KR102349753B1 - Multi-Contact DC Relay - Google Patents

Abstract

A multi-contact DC relay according to an embodiment of the present invention includes an enclosure; a yoke installed inside the enclosure to form a magnetic path; a plurality of bobbins installed to be spaced apart from each other on the upper portion of the yoke; a plurality of coils each wound on the plurality of bobbins; a plurality of fixed contacts respectively installed to be spaced apart from each other on top of the plurality of coils; and a movable contact that is provided between the plurality of fixed contacts and operates so as to be able to contact or separate any fixed contact among the plurality of fixed contacts, wherein in a neutral state, the movable contact is the plurality of fixed contacts. It is characterized in that when a magnetic force is generated in any one of the plurality of coils without contacting any one of the fixed contacts among the contactors, the fixed contact is in contact with the fixed contact disposed above the one of the coils.

Description

Multi-Contact DC Relay

The present invention relates to a multi-contact DC relay, and more particularly, to a DC relay having a plurality of contact parts in an enclosure.

In general, a DC Relay or Electro-magnetic Contactor is a type of electrical circuit switchgear that uses the principle of an electromagnet to drive mechanically and transmit current signals, and is used in various industrial facilities, machines, and vehicles. is installed

As is well known, a DC relay has a structure that, when a coil power is connected and a magnetic field is generated in the coil, the main contact is connected by magnetic force to energize the main circuit.

An example of a DC relay according to the prior art is shown in FIGS. 1 and 2 . 1 to 2 show the operating state of a DC relay according to the prior art. Fig. 1 is a cut-off state, and Fig. 2 is an energized state.

1 to 2 show a hinge type relay. In the enclosure (1), a bobbin (8) and a coil (3) and a yoke (5) are installed around the coil (3). The plate 2 is coupled to one side of the yoke 5 by plate spring coupling, and the movable contact 6 is coupled to the plate 2 and moves together with the plate 2 . The fixed contact 7 is installed to contact or separate the movable contact 6 .

In the blocking state (Off state) as shown in FIG. 1 , the coil 3 is in a non-acting state (not generating a magnetic field). The yoke (5) and the plate (2) are made of a plate spring joint, and accordingly, the moving contact (6) and the fixed contact (Fixed Contact) are kept apart. The plate 2 is coupled to the yoke 5 by a leaf spring so as to maintain a predetermined distance from the bobbin 8 supporting the coil 3 as long as no external force acts on it. This plate spring coupling serves as a blocking function to keep the plate 2 from contacting the bobbin 8 and to maintain a certain distance at the same time. At this time, the movable contact 6 coupled to the plate 2 is in a state separated from the fixed contact 7 and the circuit is maintained in a blocked state.

2 shows an On state. When an LV (Low Voltage) voltage is applied to the coil 3 through the coil terminal 4 , a magnetic force is generated in the coil 3 . That is, a magnetic field is formed around the coil 3 , and a magnetic path circulating through the yoke 5 and the plate 2 is formed. By this magnetic force, the yoke 5 is drawn in the direction in which the bobbin 8 is located. As long as the magnetic force is maintained, the plate 2 remains attached to the bobbin 8 . At this time, the movable contact 6 coupled to the plate 2 moves downward along the plate 2 and maintains a state in contact with the fixed contact 7 . That is, the circuit is energized.

In the relay according to the prior art, it is customary to provide a single contact part (fixed contactor and movable contactor) in a single enclosure.

However, when it is necessary to arrange a plurality of relays in a narrow space, difficulties arise when the installation space is small compared to the occupied area of the plurality of relays.

This may also occur when it is necessary to selectively provide relays of different capacities in the same circuit.

That is, when it is necessary to install a plurality of relays, it is sometimes advantageous to provide a plurality of contacts in a single product rather than separately installing a plurality of relays each having a single contact.

As a prior document, reference may be made to US 6426689 B1 "ELECTROMAGNETIC RELAY".

The present invention has been devised to solve the above problems, and an object of the present invention is to provide a DC relay having a plurality of contact parts in an enclosure.

