KR20220168465A - Relay - Google Patents

Abstract

The purpose of the present invention is to provide a relay that includes a structure for improving electromagnetic force in addition to a coil wire, can maximize the winding space of the coil wire, and can improve productivity by simplifying parts and structure. The present invention comprises: a main plate that is panel-shaped and has a hole formed therethrough in the center; a coil portion installed at a lower portion of the main plate and including a cylindrical bobbin extending in one direction and a coil wire wound around the bobbin; an upper terminal installed on the main plate, installed on one side of the coil unit, and including a plurality of electrodes; a movable core portion disposed in the center of the coil portion and movable through a hole in the main plate to move back and forth in the longitudinal direction of the bobbin and in contact with or spaced apart from the upper terminal; and a ring-shaped permanent magnet disposed on the upper surface of the main plate and disposed in a direction surrounding an outer circumference of the movable core portion.

Description

relay {relay}

The present invention relates to a relay, which is a device that serves to open or close an electric circuit. More specifically, it relates to a relay that opens and closes an electric circuit by moving a movable electrode with a coil so that it contacts or separates from a fixed electrode.

A relay is a device that operates when an input reaches a certain value to open and close another circuit, and includes relays with contacts, thermal relays, pressure relays, optical relays, and the like. Among them, a relay having a contact is formed to be energized by having a fixed electrode and a movable electrode and moving the movable electrode to come into contact with the fixed electrode.

The movable electrode is the principle that when electricity is applied to the coil wire, current flows and an electromagnetic field is generated, and it is moved using electromagnetic force. If the electromagnetic force can be increased, the weight of the relay can be reduced and the size can be made small, so an iron core upper and lower adsorption structure or a lower permanent magnet structure is used to form a large electromagnetic force.

1 is a perspective view and partial cross-sectional view of a relay to which a conventional iron core upper and lower adsorption structure is applied, and FIG. 2 is a perspective view and a partial cross-sectional view of a relay to which a conventional lower permanent magnet structure is applied. As shown in the general structure of the relay, two fixed electrodes (1) are formed, a movable electrode (2) that conducts electricity to the two fixed electrodes is formed, and a movable core (5) is formed in the center of a coil wire (4) wound. and the movable core is connected to the movable electrode by a rod. Based on the main plate 7, the coil wire 4 is formed at the bottom and the movable electrode 2 is formed at the top.

Referring to FIG. 1, the iron core up-and-down suction method forms a fixed core 6 under the main plate together with the movable core 5, and the movable core and the fixed core are formed to be engaged by a tapered structure. However, in this iron core up-and-down adsorption method, since the fixed core 6 must be arranged to form a large magnetic field at intervals, a structure that maximizes the length and total volume of the coil wire 4 is required, and the fixed core 6 Fixing to the main plate 7 is also required. In addition, there are also difficult processing problems, such as forming the shape of the core to be tapered to increase the contact cross-sectional area.

Referring to FIG. 2, the lower permanent magnet method is to install a permanent magnet 6a under the main plate 7, but it is not formed to contact the movable core including the permanent magnet. However, even in this case, there is a spatial problem in that the iron piece 6b must be used together and parts must be added, and the winding space of the coil wire 4 must be devoted to the permanent magnet. Therefore, there is a problem in that the magnetic field generation area of the coil wire is reduced.

Therefore, there is a need for a structure capable of improving the magnitude of the electromagnetic force without using the conventional iron core upper and lower adsorption method or the lower permanent magnet method.

The present invention is to solve the problems of the prior art as described above, and includes a structure for improving electromagnetic force in addition to the coil wire, can maximize the winding space of the coil wire, and improves productivity by simplifying parts and structures. Its purpose is to provide a relay that can

An embodiment of the present invention provides the following relay in order to solve the above problems.

The present invention is a panel-shaped main plate through which a hole is formed in the center; a coil unit installed under the main plate and including a cylindrical bobbin extending in one direction and a coil wire wound around the bobbin; an upper terminal installed on the main plate, installed on one side of the coil unit, and including a plurality of electrodes; a movable core part disposed in the central part of the coil part, passing through the hole of the main plate and reciprocating in the longitudinal direction of the bobbin, and installed in contact with or spaced apart from the upper terminal; and a ring-shaped permanent magnet disposed on an upper surface of the main plate and disposed in a direction surrounding an outer circumference of the movable core unit. It is characterized in that it includes.

In addition, an insulator made of an insulating material, disposed on the upper surface of the main plate, and formed to surround the permanent magnet and the outer circumference of the movable core part; It is characterized in that it further comprises.

