KR20220119213A - High voltage relay - Google Patents

Abstract

The present invention relates to a relay and specifically, relates to a high voltage relay wherein a ring permanent magnet is provided in a fixed core. The present invention enables the ring permanent magnet to be provided on the fixed core, and can improve an operating force of an actuator part. In addition, the present invention, by providing the ring permanent magnet to be positioned inside of a bobbin hollow part and outside of a coil wound on the bobbin without changing a shape of the bobbin, prevents loss of coil winding by keeping a diameter of the bobbin constant. The high voltage relay comprises: a pair of fixing contact points; a contact point part; and an actuator part.

Description

High voltage relay

The present invention relates to a relay, and more particularly to a high voltage relay having a ring permanent magnet in a fixed core.

A relay is a device that opens and closes another circuit by operating by an external input, and includes a contact relay, a pressure relay, an optical relay, and a thermal relay. Among them, the contact relay operates the actuator by an external input to control the contact. Among these contact relays, the high voltage relay applied to high voltage controls the contact with an actuator, so the actuation force of the actuator is important.

Referring to Japanese Patent Application Laid-Open No. 2020-087567, the prior literature improved the actuation force of the actuator by adding a magnet. These prior documents include a bobbin assembly in which a coil is wound on a hollow bobbin and a movable core inserted in the center of the bobbin, but the upper part of the bobbin is bent outward to position the magnet. However, in this case, although the actuating force of the actuator can be improved, there is a problem in that coil winding loss in the region where the magnet is located occurs. Accordingly, there is a need for a technique capable of further increasing the operating force of the actuator without loss of coil winding.

Japanese Laid-Open Patent Publication No. 2020-087567 (published on June 4, 2020)

It is an object of the present invention to provide a high voltage relay capable of further improving the actuation force of an actuator without loss of coil winding.

The object of the present invention is not limited to the above-mentioned object, and other objects and advantages of the present invention not mentioned may be understood by the following description, and will be more clearly understood by the examples of the present invention. It will also be readily apparent that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the appended claims.

A high voltage relay according to the present invention includes a pair of fixed contacts, a contact portion including a movable contact in contact with the pair of fixed contacts, and an actuator portion for controlling the movable contact to contact the pair of fixed contacts. As a high voltage relay, the actuator unit includes: a coil assembly in which a coil is wound on a bobbin; a plate provided between the contact unit and the coil assembly; Includes ring permanent magnets.

The fixed core includes a first fixed core part located inside the hollow part, which is a space formed in the center of the bobbin, and a second fixed core part protruding from an upper portion of the first fixed core part and having a smaller diameter than the first fixed core part. and a lower surface of the ring permanent magnet is in contact with an upper edge of the first fixed core portion, and an inner surface of the ring permanent magnet is in contact with an outer surface of the second fixed core portion.

The coil is wound on the outer surface of the bobbin having a constant diameter, and the ring permanent magnet is provided on the outside of the coil.

In addition, the ring permanent magnet is located inside the hollow part, which is a space formed in the center of the bobbin, and the upper surface of the bobbin is provided to be in contact with the lower surface of the plate.

The high voltage relay according to the present invention may include a ring permanent magnet in a fixed core to improve the actuation force of the actuator unit.

In addition, the high voltage relay according to the present invention has a ring permanent magnet positioned inside the hollow part of the bobbin and outside the coil wound on the bobbin without changing the shape of the bobbin, thereby making the diameter of the bobbin constant to prevent coil winding loss can do.

In addition to the above-described effects, the specific effects of the present invention will be described together while describing specific details for carrying out the invention below.

1 is an exploded perspective view of a high voltage relay according to the present invention.
2 is a schematic cross-sectional view of an actuator unit in a high voltage relay according to the present invention.
FIG. 3 is an enlarged cross-sectional view of a dotted line area of FIG. 2 .

