KR102388586B1 - Direct Current Relay - Google Patents

Abstract

The present invention relates to a DC relay, and more particularly, to a DC relay having a mover assembly with improved contact pressure.
A DC relay according to an embodiment of the present invention is a DC relay comprising a pair of fixed contactors and a movable contactor that is moved up and down by electromagnetic force to contact or separate the pair of fixed contactors, wherein an upper portion of the movable contactor is provided. and an upper yoke and a lower yoke respectively provided at the lower portion; a mover support for supporting the movable contactor, the upper yoke and the lower yoke; a mover holder fixed to the upper part of the mover support; a contact pressure spring provided between the lower yoke and the mover support; and a shaft coupled to the mover support to transmit the power of the actuator, wherein the contact spring presses the lower yoke to move the movable contact, and the shaft has an upper end coupled to the upper mover support characterized.

Description

Direct Current Relay

The present invention relates to a DC relay, and more particularly, to a DC relay having a mover assembly with improved contact pressure.

In general, a direct current relay or magnetic switch is a kind of electrical circuit switch that uses the principle of an electromagnet to mechanically drive and transmit current signals, and is installed in various industrial facilities, machines, and vehicles. do.

In particular, electric vehicles, such as hybrid vehicles, fuel cell vehicles, golf carts, and electric forklifts, are equipped with an Electric Vehicle Relay for supplying and shutting off the power of the battery to the power generator and electric parts. The relay for electric vehicle is one of the very important core parts in electric vehicle.

1 shows an internal structural diagram of a DC relay according to the prior art.

The DC relay includes a case (1,2) composed of an upper frame (1) and a lower frame (2), a middle plate (9) provided inside the case, and a contact part ( 3 and 4), the arc extinguishing unit 8, and an actuator 7 installed under the middle plate 9. Here, the actuator 7 may be a device operated by the principle of an electromagnet.

The fixed contacts 3 of the contact parts 3 and 4 are exposed on the upper surface of the upper frame 1 to be connected to a load or a power source.

Contact parts 3 and 4 and arc extinguishing parts 8 are provided inside the upper frame 1 . The contact parts 3 and 4 are composed of a fixed contact 3 fixedly installed on the upper frame 1 and a movable contact 4 operated by an actuator 7 to contact or separate the fixed contact 3 do. The arc extinguishing unit 8 is usually formed of a ceramic material. The arc extinguishing unit 8 is also referred to as an arc chamber. The inside of the arc extinguishing unit 8 may be filled with an extinguishing gas for arc extinguishing.

A permanent magnet (not shown) may be provided in order to effectively control the arc generated when the contact parts 3 and 4 are blocked (when separated). The permanent magnet is installed around the contact part to generate a magnetic field to control the arc, which is a rapid flow of electricity, and a permanent magnet holder 6 is provided to fix the permanent magnet.

The actuator operates using the principle of an electromagnet and includes a fixed core 7a, a movable core 7b, a movable shaft 7c, and a return spring 7d. A cylinder 7e surrounds the stationary core 7a and the movable core 7b. The cylinder 7e and the arc extinguishing unit 8 form an enclosed space.

A coil 7f is provided around the cylinder 7e to generate electromagnetic force around it when control power is applied. The fixed core 7a is magnetized by the electromagnetic force generated by the coil 7f, and the movable core 7b is attracted by the magnetic force of the fixed core 7a. Accordingly, the movable shaft 7c coupled to the movable core 7b and the movable contactor 4 coupled to the upper portion of the movable shaft 7c move together and come into contact with the stationary contactor 3, so that the circuit is energized. The return spring 7d provides an elastic force that allows the movable core 7b to return to its initial position when the control power of the coil is cut off.

However, in the DC relay according to the prior art, an electromagnetic repulsive force is generated between the fixed contactor and the movable contactor, and accordingly, there is a tendency to separate from each other. In order to prevent unintentional separation by this electromagnetic repulsive force, the movable contactor 4 receives a contact pressure through the contact pressure spring 5 . That is, the distance between the fixed core 7a and the movable core 7b is set longer than the distance between the fixed contactor 3 and the movable contactor 4, so that the movable contactor exerts a contact pressure due to overtravel of the movable core. receive However, if the electromagnetic repulsive force is stronger than the contact force, there is still a risk of the contact portion being separated.