A multi-contact DC relay according to an embodiment of the present invention includes an enclosure; a yoke installed inside the enclosure to form a magnetic path; a plurality of bobbins installed to be spaced apart from each other on the upper portion of the yoke; a plurality of coils each wound on the plurality of bobbins; a plurality of fixed contacts respectively installed to be spaced apart from each other on top of the plurality of coils; and a movable contact that is provided between the plurality of fixed contacts and operates so as to be able to contact or separate any fixed contact among the plurality of fixed contacts, wherein in a neutral state, the movable contact is the plurality of fixed contacts. It is characterized in that when a magnetic force is generated in any one of the plurality of coils without contacting any one of the fixed contacts among the contactors, the fixed contact is in contact with the fixed contact disposed above the one of the coils.

Here, the enclosure may include a plurality of side plates, and the plurality of bobbins may be respectively installed on the plurality of side plates to be spaced apart from each other.

In addition, the yoke may include a horizontal portion formed of a flat plate, and a plurality of vertical portions bent at the horizontal portion and coupled to the plurality of side plates, respectively.

In addition, a return member for elastically supporting the movable contactor may be coupled to the plurality of bobbins, respectively.

Further, each of the return members may be composed of an elastic member.

In addition, each of the return members may be insertedly coupled to the insertion portion formed on one side flange of the plurality of bobbins.

In addition, each of the plurality of fixed contacts may be composed of a pair of contacts spaced apart from each other.

In addition, it further includes a moving member installed on the yoke to move between the plurality of coils, the movable contactor may be coupled to the moving member.

In addition, the moving member may include a shaft portion to be rotatably installed in the yoke or the enclosure.

In addition, the yoke or the enclosure may be formed with an insertion hole to which the shaft portion can be coupled.

In addition, the movable contactor may be formed of a flexible material that can be bent.

Since the multi-contact DC relay according to an embodiment of the present invention is provided with a plurality of contact parts within a single enclosure, there is no need to separately install a plurality of relays, thereby reducing the installation space.

In addition, since the effect of installing several relays with a single assembly is shown, assembly is simple and the time required for installation is reduced.

In addition, since the number of components such as the enclosure is reduced, the production cost is reduced.

In addition, since the contact unit can be disposed in both directions or in multiple directions, installation efficiency is increased where a three-dimensional configuration is required.

1 and 2 are diagrams showing the internal structure of a DC relay according to the prior art. 1 and 2 show the operation state of the relay. Fig. 1 is a cut-off state, and Fig. 2 shows a energized state.
3 is a perspective view of a multi-contact (two-contact) DC relay according to an embodiment of the present invention.
4 is a perspective view illustrating an internal structure by removing the case in FIG. 3 .
5 to 7 are perspective views of a movable member, a yoke, and a movable contact applied to a multi-contact DC relay according to an embodiment of the present invention, respectively.
8 to 10 are operational diagrams of a multi-contact DC relay according to an embodiment of the present invention, and respectively show a neutral state (Off state), a first contact part energized state, and a second contact part energized state.
11 and 12 are top views of a multi-contact DC relay according to another embodiment of the present invention, wherein the DC relay having four contact parts is shown. 11 shows a neutral state, and FIG. 12 shows a energized state of the first contact part.
13 shows a movable contactor applied to the embodiment of FIG. 12 .

Hereinafter, 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 spirit and scope of the invention are limited.

A multi-contact DC relay according to each embodiment of the present invention will be described in detail with reference to the drawings.

A multi-contact DC relay according to an embodiment of the present invention includes an enclosure (10); a yoke 45 installed inside the enclosure 10 to form a magnetic path; a plurality of bobbins (20, 25) installed to be spaced apart from each other on the upper portion of the yoke (45); a plurality of coils 30 and 35 wound around the plurality of bobbins 20 and 25, respectively; a plurality of fixed contacts (50, 55) respectively installed to be spaced apart from the upper portions of the plurality of coils (30, 35); and a movable contact that is provided between the plurality of fixed contacts 50 and 55 and operates so as to be able to contact or separate any fixed contact 50 and 55 among the plurality of fixed contacts 50 and 55 ( 60); and, in a neutral state, the movable contact 60 does not contact any one of the plurality of fixed contacts 50 and 55 among the plurality of fixed contacts 50 and 55, and the plurality of coils 30, 35), when a magnetic force is generated in any one of the coils 30, it is characterized in that it comes into contact with the fixed contactor 50 disposed above the one of the coils 30.