The above-described objects, features and advantages will be described below in detail with reference to the accompanying drawings, and accordingly, those skilled in the art to which the present invention pertains will be able to easily implement the technical idea of the present invention. In describing the present invention, if it is determined that a detailed description of a known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to indicate the same or similar components.

1 is an exploded perspective view of a high voltage relay according to the present invention.

As shown in FIG. 1, the high voltage relay according to the present invention includes a contact unit 1000 for controlling the flow of current to the contact point, and an actuator unit 2000 for controlling the contact unit 1000 by an external power source. .

The contact unit 1000 contacts or separates the movable contact 1230 from the fixed contact 1120 under the control of the actuator unit 2000 to control the flow of current. To this end, the contact unit 1000 includes an arc chamber 1100 having a fixed contact 1120 and a moving moving contact 1230 provided in the arc chamber 1100 to operate the movable contact 1230 under the control of the actuator unit 2000 . an assembly 1200 , and an upper frame assembly 1300 accommodating the arc chamber 1100 .

The arc chamber 1100 is for energization and airtight maintenance, and includes a box-shaped ceramic chamber 1110 and a fixed contact 1120 fixed to the upper portion of the ceramic chamber 1110 . In addition, a cap plate 1140 sealing the lower edge opened when the ceramic chamber 1110 is assembled is included.

The ceramic chamber 1110 prevents an arc generated when the movable contact 1230 comes into contact with the fixed contact 1120 from being emitted to the outside. To this end, the ceramic chamber 1110 exemplifies the ceramic chamber 1110 which is a rectangular parallelepiped in which the region other than the lower portion is closed, that is, the lower portion is open. In addition, two holes spaced apart from each other are formed in the upper portion of the ceramic chamber 1110 so that the fixed contact 1120 is fixed. The open lower portion of the ceramic chamber 1110 is sealed by an arc protector 1260 to be described later, and a gas for arc extinguishing is filled in the sealed interior.

The fixed contact 1120 is fixed to the two holes formed in the upper portion of the ceramic chamber 1110 so that when the movable contact 1230 comes into contact, electricity is conducted. The fixed contact 1120 includes a first fixed contact 1121 and a second fixed contact 1122 provided in two holes formed in the ceramic chamber 1110, respectively, and a first fixed contact 1121 and a second fixed contact 1121 are provided. The fixed contact 1122 has an upper portion exposed to the outside and a lower portion exposed to the inside of the ceramic chamber 1110 . In addition, the fixed contact 1120 has a cylindrical shape, but is formed of a metal material so that the first fixed contact 1121 , the movable contact 1230 , and the second fixed contact 1122 are energized when the contact is in contact.

Meanwhile, a ring-shaped seal cap 1130 for airtight maintenance may be provided between the fixed contact 1120 and the ceramic chamber 1110 .

The cap plate 1140 closes and seals the open edge between the ceramic chamber 1110 and the plate 2230 . The cap plate 1140 is exemplified to have a rectangular loop shape with an open center, and is preferably made of metal and protrudes upward along the edge to be inserted into the inner edge of the ceramic chamber 1110 . In addition, a seal may be provided between the cap plate 1140 and the ceramic chamber 1110 to increase sealing force.

The moving assembly 1200 is moved by the actuator unit 2000 to conduct electricity between the first fixed contact 1121 and the second fixed contact 1122 . To this end, the moving assembly 1200 includes an upper yoke 1210, a magnetic body 1220 provided in the upper yoke 1210, a movable contact 1230, a lower yoke 1240, a contact spring 1250, an arc protector ( 1260 , and a shaft assembly 1270 .