In addition, the insulator may include a magnet accommodating part formed so that a lower surface is in contact with an upper surface of the main plate and the permanent magnet is accommodated in a lower portion to cover the side surface and the upper surface of the permanent magnet.

In addition, a seating hole is formed through the central portion of the magnet accommodating portion, and the movable core portion is installed to be reciprocally movable through the seating hole, the seating hole is smaller than the width of the inner diameter of the permanent magnet, and the movable core portion It is characterized in that it is formed in a shape corresponding to the cross section.

In addition, the movable core part includes a movable core disposed inside the bobbin in a longitudinal direction, a movable contact formed to contact the upper terminal and conduct electricity, and a holder connecting the movable core and the movable contact, The core, the holder, and the movable contact are disposed in the longitudinal direction of the bobbin, and on the side of the holder, a rib-shaped protrusion is formed to form a stepped seating step, and the upper terminal and the movable core part are spaced apart. The holder is inserted into the seating hole, and the seating jaw is in contact with an upper surface of the magnet receiving portion.

According to the problem solving means of the present invention as described above, various effects including the following can be expected. However, the present invention is not established when all of the following effects are exerted.

According to the present invention, since the conventional iron core or permanent magnet is not disposed in the portion where the coil wire is wound, the number of windings of the coil wire can be maximized, and thus the magnetic force can be maximized. That is, the permanent magnet can be disposed without interfering with the space of the coil wire by disposing the permanent magnet on the upper side of the main plate. Therefore, there is an effect that the volume and weight of the entire relay can be reduced. In addition, in the case of applying this structure, there is an effect of cost reduction by reducing coil consumption, and there is an effect of improving quality by increasing operational safety.

In addition, in order to place the conventional permanent magnet at the bottom of the main plate, an iron piece had to be placed at the end of the permanent magnet, but when the permanent magnet is placed at the top of the main plate, the iron piece is unnecessary, so the number of parts can be reduced, which has an economical effect.

In addition, since the holder is seated on the insulator when the relay is off, the moving distance of the contact point can be kept constant, and since the contact between the holder and the insulator is made of plastic materials, it is less likely to collide with a permanent magnet or piece of iron during operation. It has the effect of reducing noise.

1 is a perspective view and partial cross-sectional view of a relay to which a conventional iron core upper and lower adsorption structure is applied;
2 is a perspective view and partial cross-sectional view of a relay to which a conventional lower permanent magnet structure is applied;
Figure 3 is a perspective view in which the housing, relay body and installation cover of the relay of the present invention are separated;
4 is a perspective view in which the relay body is separated from FIG. 3;
5 is a front view showing a part of the configuration of the relay body of FIG. 3;
6 is a perspective view showing a configuration related to an upper terminal and a movable contact;
7 is a perspective view showing two embodiments of a contact guide;
8 is an enlarged view showing that the movable contact is pressed by the contact guide;
9 is a perspective view of an upper core and a movable core part and an enlarged view of a holder seating jaw part;
10 is a longitudinal sectional view of a part of FIG. 9;
11 is a perspective view and a front view of the lower magnet;
12 is a perspective view of an insulator;
13 is a perspective view and a cross-sectional view of a movable core unit in a state in which an external housing is removed.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings.

Figure 3 is a perspective view of the relay housing of the present invention, the relay body and the installation cover are separated, Figure 4 is a perspective view of the relay body in Figure 3 is separated, Figure 5 is a front view showing a part of the configuration of the relay body of Figure 3, 6 is a perspective view showing the configuration related to the upper terminal and the movable contact, FIG. 7 is a perspective view showing two embodiments of the contact guide, FIG. 8 is an enlarged view showing that the movable contact is pressed by the contact guide, FIG. A perspective view of the upper core and the movable core part and an enlarged view of the holder seating jaw part, Fig. 10 is a longitudinal sectional view of a part of Fig. 9, Fig. 11 is a perspective view and a front view of the lower magnet, Fig. 12 is a perspective view of the insulator, Fig. 13 is an external housing A perspective view and a cross-sectional view of the movable core in a removed state.

As shown in these drawings, in one embodiment of the relay 10 of the present invention, the relay body 200 is installed in a hollow space such as an enclosure formed of an outer housing 101 and an installation cover 102 to form a body. .

The body of the relay 10 is composed of an upper housing 210, an insulator 220, a movable core 230, a coil 240, and a lower housing 250, and a fixed electrode is formed on the upper housing 210. A movable electrode is formed on the movable core part 230, and when a current flows through the coil part 240, the movable electrode moves and comes into contact with the fixed electrode. A detailed configuration is described below.

