KR20160147183A - Magnetic contactor driven permament magnet and one-coil and current conversion apparatus - Google Patents

Abstract

The present invention relates to a magnetic contactor driven by a coil, a current switching unit, and a permanent magnet, which simplifies the structure thereof as a capacitor for driving a coil is not required by driving a movable contact through the operation of a coil using an external power source, and prevents malfunction caused by the failure of the capacitor.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a magnetic contactor driven by a single coil, a current direction switching means and a permanent magnet,

[0001] The present invention relates to an electromagnetic contactor, and more particularly to an electromagnetic contactor that operates a coil by a control power source when the electromagnetic contactor is turned on to drive a movable contactor and maintains a connection using a permanent magnet, The present invention relates to an electromagnetic contactor that is driven by a coil, current direction switching means, and permanent magnet, which operates a coil by an external power source and interrupts contact by elasticity of a spring.

Generally, an electromagnetic contactor is a device that causes an operating body to open and close a circuit, and is used for controlling various switching devices such as a motor, a welding machine, and a transformer.

The conventional electromagnetic contactor typically includes a fixed contact connected to a power source side and a load side, a fixed contact connected to one side of the fixed contacts, And when a current is applied to the coil of the electromagnet, a magnetic force is generated, and the movable contact moves to the fixed contacts, and the fixed contacts are brought into contact with each other by the movable contact to make electrical connection (input). In this state, when the current flowing through the coil is cut off, the magnetic force extinguishes in the fixed iron core, and the movable iron core is pushed by the repulsive force of the spring to return to the original position. As a result, the movable contactor, The connection between the fixed contacts is disconnected (opened).

Such a conventional electromagnetic contactor requires a constant current to be applied to the coil to keep the contact state of the contactor after the closing operation. As a result, they were susceptible to heat, vibration, noise, high power consumption, and momentary power failure.

Patent literatures 4 and 5 are techniques developed to overcome such disadvantages.

Patent Literatures 4 and 5 are permanent magnet type electromagnetic contactors. As shown in Fig. 5, permanent magnets 200 are provided on the rod 100r of the movable contactor 100m, And includes an input coil 400 and an open coil 500. When the power supply is applied to the input coil 400, the permanent magnet is pulled to move the movable contact to contact the fixed terminal 100f to connect the two fixed contacts. When the two fixed contacts are connected, the power supplied to the input coil is cut off The permanent magnets are fixed to the fixed iron core by the magnetic force of the permanent magnets, so that the two fixed contacts maintain the connection state by the movable contacts.

Conversely, when the movable contact is separated from the two fixed contacts, when power is supplied to the open coil 500, the permanent magnet 200 is pushed out to separate the permanent magnet from the fixed core 300 and the movable contact 100m The two fixed contacts 100f are disconnected from the two fixed contacts 100f by the jamming so that the two fixed contacts 100f are electrically disconnected from each other.

As shown in FIG. 6, the conventional permanent magnet type electromagnetic contactor includes switches S1 and S2 for interrupting power supplied to the input coil and the open coil, respectively, and supplies power to the open coil A capacitor C is provided.

That is, at the time of charging, the switch S1 is turned on and the switch S2 is turned off to apply the constant power source to operate the charging coil Lc and charge the capacitor C, and when the switch S1 is open, the switch S1 is turned off The switch S2 is turned on to operate the open coil Lo using the power stored in the capacitor C charged in the closing operation.

However, since the capacitor element provided for driving the open coil has a limited life span and is greatly influenced by the external environment, the actual electric-related industrial site may become a harsh environment such as heat or moisture. In such a circumstance, There is a problem that the control circuit having the element frequently fails and the electromagnetic contactor can not normally operate.

In addition, there is a disadvantage that the structure is complicated because it is constituted by using two coils.

1. Korean Patent Registration No. 0333935 2. Korean Patent Publication No. 1985-0006963 3. Korean Patent Registration No. 0025834 4. Korean Patent Registration No. 0899432 5. Korea Patent No. 1274340

SUMMARY OF THE INVENTION It is an object of the present invention to provide an electromagnetic contactor that is driven by a permanent magnet and one coil that is simplified in configuration of the control circuit to reduce the failure rate and less affected by the environment .

Further, there is provided a magnetic contactor which is driven by a permanent magnet and one coil, which enables the contact to be opened and closed by one coil by switching a current direction by operating a coil using an external power source, .