The upper yoke 1210 is positioned above the movable contact 1230 and is fixed in position by a yoke holder 1271 to be described later. In addition, the upper yoke 1210 has a rectangular plate shape, and one side and the other side are fixed in contact with the upper one side and the upper other side of the yoke holder 1271 , respectively. The upper yoke 1210 may be made of metal, for example, nickel-plated iron. In addition, protrusions protruding upward are formed on one side and the other side of the upper surface of the upper yoke 1210 , and concave portions concavely formed are formed on one side and the other side of the lower surface. A recess 1211 is formed in the upper surface of the upper yoke 1210 so that a magnetic material 1220, which will be described later, is fitted. This embodiment illustrates a straight recess 1211 extending in the longitudinal direction of the movable contact 1230 into the recess 1211 . However, the present invention is not limited thereto, and the recess 1211 is formed such that a plurality of straight recesses 1211 spaced apart from each other are formed, or the recesses 1211 are formed to penetrate the side surface of the upper yoke 1210 . Thus, the magnetic material 1220 may not be exposed to the upper or lower portion of the upper yoke 1210 . Furthermore, the recess 1211 may be provided on the lower surface as well as the upper surface of the upper yoke 1210 , or may be provided on both the upper surface and the lower surface.

The magnetic body 1220 is provided in the recess 1211 of the upper yoke 1210 . The magnetic body 1220 illustrates that the upper yoke 1210 is formed in a shape corresponding to the recess 1211 so that the upper yoke 1210 is a hexahedron as a whole while being inserted into the recess 1211 of the upper yoke 1210 . That is, when the magnetic material 1220 is inserted into the recess 1211 of the upper yoke 1210, the upper surface of the magnetic material 1220 and the upper surface of the upper yoke 1210 are made to be the same surface without a step. However, the present invention is not limited thereto, and the upper surface of the magnetic material 1220 may protrude above the upper surface of the upper yoke 1210 . Meanwhile, in the present invention, the above-described magnetic material 1220 and the recess 1211 may be omitted.

The movable contact 1230 allows, for example, a current applied to the first fixed contact 1121 to flow to the second fixed contact 1122 through contact with the fixed contact 1120 . The movable contact 1230 is formed in a rectangular plate shape as a whole, and the thickness of the contact located on the left and right sides, that is, the region in contact with the fixed contact 1120 is thick. Accordingly, the movable contact 1230 includes the movable plate 1231 , the first contact 1232 and the second contact 1233 protruding upward from the left and right sides of the movable plate 1231 , respectively, and the movable plate 1231 . A central portion 1234 protruding from the central portion 1234 of and a central protrusion 1236 to which it engages.

The lower yoke 1240 increases the lifting force of the movable contact 1230 together with the upper yoke 1210 . To this end, the upper yoke 1210 is provided on the upper portion of the movable contact 1230 and the lower yoke 1240 is provided on the lower portion of the movable contact 1230 , and the upper yoke 1210 and the lower yoke 1240 are the movable contact points. It is formed to surround a direction crossing the longitudinal direction of the 1230 . Accordingly, the lower yoke 1240 illustrates that the front and rear are bent upwards in a 'U' shape. In addition, a yoke hole 1241 is formed in the center of the lower yoke 1240 , and a circular seating portion 1242 concave upward so that a contact spring 1250 to be described later is mounted is formed on the lower surface. The lower yoke 1240 is exemplified to be formed of the same material as the upper yoke 1210 .

The contact spring 1250 is to restore the position of the movable contact 1230, and the upper part is in contact with the seating part 1242 formed on the lower surface of the lower yoke 1240, and the lower part is in contact with the upper surface of the shaft body 1272. positioned to do In addition, the contact spring 1250 is exemplified in the form of a coil spring made of metal.

The arc protector 1260 prevents the arc generated when the fixed contact 1120 and the movable contact 1230 are in contact with each other from being discharged to the outside. To this end, the arc protector 1260 is provided to close the open lower portion of the ceramic chamber 1110, and the arc chamber 1100 for extinguishing the arc is formed. The arc protector 1260 includes a base plate 1261 , a first arc extinguishing chamber 1262 , a second arc extinguishing chamber 1263 , and a first arc extinguishing chamber 1262 respectively formed on one side and the other side of the base plate 1261 , and An opening 1264 formed to be opened between the second arc extinguishing chambers 1263 and a stopper 1265 extending inward from one side and the other side of the opening 1264 are included.