The upper housing 210 includes an upper yoke 211 serving as a housing and an upper magnet 212 inserted inside the upper yoke 211 .

The insulation unit 220 is configured for insulation and includes an upper terminal 221 serving as a fixed electrode or a fixed contact therein. Two upper terminals 221 are formed, and may be formed apart from each other in a structure electrically connected by a movable contact point 231 . In addition, a ceramic plate 222b having a panel shape and formed of an Fe-Ni alloy, etc., and a ceramic base 222a made of an alumina material are formed by being bonded in a box shape on the upper side of the ceramic plate 222b. The movable contact 231 moves within the ceramic base 222a. In addition, an insulator 223 for insulation is inserted between the ceramic base 222a and the movable contact 231 inside the insulator 220 .

The insulator 223 is disposed within a range that does not interfere with the movement of the movable contact 231, is formed of a plastic injection product, and is a configuration to prevent damage to internal components from a high voltage arc generated when the relay 1 is turned off. More specifically, the insulator 223 includes a panel-shaped base portion 223a, a rib 223b extending upward from the base portion 223a, and a magnet receiving portion protruding from the central portion and having a space formed therein. (223c) may be formed. The magnet accommodating part 223c is formed to cover the side surface and the upper surface of the lower magnet 236, and a seating hole 223d may be formed through the upper surface of the magnet accommodating part 223c at a central portion. The holder 234 is installed and moved through the seating hole 223d, and the shape of the seating hole 223d may be formed to correspond to the shape of the outer surface of the holder 234. Also, although not shown in the drawing, a stepped structure having a complementary shape that can be engaged with the seating jaw 234a of the holder 234 may be formed around the seating hole 223d.

In addition, the movable core part 230 is a part where the movable contact point 231 is movable, and the movable contact point 231 extends in one direction so as to connect the two upper terminals 221 to each other. For example, the movable contact 231 may be formed in an elongated panel shape as shown in the drawing so that one surface is in contact with the upper terminal.

A main plate 237 is installed on the lower surface of the ceramic plate 222b, and a movable shaft may be formed through the main plate 237 so that the movable contact point 231 can be driven. The main plate 237 is magnetized by magnetic force and has a core and attractive force acting thereon.

Further, a lower magnet 236, which is a ring-shaped permanent magnet, is installed on the upper surface of the main plate 237, and the lower magnet 236 may have N poles 236a and S poles 236b formed in a horizontal direction. The lower magnet is a component for amplifying the magnetic force of the solenoid and is related to the operation of the movable core unit. The above-described insulator 223 may be installed on the lower magnet 236 . The movable contact 231 is installed by the holder 234, and an upper spring 233 is inserted between the holder 234 and the movable contact 231 to apply elastic force in the movable direction.

Meanwhile, the holder 234 is formed in a shape having a width and a certain height, such as a rectangular parallelepiped, and a holder pin 235 may protrude from one surface or one surface and the other surface facing the holder 234 . In addition, a groove may be concave on the surface where the holder pin 235 is formed. In addition, on the surface where the holder pin 235 is not formed, a seating jaw 234a may be formed to protrude laterally in a rib shape from the top. That is, a jaw may be formed at the lower end of the seating jaw 234a.

Therefore, the holder 234 moves together with the movable contact 231, but when the relay 10 moves in the off direction, the seating jaw 234a can be caught on the upper surface of the magnet receiving part 223c of the insulator 223. to be. Therefore, while limiting the movable range of the holder 234, since the holder 234 and the insulator 223 are formed of plastic injection products, there is an effect of reducing noise even when bumped into.

In addition, a contact guide 232 may be installed in the holder 234 and the movable contact 231 . The contact guide 232 may be installed to connect the holder 234 and the movable contact 231, and may be formed in a bent panel shape as a whole. The contact guide 232 includes a limiting portion 231a disposed to overlap the upper surface of the movable contact 231, a connecting portion 231b extending from the limiting portion 231a toward the holder 234, and a connecting portion 231b. It may include an insertion portion 231c bent inwardly at the end and a wing portion extending from the limiting portion 231a in a direction extending the surface overlapping the movable contact 231 . The wing portion may extend from the limiting portion 231a and may be bent toward the holder 234 and inclined. As the first embodiment of the contact guide 232 of the present invention, the first wing portion 231d is formed at a plurality of places along the width direction of the movable contact point 231, or in the second embodiment 2320, The two wing parts 2310d may be formed long and extended in the shape of one wing. In addition, a hole or groove may be formed on the connection portion 231b to be inserted into the holder pin 235 described above.