In the present invention, the multi-contact point means that a plurality of contact parts (a contact point between a fixed contact and a movable contact, or a fixed contact and a movable contact) are provided inside the enclosure. Here, the movable contact is provided singly, and the fixed contact is provided according to the number of contact parts. In addition, the movable contact may be provided with movable contacts corresponding to the number of contact parts, and the fixed contact may be provided with fixed contacts corresponding to the number of contact parts.

First, an example of a DC relay having two contact parts will be described.

3 is a perspective view of a two-contact DC relay according to an embodiment of the present invention, and FIG. 4 is a perspective view showing an internal structure of the case by removing the case in FIG. 3 .

The enclosure 10 is provided to accommodate the components therein. The enclosure 10 may be made of a synthetic resin material by molding injection. The enclosure 10 may be formed in a box shape.

The enclosure 10 includes a case 11 formed in a square ring shape, and a pair of side plates (or covers) 15 and 16 formed in a flat plate and symmetrically coupled to both side openings of the case 11 . may include

The case 11 may be formed to cover the first side plate 15 and the second side plate 16 .

The first side plate 15 and the second side plate 16 are disposed to be spaced apart from each other. The first side plate 15 and the second side plate 16 may be spaced apart from each other in a symmetrical form. The first side plate 15 and the second side plate 16 may be respectively installed in openings formed on both sides of the case 11 .

A yoke 45, a first bobbin 20 and a second bobbin 25, a first coil 30 and a second coil 35, and a first fixed to the first side plate 15 and the second side plate 16 The contactor 50, the second fixed contactor 55, the first coil terminal 33 and the second coil terminal 37 are installed and supported.

5 to 7 show a movable member, a yoke, and a movable contact applied to a multi-contact DC relay according to an embodiment of the present invention. Let's take a look at this with additional reference.

The yoke 45 is installed over the first side plate 15 and the second side plate 16 . The yoke 45 may be formed in a “C” shape. That is, the yoke 45 includes a horizontal portion 46 and a vertical portion 47 bent vertically on both sides of the horizontal portion 46 .

In the center of the horizontal portion 46, the movable member 40 is installed to be movable. For example, the moving member 40 may be rotatably installed on the horizontal portion 46 . At this time, an installation hole (or an installation groove) 48 is formed in the horizontal part 46 so that the movable member 40 can be rotatably installed. A shaft fixing hole 49 may be formed in communication with the installation hole 48 of the horizontal portion 46 . That is, in this embodiment, the moving member 40 may be coupled to the yoke 45 in the form of a hinge. Although not shown separately, the movable member 40 may be coupled to the yoke 45 in various ways to be movable.

The yoke 45 may be formed of a magnetic material (eg, iron) to form a magnetic path. That is, when a surrounding magnetic field is formed, it is magnetized to form a magnetic path.

A plurality of bobbins 20 and 25 are provided. In this embodiment, two bobbins are provided. Each bobbin is installed to be spaced apart from each other. For example, they are respectively provided on both sides of the yoke 45 .

Each of the bobbins is installed on the yoke 45 so as to be included as much as possible in the space formed by the magnetic path formed by the yoke 45 . For example, it may be installed inside a space formed by the magnetic path.

Each of the bobbins 20 and 25 may be respectively installed on the side plates 15 and 16 . That is, the first bobbin 20 may be installed on the first side plate 15 , and the second bobbin 25 may be installed on the second side plate 16 .

Since the first bobbin 20 and the second bobbin 25 may be formed symmetrically to each other, only the first bobbin 20 will be described. What has been described for the first bobbin 20 may also be applied to the second bobbin 25 .