The base plate 1261 is formed in a rectangular plate shape to close the open lower portion of the ceramic chamber 1110 . A first arc extinguishing chamber 1262 is formed on one side of the upper surface of the base plate 1261 , and a second arc extinguishing chamber 1263 is formed on the other side of the upper surface of the base plate 1261 .

The first arc extinguishing chamber 1262 allows the arc generated when the first fixed contact 1121 and the movable contact 1230 to come into contact with each other. The first extinguishing chamber 1262 includes a first closed wall 1262a protruding from the upper surface of the base plate 1261 and a first open wall 1262b protruding from the other side wall of the first closed wall 1262a to one side wall. ) is included.

The first closing wall 1262a protrudes upward along one edge of the base plate 1261 , and is formed to surround one upper side of the base plate 1261 . In addition, the first closing wall 1262a is formed in a rectangular shape based on a plan view, the lower portion is closed by the base plate 1261 and the upper portion is open.

The first open wall 1262b is formed to divide the first closed wall 1262a into equal parts, but one side is open. Accordingly, the first arc extinguishing chamber 1262 is in the form of a single chamber with an open upper part, but one side is open across the middle, so that one space of the first arc extinguishing chamber 1262 communicates with the other space. Due to this structure, the arc generated when the first fixed contact 1121 and the movable contact 1230 are in contact is, for example, introduced into the work space of the first extinguishing chamber 1262, and when the work space is insufficient, the first opening It flows into another space through the open side of the wall 1262b. Accordingly, the arc generated when the first fixed contact 1121 and the movable contact 1230 are in contact is extinguished in the first extinguishing chamber 1262 . Preferably, the first fixed contact 1121 is positioned on the upper portion of the first open wall 1262b so that the arc can be introduced into the first extinguishing chamber 1262 .

The second arc extinguishing chamber 1263 allows the arc generated when the second fixed contact 1122 and the movable contact 1230 to come into contact with each other. The second extinguishing chamber 1263 includes a second closed wall 1263a and a second open wall 1263b, and the second closed wall 1263a is also formed to protrude upward from the other side of the upper surface of the base plate 1261 . do. In addition, the second opening wall 1263b is formed to protrude from one side of the second closing wall 1263a to the other side so as to communicate one space and the other space of the second arc extinguishing chamber 1263 so that the other side is opened. Accordingly, the arc generated when the second fixed contact 1122 and the movable contact 1230 contact is introduced into the second extinguishing chamber 1263 and extinguished. In addition, it is preferable that the second fixed contact 1122 is provided on the second closing wall 1263a.

The opening 1264 is formed between the first arc extinguishing chamber 1262 and the second arc extinguishing chamber 1263 and allows the shaft assembly 1270 to pass therethrough. That is, the shaft assembly 1270 is provided over the actuator unit 2000 and the arc chamber 1100 through the opening 1264 .

The stopper 1265 is formed on one side and the other side of the opening 1264 to prevent rotation of the shaft assembly 1270 , thereby regulating the rotation of the movable contact 1230 . The stopper 1265 includes a first stopper formed to protrude from one side of the opening 1264 and a second stopper formed to protrude from the other side of the opening 1264 . Of course, in the present invention, the above-described stopper 1265 may be omitted, and in this case, it is preferable that the groove portion into which the stopper 1265 is fitted is also omitted.

The shaft assembly 1270 allows the movable contact 1230 to reciprocate up and down by the actuator unit 2000 . The shaft assembly 1270 includes a yoke holder 1271 to which the upper yoke 1210 is fixed, a shaft body 1272 to which the yoke holder 1271 is fixed, and a shaft fixed to the lower portion of the shaft body 1272 . (1273).

