KR101346086B1 - Relay - Google Patents

Abstract

The present invention relates to a relay, and in particular, the operation voltage for the relay operation to maintain the relay state on or off with a short pulse current without changing the polarity, and in the event of an electrical signal such as a solenoid control device, the movable portion of the latch relay itself The relay can be operated by manual operation, and the contact structure is related to a latch relay having a structure that is small and suitable for supplying large power.
To this end, the present invention
A bobbin mounted with a solenoid, having a plurality of guide grooves formed in a vertical length direction at predetermined intervals, and having a rack groove portion formed between the guide grooves; A first movable piece formed of a magnetic material and inserted into the bobbin and mounted to have an upper side exposed to an upper side of the bobbin while having a downward elastic force by a spring; It is mounted on the lower side of the first movable piece, the latch is formed on the upper side and latch coupled to the rack groove portion of the bobbin, the outer electrode is formed along the outer circumference and the inner electrode groove is formed on the lower inner side, by a spring A second movable piece having an upward elastic force; A holder accommodating and supporting while exposing the lower side of the second movable piece; The cabinet is coupled to the outside of the bobbin while accommodating the holder, the inner side of the cabinet is formed with an insertion electrode which is inserted into the outer fixed electrode and the inner electrode groove in contact with the external electrode with an elastic force during the downward movement of the second movable piece; do.

Description

Relay {Relay}

The present invention relates to a relay, and in particular, the operation voltage for the relay operation to maintain the relay state on or off with a short pulse current without changing the polarity, and in the event of an electrical signal such as a solenoid control device, the movable portion of the latch relay itself The relay can be operated by manual operation, and the contact structure relates to a relay having a structure that is small and suitable for supplying large power.

Typically, all power and electronic devices have complex control circuits for operation and control of the device, and relays are used to turn the power supply on and off at the final output stage.

This general relay is used when the solenoid is excited and the case of the bias is used as the electrical contact signal using the mechanical state change of the contact, this method is widely used as a representative method of the commonly used relay.

However, the disadvantage of this method is that the solenoid consumes power energy to maintain the excitation state in order to maintain one state.

In addition, even when a temporary abnormality such as a momentary power failure of the relay control power system occurs, an undesired state change is required and the on signal is required again to restart.

In addition, when the power system is normal and a failure occurs in the control power system, the operation is impossible because the operation of the power equipment is inevitable.

Therefore, a latch relay is used to solve such shortcomings such as energy consumption. The operation is a combination of a permanent magnet and an electromagnet. The operation of the solenoid coil changes the polarity of the solenoid coil in the case of one solenoid type to realize a state change. In case of changing state by installing two solenoids, control power is supplied only to the corresponding electromagnet.

However, the power system is normal and the operation of the power equipment is inevitable because the operation is impossible when the control power system is abnormal.

Therefore, the improvement of the control circuit of the relay and the latch relay is necessary to prevent unnecessary energy consumption and to supply a relay that can be operated manually in an emergency.

Therefore, the present invention is to solve the conventional problems, the guide groove is formed in the solenoid bobbin to move the movable piece at a constant angle, the first movable piece in the bobbin is subjected to electromagnetic force to the hollow solenoid so that the traveling distance of the movable piece to the maximum It is arranged to move straight along the guide groove, and in addition to the movement of the first movable piece is configured to enable the rotary motion after going straight at a certain angle and the maximum change in position caused by the linear movement of the first and second movable pieces The relay configured so that the contact portion of the second movable piece and the contact portion of the fixed electrode are sufficiently inserted so that the output contact is turned on / off irrespective of the disadvantage that it is impossible to apply to the relay due to the occurrence of the rack return distance caused by the characteristics of the rack structure. The purpose is to provide.

In addition, one side of the first movable piece protrudes to the outside of the bobbin to enable manual operation and locking is to double the convenience and stability of the system to the operator.

In addition, regardless of the polarity of the control power supply, once the control pulse is turned on, the on / off state changes, and even if the control power supply is removed, the state is maintained so that the control can be easily applied to various power and electronic devices. Its purpose is to construct.

The relay of the present invention for achieving the above object,

A bobbin mounted with a solenoid, having a plurality of guide grooves formed in a vertical length direction at predetermined intervals, and having a rack groove portion formed between the guide grooves;

A first movable piece formed of a magnetic material and inserted into the bobbin and mounted to have an upper side exposed to an upper side of the bobbin while having a downward elastic force by a spring;

It is mounted on the lower side of the first movable piece, the latch is formed on the upper side and latch coupled to the rack groove portion of the bobbin, the outer electrode is formed along the outer circumference and the inner electrode groove is formed on the lower inner side, by a spring A second movable piece having an upward elastic force;

A holder accommodating and supporting while exposing the lower side of the second movable piece;

The cabinet is coupled to the outside of the bobbin while accommodating the holder, the inner side of the cabinet is formed with an insertion electrode which is inserted into the outer fixed electrode and the inner electrode groove in contact with the external electrode with an elastic force during the downward movement of the second movable piece; do.