Due to the elastic force of the upper spring 233, the movable contact point 231 is brought into close contact with the lower surface of the contact guide 232, and in particular, it can be brought into close contact as if being pressed by the wings. Therefore, during operation, the movable contact point 231 can be maintained horizontally and can be fixed without swinging in the vertical direction.

Continuing to describe the movable core part 230, the holder 234 is connected to the movable core 238 by a rod 239, and the movable core 238 is applied with power to the coil wire 241 to generate magnetic force. When formed, it is configured to move along the longitudinal direction of the bobbin by electromagnetic force.

A lower spring for supporting between the main plate 237 and the movable core 238 may be installed on the outer circumference of the rod 239 . That is, one end of the lower spring may be supported on the lower surface of the main plate 237 and the other end may be supported on the upper surface of the movable core 238 .

The coil unit 240 is a part to which power is supplied to operate the relay 10, and a coil wire 241 is wound around a bobbin 242, and a terminal 243 may be formed at one end of the coil wire.

The lower housing 250 may include a lower yoke 251 and a bobbin guide 252 formed of a lower surface and a side surface. A bobbin guide 252 is formed in a cylindrical shape at the center of the lower surface of the lower yoke 251 so that the bobbin 242 is fitted to the outer circumference, and the movable core 238 can be driven in the longitudinal direction inside the bobbin guide 252. . In addition, a side surface may extend upward from the lower surface of the lower yoke 251, and a step may be formed at an end portion of the side surface so that the main plate 237 may be installed.

In the present specification, each configuration has been described in detail by division, but embodiments that can be derived by arbitrarily combining some configurations also fall within the scope of the present invention.

The above description is only illustrative of the technical idea of the present invention, and those skilled in the art can make various modifications and variations without departing from the essential characteristics of the present invention. The protection scope of should be interpreted by the claims below, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

10 Relay 101 External Housing
102 Installation cover 200 Relay body
210 upper housing 211 upper yoke
212 upper magnet 220 insulation
221 upper terminal 222a ceramic base
222b ceramic plate 223 insulator
223a base part 223b rib
223c Magnet storage unit 223d Seating hole
230 movable core 231 movable contact
231a limiting part 231b connecting part
231c insertion part 231d first wing part
2310d second wing 232 contact guide
233 upper spring 234 holder
234a seat jaw 235 holder pin
236 lower magnet 236a N pole
236b S pole 237 Main plate
238 movable core 239 rod
240 coil part 241 coil wire
242 bobbin 243 terminal
250 lower housing 251 lower yoke
252 bobbin guide

Claims (5)

A main plate having a panel shape and having a through hole in the center;
a coil unit installed under the main plate and including a cylindrical bobbin extending in one direction and a coil wire wound around the bobbin;
an upper terminal installed on the main plate, installed on one side of the coil unit, and including a plurality of electrodes;
a movable core part disposed in the central part of the coil part, passing through the hole of the main plate and reciprocating in the longitudinal direction of the bobbin, and installed in contact with or spaced apart from the upper terminal; and
a ring-shaped permanent magnet disposed on an upper surface of the main plate and disposed in a direction surrounding an outer circumference of the movable core unit;
A relay comprising a.
According to claim 1,
an insulator made of an insulating material, disposed on an upper surface of the main plate, and formed to surround outer circumferences of the permanent magnet and the movable core;
Relay characterized in that it further comprises.
According to claim 2,
The relay of claim 1 , wherein a lower surface of the insulator is in contact with an upper surface of the main plate, and includes a magnet accommodating part formed to cover the side surface and the upper surface of the permanent magnet by receiving the permanent magnet therein.
According to claim 3,
A seating hole is formed through the central portion of the magnet storage unit,
The movable core part is installed to be reciprocally movable through the seating hole,
The seating hole is smaller than the width of the inner diameter of the permanent magnet and is formed in a shape corresponding to the cross section of the movable core part.
According to claim 4,
The movable core part includes a movable core disposed inside the bobbin in a longitudinal direction, a movable contact formed to contact the upper terminal and conduct electricity, and a holder connecting the movable core and the movable contact,
The movable core, holder and movable contact are disposed in the longitudinal direction of the bobbin,
On the side surface of the holder, a rib-shaped protrusion is formed to form a stepped seating step,
In a state where the upper terminal and the movable core part are spaced apart, the holder is inserted into the seating hole, and the seating jaw is in contact with an upper surface of the magnet receiving portion.

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