The yoke holder 1271 fixes the upper yoke 1210, the lower yoke 1240, and the movable contact 1230, and the upper part directly fixes the upper yoke 1210 and the lower part is fixed to the upper part of the shaft body 1272. do. The yoke holder 1271 includes a first yoke holder 1271a for directly fixing the upper yoke 1210, and a second yoke holder 1271b coupled to the first yoke holder 1271a and fixed to the shaft body 1272. ) is included.

The first yoke holder 1271a is formed in an 'n' shape to surround the upper yoke 1210 from the top, and four legs are formed at the bottom to be coupled to the second yoke holder 1271b. In addition, the four legs are formed to extend downward in a flat shape, and are formed two by two on both sides of the upper yoke 1210 to illustrate that they are in contact with the side surfaces of the upper yoke 1210 .

The second yoke holder 1271b fixes the first yoke holder 1271a to the shaft body 1272 . To this end, the second yoke holder 1271b is formed in a 'u' shape, and the upper portion of the open second yoke holder 1271b is coupled to the four legs of the first yoke holder 1271a and the upper portion. In addition, the second yoke holder 1271b includes four legs protruding upward in order to be coupled with the four legs of the first yoke holder 1271a. Here, the second yoke holder 1271b is bisected to include two legs, and accordingly, the second yoke holder 1271b has a bisected end fixed to one side of the shaft body 1272 and the other end is a shaft body ( 1272) and are electrically insulated from each other. Here, the present invention may allow the above-described yoke holder 1271 to be integrally formed without being separated into the first yoke holder 1271a and the second yoke holder 1271b.

The shaft body 1272 fixes the yoke holder 1271 and the shaft 1273 but electrically insulates them from each other and prevents rotation of the movable contact 1230 . To this end, the shaft body 1272 has a generally cylindrical shape, and an anti-separation protrusion is formed on the upper surface to support the lower portion of the contact spring 1250 to prevent separation. The separation preventing protrusion includes an intermediate protrusion supporting the inside of the contact spring 1250 and an external protrusion supporting the outside of the contact spring 1250 . In addition, the middle protrusion has a cylindrical shape, and the outer protrusion is formed in an arc shape to correspond to the outer shape of the contact spring 1250 . In addition, a groove portion coupled to the stopper 1265 is formed in the shaft body 1272 to prevent rotation of the movable contact 1230 , and the groove portion includes a first groove portion corresponding to the first stopper and a second groove portion corresponding to the second stopper. Includes 2 grooves.

The shaft 1273 is connected to the lower portion of the shaft body 1272 and ascends or descends on the actuator unit 2000 . The shaft 1273 is formed in the shape of a rod, and the upper part is connected to the shaft body 1272 and the lower part is connected to the movable core 2400 .

The upper frame assembly 1300 is provided to cover the arc chamber 1100 to protect the arc chamber 1100 and extinguish an arc generated in the arc chamber 1100 . To implement this, the upper frame assembly 1300 includes a magnet 1310 , a magnet holder 1320 , and an upper frame 1330 .

The magnet 1310 is for extinguishing the arc generated in the ceramic chamber 1110 with a magnetic field, and is formed on one side and the other side outside the ceramic chamber 1110 . Accordingly, the magnet 1310 includes a first magnet 1311 provided on one side outside the ceramic chamber 1110 and a second magnet 1312 provided on the other side outside the ceramic chamber 1110 . In addition, this embodiment exemplifies that the magnet 1310 has a square plate shape, and accordingly, one side and the other side of the magnet 1310 have different poles from each other. Here, the present embodiment illustrates that one side of the first magnet 1311 is an S pole and the other side is an N pole, and the second magnet 1312 also illustrates that one side is an S pole and the other side is an N pole. Accordingly, the other side of the first magnet 1311 adjacent to the ceramic chamber 1110 is an N pole, and one side of the second magnet 1312 adjacent to the ceramic chamber 1110 is an S pole. Of course, the magnet 1310 may be omitted.

The magnet holder 1320 is provided to surround the magnet 1310 to prevent and protect the magnet 1310 from being separated. The magnet holder 1320 is coupled to the upper frame 1330 so that the edges protrude and bend to support the upper portion of the magnet 1310 . In addition, the magnet holder 1320 may be separated into two and spaced apart.