The first bobbin 20 may include a cylindrical body and flanges provided at both ends of the cylindrical body.

An insertion part 23 into which the return members 71 and 72 can be inserted is provided on one side flange (eg, the second flange) of the first bobbin 20 . The insertion part 23 may be formed as a groove.

The first bobbin 20 may be installed on the yoke 45 in a lying state. The first bobbin 20 has a first flange 21 coupled to the first side plate 15 , and a second flange 22 is disposed inside the case 11 .

Coils 30 and 35 are installed in the plurality of bobbins 20 and 25, respectively. That is, the first coil 30 is wound around the first bobbin 20 , and the second coil 35 is wound around the second bobbin 25 .

The coils 30 and 35 are provided with coil terminals 33 and 37, respectively, and are exposed to the outside of the enclosure 10 . The first coil terminal 33 is connected to the first coil 30 , and the second coil terminal 37 is connected to the second coil 35 . When control power is input through the coil terminals 33 and 37 , a magnetic field is formed in each of the coils 30 and 35 and a magnetic force is generated in the yoke 45 .

Since each of the bobbins 20 and 25 are installed to be spaced apart, the respective coils 30 and 35 are also installed to be spaced apart, so that a magnetic field generated by each coil 30 and 35 is formed in a specific area within the enclosure 10 . For example, a magnetic field generated by the first coil 30 is formed in a left area under the enclosure 10 , and a magnetic field generated by the second coil 35 is formed in a right area under the enclosure 10 .

The moving member 40 is formed of a magnetic material (eg, iron) and can move (or be attracted) in the direction of each bobbin or each coil.

The moving member 40 may be formed in a bar or plate shape. The moving member 40 is movably coupled to the yoke 45 . Although not shown separately, the moving member 40 may pass through the yoke 45 and be movably coupled to the case 11 .

The movable member 40 may move in both directions (eg, in a left-right direction, in a direction of the first coil and the second coil). The moving member 40 may perform a linear motion or a rotational motion (rotational motion with the hinge as an axis). The moving member 40 may move between the first coil 30 and the second coil 35 through rotational motion. To this end, the shaft portion 41 may be formed to protrude from the moving member 40 . A shaft hole 42 into which the shaft member 44 can be inserted may be formed in the shaft portion 41 .

The fixed contacts 50 and 55 are respectively installed to be spaced apart from each of the coils 30 and 35 . The fixed contacts 50 and 55 are installed on the side plates 15 and 16 . That is, the first fixed contactor 50 is installed on the first side plate 15 , and the second fixed contactor 55 is installed on the second side plate 16 .

Each fixed contactor (50, 55) is installed on the side where each coil (30,35) is installed. That is, if the coils 30 and 35 are divided in the left and right directions, the fixed contacts 50 and 55 are also divided in the left and right directions. In other words, each of the fixed contacts 50 and 55 may be installed directly above each of the coils 30 and 35 .

Each fixed contact (50, 55) is provided as a pair, respectively. For example, the first fixed contactor 50 includes a pair of a first contactor 50a connected to one end of the main circuit and a second contactor 50b connected to the other end of the main circuit. The first contactor 50a connected to one end of the main circuit and the second contactor 50b connected to the other end of the main circuit are installed to be spaced apart from each other. At this time, the spaced distance between the first contactor 50a and the second contactor 50b should be formed to be smaller than the width of the movable contact 63 of the movable contact 60 .

The first fixed contactor 50 is exposed to the outside of the enclosure 10 and is connected to a load or a power source. For example, a first contactor 50a connected to one end of the main circuit may be connected to a power source, and a second contactor 50b connected to the other end of the main circuit may be connected to a load.

Matters applied to the first fixed contact 50 may be equally applied to the second fixed contact 55 . That is, the second fixed contacts 55 may also be provided in a symmetrical pair to be spaced apart from each other. The first fixed contact 50 is connected to the first circuit, and the second fixed contact 55 is connected to the second circuit.

A movable contact 60 is provided. The movable contact 60 is coupled to the movable member 40 . Accordingly, according to the movement of the movable member 40 , the movable contact 60 moves together with the movable member 40 .

