blocking performance is maintained constant.

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 scope of the present invention. It is obvious that the claims fall within the scope of the claims.

110 frame 111 first fixing portion
111a first seat portion 112 second seat portion
113, 114, 115 First, second, and third supporting portions 116 Second fixing portion
117 insertion groove 118 axial groove
120 bobbin 121 coils
122 yoke groove 123 terminal pin
124 through holes 130, 135, first and second yokes
131, 136 legs 132, 137 head
140 rotating traveler 141 body part
142 permanent magnets 143, 144 first and second magnet plates
145 Rotating shaft 146 Mounting part
147 mounting groove 149 shaft member
150 Transmission Lever 151 Horizontal Slot
152 Guide hole 153 Fixing groove
154 pressing projection 160 first fixed contact
161 first terminal portion 162 fixed contact
165 second fixed contact 166 second terminal portion
167 other end portion 168 engaging projection
169 lever hole 170 movable contact
175 Elastic member 180 Terminal block

Claims (9)

frame;
A bobbin embedded in the frame and having a coil wound thereon;
First and second yokes each of which is connected to both sides of the bobbin and formed by a magnetic body;
A rotating member made of a magnetic material and rotating clockwise or counterclockwise between the head portions of the first and second yokes;
A feed lever whose one end is coupled to one side of the rotary mover and which moves up and down; And
And an elastic member moving or contacting the movable contact with the first stationary contactor by the other end of the transmission lever,
Wherein a horizontal slot is formed in the transmission lever and a shaft member is slidably coupled to the horizontal slot on one side of the rotary mover. The latch relay according to claim 1, wherein the movable contact is installed at one end to a second stationary contactor which is installed apart from the first stationary contactor. 3. The latch relay according to claim 2, wherein a lever hole is formed at a central portion of the second fixed contact, the lever hole being operable through the transmission lever. The latch relay according to claim 1, wherein the elastic member is formed of a leaf spring. The latch relay according to claim 1, wherein a mounting portion capable of mounting the shaft member is formed on one side of the rotary mover. The latch relay according to claim 1, wherein the shaft member comprises a pin or a rivet. The latch relay according to claim 1, wherein the frame is provided with first, second, and third support portions protruding from the frame so as to support the lever so that the lever is not swayed from side to side. The latch relay according to claim 1, wherein an insertion groove into which a leaf spring is inserted is formed at the other end of the lever. 2. The latch relay according to claim 1, wherein the second fixed contact is bent upward at a portion where the movable contact is engaged.

Images