The upper frame 1330 is provided to cover the arc chamber 1100 and the magnet holder 1320 to protect the arc chamber 1100 , the magnet holder 1320 , and the magnet 1310 . The upper frame 1330 has a generally rectangular box shape with an open lower portion, and a terminal exposure hole is formed in the upper portion to expose the fixed terminals. In addition, the upper frame 1330 is preferably formed of an insulator, for example, a resin. A hook 1331 coupled to a lower frame 2800 to be described later is formed on the lower edge of the upper frame 1330, and in this embodiment, four hooks, that is, a first hook and a second hook, a third hook, and a third hook are formed. 4 illustrates that the hook is formed. In addition, the front surface of the upper frame 1330 in which the first hook and the second hook are formed has a length longer than the rear surface in which the third hook and the fourth hook are formed. Of course, the lower frame 2800, which will be described later, is formed so that the length of the front surface is shorter than the length of the rear surface.

2 is a schematic cross-sectional view of an actuator unit in a high voltage relay according to the present invention.

The actuator unit 2000 controls the contact unit 1000 by an external power source. As shown in FIGS. 1 and 2, the actuator unit 2000 includes a coil 2120 assembly 2100 that generates a magnetic field by an external power source, and the coil 2120 assembly 2100. A path of the magnetic field generated in the assembly 2100 The yoke 2210 and the yoke ring 2220 and the plate 2230 to form, the fixed core 2300 magnetized by a magnetic field, the ring permanent magnet 2900 provided at the edge of the fixed core 2300, the fixed core 2300 ), the movable core 2400 that rises or descends by the repulsive force with the, the return spring 2500 provided between the fixed core 2300 and the movable core 2400, the fixed core 2300 and the movable core 2400 and the return spring A cylinder 2600 for accommodating 2500, a terminal 2700 for applying external power to the coil 2120 assembly 2100, and a lower frame 2800 for accommodating them and coupled to the upper frame 1330. .

Coil 2120 The assembly 2100 receives external power to generate a magnetic field, and includes a bobbin 2110 and a coil 2120 wound around the bobbin 2110 .

The bobbin 2110 has a hollow cylindrical shape, and the upper and lower edges are extended to the side so that the coil 2120 wound on the side does not deviate to the upper or lower portion, so that it has an 'I' shape based on the side view.

The coil 2120 is wound around the bobbin 2110 to generate a magnetic field when an external power is applied. The coil 2120 is connected to the terminal 2700 , and the terminal 2700 is exposed to the outside to receive external power.

The yoke 2210 is for forming a path for the magnetic field generated by the coil 2120, and in the form of a 'U' with the top, front, and back open to surround the side and bottom of the coil 2120 assembly 2100. is formed The yoke 2210 is made of a metal such as iron, and a coupling hole 2211 to which the yoke ring 2220 is coupled is formed at a lower portion thereof.

The lower portion of the yoke ring 2220 is fitted into the coupling hole 2211 formed in the lower portion of the yoke 2210 , and forms a magnetic field path together with the yoke 2210 . In addition, the yoke ring 2220 is formed in a hollow cylindrical shape with one side spaced apart, and the material thereof is the same as that of the yoke 2210 . The lower portion of the cylinder 2600 to be described later is fitted inside the yoke ring 2220 .

The cylinder 2600 has a movable core 2400 , a fixed core 2300 , and a return spring 2500 housed therein. The cylinder 2600 has a hollow cylindrical shape with a closed lower portion and an open upper portion, and the upper edge is bent and extended to the outer surface. The cylinder 2600 may be made of metal, for example, stainless steel.

The plate 2230 is provided on the upper portion of the yoke 2210 and the lower portion of the arc protector 1260 to form a magnetic field path together with the yoke 2210 . The plate 2230 is made of metal, and the present embodiment exemplifies the plate 2230 in the shape of a square plate. In addition, a center hole 2231 is formed in the center of the plate 2230 to allow the shaft 1273 to pass therethrough.