The movable contact 60 may be formed of a bar or plate. The movable contactor 60 includes an extended portion 61 formed in a flat plate and a contact portion 62 formed in a curved surface. Here, the contact part 62 may include a first contact point 63 contacting the first fixed contacts 50 and 55 and a second contact point 64 contacting the second fixed contacts 50 and 55 . That is, the movable contact 60 is provided singly, the movable contact may be provided in plurality. In the example of the two-contact relay, two movable contacts 63 and 64 are provided.

The movable contactor 60 is installed so as not to contact any of the fixed contacts 50 and 55 in a neutral state. That is, it may be installed to be placed between the first fixed contact 50 and the second fixed contact 55 (eg, at an intermediate point).

Return members 71 and 72 are provided. The return members 71 and 72 elastically support the movable member 40 and the movable contact 60 to be positioned at a central position (neutral position) in a neutral state. When a magnetic force is generated in any one of the plurality of coils 30 and 35, the return member (71, 72) moves the movable member (40) and the movable contactor (60) so that the movable contactor (60) is moved to any one of the above coils. to be in contact with the fixed contactor installed in the direction of the coil of .

The return members 71 and 72 may be respectively coupled to the first bobbin 20 and the second bobbin 25 . For example, the first return member 71 may be insertedly coupled to the first insertion portion 23 of the first bobbin 20 .

The return members 71 and 72 may be formed of an elastic member, for example, a spring. That is, the return members 71 and 72 may be formed of a coil spring or a leaf spring.

Since the return members 71 and 72 are respectively provided on the first bobbin 20 and the second bobbin 25 to provide an elastic force, the movable contact 60 is located at the center between the first bobbin 20 and the second bobbin 25 . is placed on

An operation of the two-contact DC relay according to an embodiment of the present invention will be described with reference to FIGS. 8 to 10 . 8 to 10 show a neutral state (Off state, cut-off state), a first contact part energized state, and a second contact part energized state, respectively.

As shown in FIG. 8 , in a neutral state (Off state) in which control power is not input to any one of the plurality of coils 30 and 35 , the movable contact 60 is selected from among the plurality of fixed contacts 50 and 55 . Since it is placed in a neutral position without contacting even one fixed contact, the main circuit (the first circuit connected to the first fixed contact and the second circuit connected to the second fixed contact) is not energized. That is, both main circuits are in a state in which the current is cut off.

Referring to FIG. 9 , when control power is input to the first coil 30 , a magnetic field is generated around the first coil 30 to form a magnetic path circulating the yoke 45 and the first bobbin 20 . Accordingly, the movable member 40 is drawn toward the first bobbin 20 , and the movable contact 60 moving together with the movable member 40 is in contact with the first contact 63 and the first fixed contact 50 . The first circuit is energized. That is, the first contact portion is connected.

If the control power input to the first coil 30 is cut off and the magnetic force of the first coil 30 disappears, the movable member 40 and the movable contactor 60 are placed in a neutral position by the restoring force of the first return member 71 . to return to the state shown in FIG. 8, and the current in the first circuit is cut off. The first contact portion is disconnected.

Referring to FIG. 10 , when control power is input to the second coil 35 , a magnetic field is generated around the second coil 35 to form a magnetic path circulating the yoke 45 and the second bobbin 25 . Accordingly, the movable member 40 is dragged to the second bobbin 25 side, and the movable contact 60 moving together with the movable member 40 is in contact with the second contact 64 and the second fixed contact 55. The second circuit is energized. That is, the second contact portion is connected.

If the control power input to the second coil 35 is cut off and the magnetic force of the second coil 35 disappears, the movable member 40 and the movable contactor 60 are placed in a neutral position by the restoring force of the second return member 72 . returns to the state shown in FIG. 8, and the current of the second circuit is cut off. The second contact portion is disconnected.

Since the two-contact DC relay according to an embodiment of the present invention has two contact parts in a single enclosure, there is no need to separately install the two relays, thereby reducing the installation space.