This invention has the following effects.

1. The contact structure is simple and small, which is advantageous for high current

2. As relay has manual operation function, it is possible to continue operation of the load facility even when the relay control circuit system has an error, and it is easy to check the contact status of the relay with the naked eye.

3. Easy to mass production and small number of parts due to molding structure, simple assembly process and uniform product quality.

4. It is not necessary to change the polarity of control power, so the structure is simple and the relay control circuit is simple, so when developing power and electronic products, it has cost reduction effect.

1 is an exploded assembly view of a relay according to the present invention.
Figure 2 is an assembled view of the relay off state according to the present invention.
Figure 3 is an assembled view of the relay on state according to the present invention.
Figure 4 is a view showing a planar structure of the bobbin 100, the first movable piece 200, the second movable piece 300.
5 is a structural diagram of a relay manual locking device according to the present invention.

The present invention configured as described above will be described in detail with reference to the accompanying drawings.

1 is an assembly view showing a relay capable of manual operation of the present invention, Figure 2 is an assembly view showing the relay is off, Figure 3 is an assembly view showing the on state of the relay.

The present invention largely has a structure of the bobbin 100, the first movable piece 200, the second movable piece 300, the holder 4000, the cabinet 500.

The bobbin 100 is formed in a cylindrical shape of the upper end is blocked and the lower side is open, the first movable piece exposed hole 150 is formed at the upper end, the solenoid 110 is installed at the outer circumference, the inner wall surface As shown in Fig. 4 (a), a plurality of guide grooves 120 are formed in the longitudinal direction at regular intervals from the upper side to the lower side.

At this time, two rack grooves 140 are formed in the middle portion of the inner wall surface of the bobbin 100 between the guide grooves 120 adjacent to each other, and one rack groove 141 has a short length and another one. The rack groove 142 is formed long in length.

The first movable piece 200 is in the form of a rod of ferromagnetic material, is inserted into the bobbin 100, the lower jaw 210 is formed in the lateral direction as shown in Figure 4 (b), The outer periphery of the jaw portion 210 is formed with protrusions 220 protruding at positions corresponding to the plurality of guide grooves 120, respectively, and have a size to be inserted into the guide grooves 120.

Therefore, the first movable piece 200 is inserted into the bobbin 100 so that the protrusion 220 moves up and down in the guide groove 120.

In addition, a first spring 230 having a coil spring shape is inserted into the first movable piece 200 from the upper side thereof and is caught by the expansion unit 210.

The upper portion of the first movable piece 200 is mounted to be exposed through the first movable piece exposed hole 150 of the bobbin 100.

The second movable piece 300 is in the form of a rod of nonmagnetic material, and has an extended portion 310 extending laterally around the upper side, and the outer side of the extended portion 310 in FIG. 4 (c). The latch 320 is formed as shown.

Then, the second spring 350 is inserted from the lower side of the second movable piece 300 to be fitted to the extension 310, and the upper end of the extension 310 is the lower end of the first movable piece 200. Mounted in contact with the

In addition, an outer electrode 330 is formed to surround the outer side of the second movable piece 300 so as to surround the outer side, and an inner electrode groove 340 is formed at the lower inner side thereof.

The holder 400 is open at the upper side, and an exposure hole 410 for exposing the second movable piece 300 is formed at the bottom, and the bobbin 100 is received in a state in which the second movable piece 300 is accommodated. It is combined with each other while wrapping on the lower side.

The cabinet 500 is mounted to surround the outside of the bobbin 100 on which the holder 400 is mounted, and the external fixed electrode 510 for contacting the external electrode 330 of the second movable piece 300 inside the cabinet 500. An insertion electrode 520 is formed to be inserted into the internal electrode groove 340.

The external fixed electrode 510 is manufactured by plating with a mixture of brass and silver as an arcuate structure to generate a spring compression force.

The structure of the latch 320 of the rack groove 140 and the second movable piece 300 mentioned above is already a generalized technology.

The operation state of the present invention will be described.

When the control signal of the 100 kHz pulse is input once to the solenoid 110 in the relay off state of FIG. 2, the first movable piece 200 follows the guide groove 120 in the bobbin 100 by an electromagnetic force as shown in FIG. 3. It is sucked and moved to the lower side, and the second movable piece 300 is also moved along the guide groove 120 in the bobbin 100 as the first movable piece 200 moves downward to compress the force of the external fixed electrode 510. The insertion electrode 520 is inserted into the internal electrode groove 340 as well as being inserted.