FIG. 3 is an enlarged cross-sectional view of a dotted line area of FIG. 2 .

The fixed core 2300 is formed in a cylindrical shape and is fixed to the inside of the cylinder 2600 . The fixed core 2300 may be made of a metal such as iron to be magnetized by the magnetic field of the coil 2120 . Here, referring to FIGS. 2 and 3 , the fixed core 2300 has an upper portion inserted into the center hole 2231 of the plate 2230 and a ring permanent magnet 2900 is fitted in the middle, for this purpose, the fixed core ( 2300 includes a first fixed core portion 2310 having a disk shape, and a second fixed core portion extending over the first fixed core portion 2310 and having a disk shape but having a smaller diameter than the first fixed core portion 2310 . 2320 , and a third fixed core part 2330 extending over the second fixed core part 2320 and having a disk shape and having a smaller diameter than the second fixed core part 2320 . In addition, the third fixed core part 2330 is inserted and fixed into the center hole 2231 of the plate 2230 , and the second fixed core part 2320 and the third fixed core part 2330 are the cylinder 2600 . stored at the top.

The ring permanent magnet 2900 is for reinforcing the magnetic force of the fixed core 2300 , and is positioned so as to be in contact with the third fixed core part 2330 , the upper edge of the edge, and the side surfaces of the second fixed core part 2320 . This embodiment illustrates that the cross-section of the ring permanent magnet 2900 is rectangular. Accordingly, the lower surface of the ring permanent magnet 2900 is in contact with the first fixed core portion 2310 and the upper surface of the edge, and the inner surface of the ring permanent magnet 2900 is in contact with the side surface of the second fixed core portion 2320 . . In addition, the width of the ring permanent magnet 2900 is the same as the width of the upper surface of the first fixed core portion 2310 and the edge, and the thickness of the ring permanent magnet 2900 is the same as the thickness of the second fixed core portion 2320 . exemplify that Accordingly, when the ring permanent magnet 2900 is mounted on the fixed core 2300 , the diameter of the first fixed core part 2310 is the same as the diameter of the second fixed core part 2320 into which the ring permanent magnet 2900 is fitted. will do The ring permanent magnet 2900 is positioned outside the coil 2120 , and is positioned between the plate 2230 and the first fixed core part 2310 . In addition, the ring permanent magnet 2900 is located inside the hollow part, which is a space formed in the center of the bobbin.

By the above-described fixed core 2300 and the ring permanent magnet 2900, the present invention can improve the actuation force of the actuator unit. In addition, by locating the ring permanent magnet on the fixed core without forming it on the bobbin, the diameter of the bobbin is made constant, thereby preventing loss of the coil winding.

The movable core 2400 is formed in a cylindrical shape and rises or falls depending on whether external power is applied to the coil 2120 . For example, when external power is applied to the coil 2120 , the fixed core 2300 is magnetized by the magnetic field of the coil 2120 , and the movable core 2400 rises by the repulsive force. In addition, if external power is not applied to the coil 2120 in a state in which the movable core 2400 is raised, the movable core 2400 is descended. The upper portion of the movable core 2400 is positioned so that the lower portion of the shaft 1273 is in contact, and accordingly, when the movable core 2400 rises, the shaft 1273 also rises.

The return spring 2500 is provided between the fixed core 2300 and the movable core 2400 to return the movable core 2400 . To this end, it is preferable that concave seating recesses are respectively formed on the upper surface of the fixed core 2300 and the lower surface of the movable core 2400 so that the return spring 2500 is seated.