The present invention has been devised to solve the above-mentioned problems, and an object of the present invention is to provide an electromagnetic contactor provided with a mover assembly in which the contact force is improved.

A DC relay according to an embodiment of the present invention is a DC relay comprising a pair of fixed contactors and a movable contactor that is moved up and down by electromagnetic force to contact or separate the pair of fixed contactors, wherein an upper portion of the movable contactor is provided. and an upper yoke and a lower yoke respectively provided at the lower portion; a mover support for supporting the movable contactor, the upper yoke and the lower yoke; a mover holder fixed to the upper part of the mover support; a contact pressure spring provided between the lower yoke and the mover support; and a shaft coupled to the mover support to transmit the power of the actuator, wherein the contact spring presses the lower yoke to move the movable contact, and the shaft has an upper end coupled to the upper mover support characterized.

Here, the mover support is characterized in that it is composed of a first flat plate portion and an arm portion which is formed to protrude upward from both ends of the first flat plate portion and to which the mover holder is fixed.

In addition, the first flat plate is characterized in that the spring support portion for supporting the lower end of the contact pressure spring is formed to protrude from the upper portion.

In addition, the lower surface of the mover support is characterized in that the insertion portion inserted into the center hole of the middle plate is formed to protrude.

In addition, the mover holder is characterized in that it has a second flat plate portion and side portions bent downward, respectively, at both ends of the second flat portion.

In addition, the mover holder is characterized in that the left and right side skirt portions into which the upper yoke can be inserted are formed.

In addition, the lower yoke is characterized in that it is composed of a third flat plate portion and a wing portion bent upwardly formed at both ends of the third flat portion.

In addition, the front and rear ends of the upper yoke is characterized in that each of the coupling grooves to which the wing can be coupled are formed.

In addition, the front and rear side surfaces of the movable contactor are characterized in that support grooves into which the wing parts are inserted are formed.

In addition, it is characterized in that a support protrusion to which the upper end of the contact pressure spring can be fixed is formed on the lower surface of the lower yoke.

In addition, the upper yoke is characterized in that it is disposed above or below the mover holder.

And, in the case where the upper yoke is disposed under the mover holder, fixing protrusions are formed to protrude from each corner of the lower yoke, pass through connection grooves formed at each corner of the mover holder, and the upper yoke It is characterized in that it is fitted into the coupling groove formed in each corner of the.

In addition, in the case where the upper yoke is disposed on the upper part of the mover holder,

A through hole through which a support formed on a lower surface of the upper yoke is inserted is formed in the upper surface of the mover holder.

A DC relay according to another aspect of the present invention includes a pair of fixed contacts; and a mover assembly that moves up and down by an actuator to contact or separate the pair of fixed contacts to energize or cut off a circuit, wherein the mover assembly includes: a mover support connected to the actuator by a shaft; a mover holder fixed to the upper part of the mover support; a movable contact installed between the mover holder and the mover support; an upper yoke and a lower yoke respectively provided on the upper and lower portions of the movable contactor to generate electromagnetic force; and a contact pressure spring provided between the lower yoke and the mover support to press the lower yoke, wherein the mover assembly includes the upper yoke, the mover holder, the movable contactor, the lower yoke, and the contact pressure from the upper side to the lower side. The spring and the mover support are arranged in this order, or the mover holder, the upper yoke, the movable contactor, the lower yoke, the contact spring, and the mover support are arranged in this order, and the shaft is characterized in that the upper end is coupled to the movable mover support. do it with

According to the direct current relay according to each embodiment of the invention, the movable contact is provided with an upper yoke and a lower yoke to cancel the electromagnetic repulsive force, so that unintentional separation of the contact portion does not occur.

1 is an internal structural diagram of a DC relay according to the prior art.
2 is an internal structural diagram of a DC relay according to an embodiment of the present invention.
Fig. 3 is a side view of the mover assembly in Fig. 2;
FIG. 4 is an exploded perspective view of the mover assembly of FIG. 3 ;
5 is a perspective view of a mover holder applied to a DC relay according to another embodiment of the present invention.
6 and 7 are a side view and an exploded perspective view of a mover assembly applied to a DC relay according to another embodiment of the present invention.

A preferred embodiment of the present invention will be described with reference to the accompanying drawings, which is intended to be described in detail enough to enable a person of ordinary skill in the art to easily practice the invention, thereby It does not mean that the technical idea and scope are limited.