Accordingly, the relay is turned on by energizing the external classical electrode 510 and the insertion electrode 520 by the external electrode 330 and the internal electrode groove 340 of the second movable piece 300.

At this time, the latch 320 of the second movable piece 300 which is moved downward along the guide groove 120 rotates along the rack groove 141 at the position of the rack groove 140 to the second rack groove 142. By being caught, even if the control power is removed from the solenoid 110, the on state is maintained.

In addition, since the external electrode 330 surrounds all of the outside of the second movable piece 300, the external electrode 330 maintains the connected state even when the second movable piece 330 rotates.

When another control signal is input to the solenoid 110 when the relay is turned off, the first movable piece 200 moves downward to press the second movable piece 300, which causes the second movable piece 300 to move. The latch 320 is moved by the elastic force of the second spring 350 by moving toward the guide groove 120 along the rack groove 142.

As a result, as shown in FIG. 2, the second movable piece 300 completely turns off the external fixed electrode 510 and the insertion electrode 520 to turn off the relay.

As a result, according to the length of the guide groove 120 and the position of the rack groove 140, the second movable piece 300 is stably connected to the external fixed electrode 510 and the insertion electrode 520 or completely separated, thereby causing an electrical contact problem. Can be solved.

On the other hand, the first spring 230 is set to a weaker elastic force than the second spring 350, so that the second movable piece 300 rises and returns to overcome the elastic force of the first spring 230, the first spring 230 ) Is for preventing the mechanical shock and noise caused by the return of the first movable piece (200).

In the case of manual operation, when the first movable piece 200 is pressed once, the first movable piece 200 is turned on by the latch function described above, and when pressed once more, it is switched off. It is unnecessary.

In addition, in the case of a relay without a latch function, as shown in FIG. 5, the latch 320 of the second movable piece 300 is deleted, and the fixing hole 240 penetrates laterally to the upper side of the first movable piece 200. ) And a through hole 130 penetrated in the transverse direction from the upper side of the bobbin 100 may be formed.

Therefore, the first movable piece 200 is pressed and then the fixing hole 240 and the penetration hole 130 in the state in which the fixing pin 160 is inserted to maintain the on state, the fixing pin 160 ) Is removed again by the second spring 350, the relay is off.

100: 110: solenoid
120: guide groove 130: through hole
140: rack groove 150: first movable piece exposed hole
160: fixed pin
200: first movable piece 210: jaw portion
220: protrusion 230: first spring
240: fixing hole 300: second movable piece
310: expansion unit 320: latch
330: external electrode 340: internal electrode groove
350: second spring 400: holder
410: exposure hole 500: cabinet
510: external fixed electrode 520: insertion electrode

Claims (2)

A bobbin mounted with a solenoid, having a plurality of guide grooves formed in a vertical length direction at predetermined intervals, and having a rack groove portion formed between the guide grooves;
A first movable piece formed of a magnetic material and inserted into the bobbin and mounted to have an upper side exposed to an upper side of the bobbin while having a downward elastic force by a spring;
It is mounted on the lower side of the first movable piece, the latch is formed on the upper side and latch coupled to the rack groove portion of the bobbin, the outer electrode is formed along the outer circumference and the inner electrode groove is formed on the lower inner side, by a spring A second movable piece having an upward elastic force;
A holder accommodating and supporting while exposing the lower side of the second movable piece;
The cabinet is coupled to the outside of the bobbin while accommodating the holder, the inner side of the cabinet is formed with an insertion electrode which is inserted into the outer fixed electrode and the inner electrode groove in contact with the external electrode with an elastic force during the downward movement of the second movable piece; Relay, characterized in that.
A solenoid is mounted, and a plurality of guide grooves formed in a vertical length direction at predetermined intervals are formed therein, and an bobbin having a through-hole penetrated in an upper direction thereof;
A first movable piece formed of a magnetic material and inserted into an inside of the bobbin, having a downward elastic force by a spring, and having an upper side exposed to an upper side of the bobbin, and having a fixing hole vertically penetrating thereon;
A second movable piece mounted below the first movable piece, having an external electrode formed along an outer circumference thereof, and having an inner electrode groove formed at a lower side thereof and having an upward elastic force by a spring;
A fixing pin for fixing the second movable piece by inserting it into the through-hole of the bobbin and the fixing hole of the first movable piece;
A holder accommodating and supporting while exposing the lower side of the second movable piece;
The cabinet is coupled to the outside of the bobbin while accommodating the holder, the inner side of the cabinet is formed with an insertion electrode which is inserted into the outer fixed electrode and the inner electrode groove in contact with the external electrode with an elastic force during the downward movement of the second movable piece; Relay, characterized in that.

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