The lower frame 2800 includes a coil 2120 assembly 2100 and a yoke 2210, a yoke ring 2220, a plate 2230, a fixed core 2300, a movable core 2400, a return spring 2500, The cylinder 2600 and the terminal 2700 are accommodated and protected. To this end, the lower frame 2800 is formed in the form of a box with an open upper portion, and is coupled to the upper frame 1330 by accommodating the components of the actuator unit 2000 described above therein. In addition, the lower frame 2800 has a fastening hole 2810 formed to be fastened with the hook 1331 of the upper frame 1330 described above, and since the above-described hook 1331 includes four hooks, the fastening hole 2810 also exemplifies that it includes four fastening holes, that is, a first fastening hole, a second fastening hole, a third fastening hole, and a fourth fastening hole.

As described above, the present invention can improve the operating force of the actuator unit by providing a ring permanent magnet in the fixed core. In addition, by providing the ring permanent magnet to be located inside the bobbin hollow part and outside the coil wound on the bobbin without changing the shape of the bobbin, it is possible to prevent coil winding loss by making the diameter of the bobbin constant.

As described above, the present invention has been described with reference to the illustrated drawings, but the present invention is not limited by the embodiments and drawings disclosed in the present specification. It is obvious that variations can be made. In addition, although the effects according to the configuration of the present invention are not explicitly described and described while describing the embodiments of the present invention, it is natural that the effects predictable by the configuration should also be recognized.

1000: contact 1100: arc chamber
1110: ceramic chamber 1120: fixed contact
1121: first fixed contact 1122: second fixed contact
1130: seal cap 1140: cap plate
1200: moving assembly 1210: upper yoke
1211: recess 1220: magnetic body
1230: movable contact 1231: movable plate
1232: first contact 1233: second contact
1234: central 1235: concave
1236: central projection 1240: lower yoke
1241: yoke hole 1242: seating part
1250: contact spring 1260: arc protector
1261: base plate 1262: first extinguishing chamber
1262a: first closed wall 1262b: first open wall
1263: second extinguishing chamber 1263a: second closed wall
1263b: second opening wall 1264: opening
1265: stopper 1265a: first stopper
1265b: second stopper 1270: shaft assembly
1271: yoke holder 1271a: first yoke holder
1271b: second yoke holder 1272: shaft body
1273: shaft 1300: upper frame assembly
1310: magnet 1311: first magnet
1312: second magnet 1320: magnet holder
1330: upper frame 1331: hook
2000: actuator unit 2100: coil assembly
2110: bobbin 2120: coil
2210: yoke 2211: mating hole
2220: yoke ring 2230: plate
2231: center hole 2300: fixed core
2310: first fixed core portion 2320: second fixed core portion
2330: third fixed core part 2400: movable core
2500: return spring 2600: cylinder
2700: terminal 2800: lower frame
2810: fastening hole 2900: ring permanent magnet

Claims (5)

A high voltage relay comprising a pair of fixed contacts, a contact portion including a movable contact in contact with the pair of fixed contacts, and an actuator portion for controlling the movable contact to contact the pair of fixed contacts,
The actuator unit,
A coil assembly in which a coil is wound on a bobbin;
a plate provided between the contact part and the coil assembly;
A fixed core having an upper portion fitted to the plate and having a stepped side surface formed in multiple stages;
A high voltage relay comprising a ring permanent magnet fitted to the fixed core.
The method of claim 1,
The fixed core may include a first fixed core part positioned inside a hollow part, which is a space formed in the center of the bobbin, and a second fixed core part protruding from an upper portion of the first fixed core part and having a smaller diameter than the first fixed core part. comprising a fixed core,
A lower surface of the ring permanent magnet is in contact with an upper edge of the first fixed core part, and an inner surface of the ring permanent magnet is in contact with an outer surface of the second fixed core part.
3. The method of claim 2,
The coil is wound on the outer surface of the bobbin having a constant diameter,
The ring permanent magnet is a high voltage relay provided outside the coil.
4. The method of claim 3,
The ring permanent magnet is a high voltage relay located inside a hollow part that is a space formed in the center of the bobbin.
5. The method of claim 4,
The upper surface of the bobbin is in contact with the lower surface of the plate.

Images