FIG. 2 is an internal structural diagram of a DC relay according to an embodiment of the present invention, FIG. 3 is a side view of the mover assembly of FIG. 2 , and FIG. 4 is an exploded perspective view of the mover assembly of FIG. 3 . A DC relay according to each embodiment of the present invention will be described in detail with reference to the drawings.

A direct current relay according to an embodiment of the present invention includes a pair of fixed contactors 114 and a movable contactor 150 that is in contact with or separated from the pair of fixed contactors 114 by moving up and down by electromagnetic force. A relay comprising: an upper yoke (131) and a lower yoke (135) respectively provided on the upper and lower portions of the movable contactor (150); and a contact pressure spring (155) provided under the lower yoke (135), wherein the contact pressure spring (155) presses the lower yoke (135) to move the movable contactor (150). do.

The frames 111 and 112 are formed in a box-shaped case capable of housing and protecting and supporting the components. The frames 111 and 112 may include an upper frame 111 and a lower frame 112 .

The arc chamber ( 113 ) is formed in a box shape with an open lower surface, and is installed inside the upper frame ( 111 ). The arc chamber 113 is made of a material having excellent insulation, pressure resistance, and heat resistance so as to extinguish the arc generated at the contact portions 114 and 150 when cut off. For example, the arc chamber 113 may be made of a ceramic material. The arc chamber 113 is fixedly installed on the upper portion of the middle plate 170 .

A fixed contact (fixed contact, 114) is provided as a pair and is fixedly installed in the arc chamber (113). The fixed contact 114 is exposed to the upper frame 111 . One of the fixed contacts 114 may be connected to the power supply side, and the other one may be connected to the load side.

A moving contact (moving contact, 150) is formed in a plate-shaped body of a predetermined length is installed under the pair of fixed contacts (114). The movable contact 150 is installed in the movable assembly 130 and moves integrally. The movable contactor 150 is linearly movable up and down by the actuator 160 installed inside the lower frame 112 , and is contacted or separated from the fixed contactor 114 to connect or block the circuit.

A permanent magnet (not shown) is provided in order to effectively control the arc generated when the contact parts 114 and 150 are blocked (disconnected). Permanent magnets are installed around the contact parts 114 and 150 to generate a magnetic field to control the arc, which is a rapid flow of electricity. A permanent magnet holder 115 is provided to fix the permanent magnet.

An actuator 160 is provided to move the mover assembly 130 , that is, the movable contact 150 . The actuator 160 is a yoke 161 formed in a 'U' shape to form a magnetic circuit, and a coil wound around a bobbin 162 installed inside the yoke 161 and receiving external power to generate a magnetic field. 163, a fixed core 165 that is fixedly installed inside the coil 163 and is magnetized by a magnetic field generated by the coil 163 to generate a magnetic attraction force, and linear motion at the lower portion of the fixed core 165 A movable core 167 that is installed so as to be in contact with or separated from the fixed core 165 by the magnetic attraction force of the fixed core 165, the lower end is coupled to the movable core 167, and the upper end is slidable on the movable contactor 150 A shaft 157 that is inserted through the shaft 157 and a return spring 169 installed between the fixed core 165 and the movable core 167 to return the movable core 167 downward, the fixed core 165, and the movable core 167 and a cylinder 168 to receive a return spring 169 .

A middle plate 170 is provided between the actuator 160 and the arc chamber 113 . The middle plate 170 is installed on the yoke 161 and formed of a magnetic material to form a magnetic path together with the yoke 161 . The middle plate 170 also serves as a support plate on which the upper arc chamber 113 and the lower actuator 160 can be installed, respectively. A cylinder 168 is sealingly coupled to a lower portion of the middle plate 170 .

A sealing member 172 may be provided between the middle plate 170 and the arc chamber 113 . That is, a sealing member 172 is provided along the lower periphery of the arc chamber 113 to seal the space formed by the arc chamber 113 , the middle plate 170 (a hole in the center of the middle plate) and the cylinder 168 . make it possible

The mover assembly 130 includes a shaft 157 , a mover support 140 and a mover holder 145 , a movable contact 150 , a contact pressure spring 155 , an upper yoke 131 and a lower yoke 135 . include

The shaft 157 is composed of a straight rod or rod. The lower end of the shaft 157 is fixedly installed on the movable core 167 . Accordingly, the shaft 157 moves up and down together with the movement of the movable core 167 to contact or separate the movable contactor 150 from the fixed contactor 114 .