In addition, since the effect of installing two relays in a single assembly is shown, assembly is simple and the time required for installation is reduced.

In addition, since the number of components such as the enclosure is reduced, the production cost is reduced.

In addition, since the contact unit can be disposed in both directions, the installation efficiency is increased where a three-dimensional configuration is required.

Although not shown separately, in the above embodiment, the movable member may be integrally formed with the movable contact. That is, the movable contactor is configured to be movable. The movable contactor may be formed to move by a rotational motion or to be made of a flexible material. In the following embodiment, an example in which the movable member is not interposed and the movable contact is configured alone is shown.

10 and 11 are top views of a multi-contact DC relay according to another embodiment of the present invention, wherein the DC relay having four contact parts is shown.

Here, FIG. 11 shows a neutral state, and FIG. 11 shows a energized state of the first contact part.

Even in a DC relay having three or more multi-contact points (a plurality of fixed contacts and a plurality of movable contacts, but here, the movable contact is also configured singly), the basic configuration of each unit is the same as or similar to the previous embodiment, so the previous embodiment and the different parts will be mainly explained.

The enclosure 110 is formed in a box shape. The enclosure 110 includes four side plates 111 to 114 . The four side plates 111 to 114 may be disposed on each side of the quadrangular box-shaped enclosure.

The yoke 146 is installed inside the enclosure 110 . The horizontal portion of the yoke 146 may be formed in a cross shape. At the end of each horizontal part, a vertical part is bent and coupled to each side plate (111 to 114). The yoke 146 may be formed of a magnetic material to form a magnetic path.

Four bobbins 121 to 124 are installed on each side plate 111 to 114, and coils 131 to 134 are installed on each bobbin 121 to 124, respectively. That is, four coils 131 to 134 are provided. The bobbins 121 to 124 and the coils 131 to 134 are installed adjacent to the yoke 146, and when control power is input to the coils 131 to 134 to form a magnetic field, the bobbins 121 to 124 and the yoke 146 are provided. forms a path.

The four fixed contacts 151 to 154 are installed to be spaced apart from the side where each coil 131 to 134 is installed. For example, each of the fixed contacts 151 to 154 may be installed to be spaced apart from each other on the upper portion of each coil 131 to 134 . Each of the fixed contacts 151 to 154 is fixedly installed on each side plate 111 to 114 and exposed to the outside of the enclosure 110 to be connected to a power source or a load, respectively.

Each of the fixed contacts 151 to 154 is provided as a pair of contacts, and each fixed contact 151 to 154 is connected to a respective main circuit (eg, a first circuit to a fourth circuit).

A movable contactor 160 is installed between each coil 131 to 134 and each fixed contactor 151 to 154 . The movable contactor 60 may be installed at a point corresponding to the same distance from each of the coils 131 to 134 .

The movable contactor 160 is made of a flexible member so that it can bend and contact each fixed contactor 151 to 154 . Alternatively, the movable contact 160 may be configured to be rotatably installed in the forward, backward, left, and right directions.

13 is a cross-sectional view of the movable contact 160 is shown. The movable contactor 160 may have a lower end fixedly installed on the bottom surface of the yoke 146 or the enclosure 110 . To this end, a coupling groove 163 may be formed in the lower end 162 of the movable contact 160 .

A contact portion 164 is formed at the upper end of the movable contactor 160 . The contact portion 164 may be formed in a shape such as a cylindrical shape or a square ring. The contact portion 164 may have movable contacts formed on a surface facing each of the fixed contacts 151 to 154 so as to be in contact with each of the fixed contacts 151 to 154 . That is, in this embodiment, four movable contacts may be provided.

Return members 171 to 174 are provided to support the movable contact 160 . The return members 171 to 174 allow the movable contact 160 to stay in a neutral position that does not contact any of the fixed contacts 151 to 154 when no external force is applied, and to make contact with any of the fixed contacts 151 to 154. When the control power is cut off in the energized state, an elastic restoring force is provided to return the movable contactor 160 to the neutral position.