A coupling portion 158 is formed at the upper end of the shaft 157 . The coupling portion 158 may be formed in a plate shape, for example, a circular plate. In the shaft 157 , the coupling part 158 is fixedly coupled to the inside of the mover support 140 . The coupling part 158 of the shaft 157 may be manufactured by inserting coupling to the mover support 140 , for example, by insert injection.

The mover support 140 has a shaft 157 fixedly installed therein and is provided to support the movable contactor 150 and the like. The mover support 140 includes a first flat plate portion 141 and an arm portion 142 protruding upwardly from both ends of the first flat plate portion 141 .

A spring support part 143 is formed to protrude from the upper portion of the first flat plate portion 141 of the mover support 140 .

The mover holder 145 is fixedly installed on the arm portion 142 of the mover support 140 .

When viewed from the front (see FIGS. 2 and 4 ), the (left and right direction) length of the first flat plate part 141 is smaller than the (left and right direction) length of the movable contactor 150 . Accordingly, the contact points of the movable contactor 150 are exposed to both sides of the movable contactor 140 .

The (front-back direction) width of the inner surface (upper surface) of the first flat plate part 141 may be formed to be smaller than the (front-back direction) width of the movable contact 150 . Accordingly, the mover holder 145 may be stably inserted and coupled to the arm portion 142 of the mover support 140 (refer to FIG. 3 ).

An insertion part 144 inserted into the central hole (unsigned) of the middle plate 170 is protruded from the lower surface of the mover support 140 . The insertion part 144 may be formed in a disk shape. Since the insertion part 144 is formed at the lower part of the mover support 140 and fitted to the middle plate 170 , the stability of the mover assembly 130 is improved.

A mover holder 145 is provided to support the movable contact 150 , the upper yoke 131 , and the lower yoke 135 .

The mover holder 145 is fixedly installed on the mover support 140 . The mover holder 145 is formed in a 'C' shape. That is, the mover holder 145 has a second flat plate portion 146 and both side portions 147 . Both side portions 147 are bent downwardly at both ends of the second flat portion 146 .

The width (length in the left and right direction) of the second flat plate portion 146 is smaller than the length of the movable contact 150 . Accordingly, the contact points of the movable contactor 150 are exposed to both sides of the movable contactor 145 .

The side portion 147 is formed to extend downwardly adjacent to the second flat portion 146 . The side part 147 is inserted and coupled to the arm part 142 of the mover support 140 .

The width (left and right direction) of the side part 147 may be the same as the width of the second flat plate part 146 .

A hole 148 is formed in the side portion 147 . Accordingly, it is possible to improve the bonding force during insert injection.

The upper yoke 131 is installed under the mover holder 145 . The upper yoke 131 may be formed of a flat plate. The width of the upper yoke 131 may be the same as the width of the mover holder 145 .

A coupling groove 132 to which the lower yoke 135 can be coupled is formed on a lower surface of the upper yoke 131 . The coupling groove 132 may be formed at the front and rear ends, respectively.

The movable contactor 150 is installed to be in contact with the lower surface of the upper yoke 131 . The upper yoke 131 and the movable contact 150 may be separated without being fixed to the movable holder 145 . Accordingly, when the mover assembly 130 moves upward, the movable contact 150 is separated from the second flat plate 146 and is brought into close contact with the fixed contact 114 by receiving a contact pressure by the contact pressure spring 155 .

Support grooves 151 are formed on the front and rear sides of the movable contact 150 . The wing portion 137 of the lower yoke 135 is inserted into the support groove 151 .

The movable contact 150 is surrounded by the upper yoke 131 of the upper part and the lower yoke 135 of the lower part.

The lower yoke 135 is installed under the movable contact 150 . The lower yoke 135 may include a third flat plate portion 136 and a wing portion 137 bent upward at both ends of the third flat portion 136 .

The contact pressure spring 155 applies a contact pressure to the movable contactor 150 through the lower yoke 135 . Therefore, since the contact spring 155 applies a contact pressure without damaging the movable contact 150, safety is improved.

The wing portion 137 of the lower yoke 135 is fitted into the support groove 151 of the movable contact 150 and the coupling groove 132 of the upper yoke 131, respectively. Accordingly, the upper yoke 131 , the movable contactor 150 , and the lower yoke 135 do not separate from the mover holder 145 and maintain their mutual coupling force.

The lower yoke 135 is formed with a support protrusion 138 to which the contact pressure spring 155 can be mounted. Since the upper end of the contact spring 155 is fitted to the support protrusion 138 of the lower yoke 135, the operation stability is improved without being separated.

By the upper yoke 131 provided on the upper portion of the movable contactor 150 and the lower yoke 135 provided on the lower portion of the movable contactor 150 , the upper yoke 131 and the lower yoke 135 are energized when the circuit is energized. ) is magnetized so that the lower yoke 135 receives a force attracted to the upper yoke 131 . Accordingly, the movable contact 150 receives a force upward to cancel the electromagnetic repulsive force generated in the contact portions 114 and 150 .

A contact spring 155 is provided between the lower yoke 135 and the mover support 140 . The contact pressure spring 155 is provided to support the movable contactor 150 and provide a contact pressure to the movable contactor 150 when energized. The contact pressure spring 155 may be configured as a compression coil spring.

The upper end of the contact spring 155 is inserted into the support protrusion 138 of the lower yoke 135 , and the lower end of the contact spring 155 is inserted into the spring support 143 of the mover support 140 to be stably maintained.

Since the contact spring 155 directly contacts the lower yoke 135 , the movable contact 150 is not damaged. Therefore, durability is increased.

A mover holder of a mover assembly of a DC relay according to another embodiment of the present invention will be described with reference to FIG. 5 .

In the mover assembly of this embodiment, other components except for the mover holder 145 may be formed the same as or similar to those of the previous embodiment.

Unlike the previous embodiment, skirt portions 149 are formed on the left and right sides of the mover holder 145 . Accordingly, the upper yoke 131 is inserted into the space created by the side portion 147 and the skirt portion 149 of the mover holder 145 . Accordingly, even if the lower yoke 135 moves up and down, it does not completely deviate from the skirt 149 of the mover holder 145 . Accordingly, the lower yoke 135 does not disengage.

A mover holder of a mover assembly of a DC relay according to another embodiment of the present invention will be described with reference to FIGS. 6 and 7 .

In the mover assembly of this embodiment, other components except for the mover holder 145 , the upper yoke 131 , and the lower yoke 135 may be formed to be the same as or similar to those of the first embodiment.

In this embodiment, the upper yoke 131 is disposed on the top of the mover holder 145 . That is, the mover holder 145 is disposed between the upper yoke 131 and the movable contact 150 . The respective dimensions of the mover holder 145 and the upper yoke 131 are changed as appropriate. A through hole 146a through which the support 133 of the upper yoke 131 is inserted is formed in the upper surface of the mover holder 145 . A fixing protrusion 139 is formed protruding from each corner of the wing portion 137 of the lower yoke, and it passes through the connection groove 147a of the mover holder 145 and is fitted into the coupling groove 132 of the upper yoke 131. . Since the mover holder 145 is in direct contact with the moveable contactor 150, operation stability is improved.

The main difference between this embodiment and the first embodiment is the arrangement order. In the first embodiment, the mover holder 145 - the upper yoke 131 - the movable contactor 150 - the lower yoke 135 - the mover support 140 are arranged in the order from top to bottom, whereas this embodiment In the upper yoke 131 - the mover holder 145 - the movable contact 150 - the lower yoke 135 - the mover support 140 in the direction from top to bottom are arranged in the order.

According to the DC relay according to each embodiment of the present invention, the movable contact is provided with an upper yoke and a lower yoke to cancel the electromagnetic repulsive force, so that unintentional separation of the contact portion does not occur.

The embodiments described above are embodiments for implementing the present invention, and various modifications and variations may be made by those of ordinary skill in the art to which the present invention pertains without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. That is, the protection scope 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.