Referring to FIG. 12 , the conduction action of the first contact part will be described. When control power is input to the first coil 131 to form a magnetic path circulating the yoke 146 and the first bobbin 121 , the movable contactor 160 is sucked in the direction of the first bobbin 121 to be first fixed It comes into contact with the contactor 151 . Accordingly, the first circuit is energized.

When the control power input to the first coil 131 is cut off, the magnetic path circulating the yoke 146 and the first bobbin 121 disappears, and the movable contactor 160 is placed in a neutral position by the elastic restoring force of the return member 171 . return to At this time, when the movable contact 160 itself is a flexible member, it is returned to the neutral position even by its own restoring force.

Since it acts in the same way for other contact parts, a redundant description will be omitted.

Since the multi-contact DC relay according to each embodiment of the present invention is provided with a plurality of contact parts within a single enclosure, there is no need to separately install a plurality of relays, thereby reducing the installation space.

In addition, since the effect of installing several relays with a single assembly is shown, assembly is simple and the time required for installation is reduced.

In addition, since the number of components such as the enclosure and the movable contactor is reduced, the production cost is reduced.

In addition, since the contact unit can be disposed in both directions or in multiple directions, installation efficiency is increased where a three-dimensional configuration is required.

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 equivalent range should be interpreted as being included in the scope of the present invention.

10 Enclosure 11 Case
15,16 Side plate 20,25 Bobbin
21,22 Flange 23 Insertion
30,35 coil 33,37 coil terminal
40 Moving member 41 Shaft
42 Shaft hole 44 Shaft member
45 yoke 46 horizontal
47 Vertical part 48 Installation hole
49 shaft fixing hole 50,55 fixed contact
50a, 50b contactor 60 movable contactor
61 extension 62 contact
63,64 movable contact 71,72 return member

Claims (11)

an enclosure including a first side plate and a second side plate facing each other;
a yoke installed inside the enclosure to form a magnetic path;
a plurality of bobbins installed to be spaced apart from each other on the upper portion of the yoke;
a plurality of coils each wound on the plurality of bobbins;
a plurality of fixed contacts respectively installed to be spaced apart from each other on top of the plurality of coils; and
and a movable contact that is provided between the plurality of fixed contacts and operates so as to be able to contact or separate any fixed contact from among the plurality of fixed contacts; and
In a neutral state, the movable contact does not contact any one of the plurality of fixed contacts,
When a magnetic force is generated in any one of the plurality of coils, it comes into contact with a fixed contactor disposed on the upper portion of the one of the coils,
The plurality of bobbins include a first bobbin disposed on the first side plate and a second bobbin disposed on the second side plate,
The plurality of coils includes a first coil wound around the first bobbin and a second coil wound around the second bobbin,
The plurality of fixed contacts includes a first fixed contact disposed on the first side plate and a second fixed contact disposed on the second side plate,
The movable contactor is disposed between the first bobbin and the second bobbin and between the first fixed contactor and the second fixed contactor. delete The multi-contact DC relay of claim 1, wherein the yoke includes a horizontal portion formed of a flat plate and a plurality of vertical portions bent at the horizontal portion and coupled to the plurality of side plates, respectively. [2] The multi-contact DC relay of claim 1, wherein a return member for elastically supporting the movable contact is coupled to the plurality of bobbins, respectively. 5. The multi-contact DC relay according to claim 4, wherein each of said return members is constituted by an elastic member. [Claim 5] The multi-contact DC relay of claim 4, wherein each of the return members is inserted and coupled to an insertion portion formed on one side flange of the plurality of bobbins. delete The multi-contact DC relay according to claim 1, further comprising a moving member installed on the yoke to move between the plurality of coils, wherein the movable contactor is coupled to the moving member. The multi-contact DC relay according to claim 8, wherein the moving member includes a shaft to be rotatably installed in the yoke or the enclosure. The multi-contact DC relay according to claim 9, wherein an insertion hole to which the shaft part can be coupled is formed in the yoke or the enclosure. The multi-contact DC relay according to claim 1, wherein the movable contactor is formed of a flexible material that can be bent.

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