111,112 frame 113 arc chamber
114 Fixed Contact 115 Permanent Magnet Holder
130 mover assembly 131 upper yoke
132 coupling groove 135 lower yoke
136 Flat part 137 Wing part
138 Support projection 140 Mover support
141 Flat part 142 Arm part
143 spring support 144 insert
145 mover holder 146 first flat plate part
147 side 148 holes
149 Chima part 150 Movable contactor
151 Support groove 155 Contact spring
157 shaft 158 coupling part
160 Actuator 161 Yoke
165 fixed core 167 movable core
168 cylinder 169 return spring
170 Middle plate 172 Sealing member

Claims (20)

A DC relay comprising a pair of fixed contacts and a movable contact that is contacted or separated from the pair of fixed contacts by moving up and down by electromagnetic force,
an upper yoke and a lower yoke respectively provided on the upper and lower portions of the movable contactor;
a mover support for supporting the movable contactor, the upper yoke and the lower yoke;
a mover holder fixed to the upper part of the mover support;
a contact pressure spring provided between the lower yoke and the mover support; and
a shaft coupled to the mover support to transmit power of the actuator; and
The contact spring presses the lower yoke to move the movable contact,
The shaft has an upper end coupled to a shank mover support,
The upper yoke is disposed on the upper part of the mover holder,
A DC relay, characterized in that fixed protrusions are formed protruding from each corner of the lower yoke, pass through connection grooves formed at each corner of the mover holder, and are fitted into coupling grooves formed at each corner of the upper yoke. . [2] The DC relay of claim 1, wherein the mover support includes a first flat plate portion and an arm portion protruding upwardly from both ends of the first flat plate portion to fix the mover holder. The DC relay according to claim 2, wherein a spring support portion supporting a lower end of the contact pressure spring is protruded from the first flat plate portion. The DC relay according to claim 1, wherein an insertion part inserted into the center hole of the middle plate is formed to protrude from the lower surface of the mover support. The DC relay according to claim 1, wherein the mover holder has a second flat plate portion and side portions bent downward at both ends of the second flat portion, respectively. [Claim 6] The DC relay according to claim 5, wherein skirt portions into which the upper yoke can be inserted are formed on left and right sides of the mover holder. [2] The DC relay of claim 1, wherein the lower yoke comprises a third flat plate portion and a wing portion bent upwardly at both ends of the third flat portion. [8] The DC relay according to claim 7, wherein coupling grooves to which the wing parts can be coupled are respectively formed at front and rear ends of the upper yoke. The DC relay according to claim 8, wherein support grooves into which the wing parts are inserted are formed on front and rear side surfaces of the movable contactor. The DC relay according to claim 1, wherein a support protrusion to which an upper end of the contact pressure spring can be fixed is formed on a lower surface of the lower yoke. delete delete The DC relay according to claim 1, wherein a through hole through which a support formed on a lower surface of the upper yoke is inserted is formed in an upper surface of the mover holder. A DC relay comprising a pair of fixed contacts and a movable contact that is contacted or separated from the pair of fixed contacts by moving up and down by electromagnetic force,
an upper yoke and a lower yoke respectively provided on the upper and lower portions of the movable contactor;
a mover support for supporting the movable contactor, the upper yoke and the lower yoke;
a mover holder fixed to the upper part of the mover support;
a contact pressure spring provided between the lower yoke and the mover support; and
a shaft coupled to the mover support to transmit power of the actuator; and
The contact spring presses the lower yoke to move the movable contact,
The shaft has an upper end coupled to a shank mover support,
The lower yoke is formed with wing portions bent upward at both ends,
Support grooves into which the wing parts are inserted are formed on the front and rear side surfaces of the movable contactor,
A DC relay, characterized in that the front and rear ends of the upper yoke are formed with coupling grooves to which the wing parts can be coupled, respectively. 15. The DC relay of claim 14, wherein the mover support includes a first flat plate portion and an arm portion protruding upwardly from both ends of the first flat plate portion to fix the mover holder. [Claim 16] The DC relay of claim 15, wherein a spring support portion supporting a lower end of the contact pressure spring is protruded from an upper portion of the first flat plate portion. 15. The DC relay of claim 14, wherein an insertion part inserted into the center hole of the middle plate is formed to protrude from the lower surface of the mover support. 15. The DC relay according to claim 14, wherein the mover holder has a second flat plate portion and side portions bent downward at both ends of the second flat portion, respectively. 15. The DC relay of claim 14, wherein a support protrusion to which an upper end of the contact pressure spring can be fixed is formed on a lower surface of the lower yoke. 15. The method of claim 14, wherein when the upper yoke is disposed on top of the mover holder,
DC relay, characterized in that the through hole is formed in the upper surface of the mover holder through the support formed on the lower surface of the upper yoke is inserted.

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