In order to achieve the above object, there is provided an electromagnetic contactor driven by one coil and a permanent magnet according to the present invention includes a load side fixed contact connected to a load, a power source side fixed contact connected to an external power source, Wherein a permanent magnet is provided on one side of the movable contact, a coil is provided on one side of the permanent magnet, and a switching circuit for switching a direction of a current supplied to the coil And the switching circuit is switched to the direction of the current supplied to the coils by the switching circuit so that the magnetic field generated in the coils is formed in the pulling direction of the permanent magnets so that the permanent magnets are pulled, When the power is cut off, the magnetic field generated in the coil is applied by the permanent magnet to the permanent magnet. And the movable contact is separated from the fixed contacts by the pushing of the permanent magnet so that the contact between the load side fixed contact and the power source side fixed contact is cut off.

Preferably, a switch is further provided at one side of the coil to cut off the power supplied to the coil when power is supplied to the coil and the permanent magnet is pulled or pushed.

The switching circuit may be modified in various ways, but preferred examples thereof include two diodes that rectify electricity input from one power source and supply currents in different directions to the coils, or alternatively, And two current rectifying circuits for rectifying the currents and supplying currents in different directions to the coils.

As described above, the electromagnetic contactor driven by one coil and the permanent magnet according to the present invention restricts the driving of the movable contactor by using the permanent magnet, so that a separate power source is supplied Not only can the driving of the electromagnetic contactor be stably controlled but also an external power source is used as a power source for driving the coils so that a charging circuit such as a capacitor is not provided inside the electromagnetic contactor, It is possible to prevent a malfunction due to the external environment of the battery or the aging of the charging circuit, and to reduce the occurrence of a failure.

1 is a configuration diagram of an electromagnetic contactor driven by one coil and a permanent magnet according to the present invention;
2 is an example of a coil power switching circuit constituting an electromagnetic contactor driven by one coil and a permanent magnet according to the present invention
3 is a view showing another example of the coil power switching circuit constituting the electromagnetic contactor driven by one coil and the permanent magnet according to the present invention
4 is a cross-sectional view of an example of an electromagnetic contactor driven by one coil and a permanent magnet according to the present invention
5 is a cross-sectional view of one example of a conventional electromagnetic contactor
Fig. 6 is a circuit diagram of a conventional electromagnetic contactor driving circuit

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

Like reference numerals are used for like elements in describing each drawing. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

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

The present invention has a permanent magnet so as not to supply power when the power is turned on or off. The permanent magnet can be pushed or pulled by only one coil, and the coil can be operated using an external power source, A charging circuit such as a capacitor is not provided to simplify the configuration of the electromagnetic contactor, reduce the cause of failure, and be less influenced by the environment.

The electromagnetic contactor driven by one coil and the permanent magnet according to the present invention includes a load side fixed contact 10r connected to a load, a power source side fixed contact 10e connected to a commercial power source, A permanent magnet 30 mounted on a rod 20r extending from the movable contact and a coil for moving the movable contact 20 in cooperation with the permanent magnet 30 40).

The electromagnetic contactor magnetizes the coil by supplying power to the coil 40, generates a magnetic field, and moves the rod 20r provided with the movable contact by pulling or pushing the permanent magnet 300 according to the polarity of the generated magnetic field. So that the movable contactor 20 is brought into contact with or disconnected from the load side fixed contact 10r and the power source side fixed contact 10e to thereby supply or cut off the commercial power source.

The coil 40 is wound around the iron core 40m as shown in FIG. 4 to magnetize the iron core by receiving external power. The coil 40 is wound around the iron core 40m in accordance with the direction of the current supplied to the coil 40, When the rod 20r is pushed and the movable contact 20 is moved from the fixed points 10r and 10e to the fixed point 10r and 10e, The power source is disconnected and the power source is shut off. If the power source is disconnected and the same polarity as that of the permanent magnet is applied, the permanent magnet is pulled to pull the rod 20r. When the rod 20r is pulled, the movable contact 20 contacts the fixed points 10r and 10e So that power is supplied to the load by connecting fixed points.

As described above, the power source supplied to the coil 40 is an external power source. As the power source, the power source branched from the commercial power source line supplied to the load or a battery can be used. And a switching circuit 50 as a means for switching the current direction.

The switching circuit 50 may be a variety of circuits capable of switching the direction of current, but it is preferable that the structure is as simple as possible. For example, as shown in FIG. 2, And two diodes Do and Dc for supplying currents in different directions to the coils.

The direction of the current when the coil 40 is supplied with power through the charging diode Dc and the direction of the current when supplying power to the coil through the diode for opening Do are opposite to each other, The polarity of the end portion toward the permanent magnet of the permanent magnet changes, pulling or pushing the permanent magnet.

Another example of the switching circuit 50 includes two rectifying circuits 50o and 50c for rectifying the electricity input from the two power sources and supplying currents in different directions to the coils as shown in Fig. 3 It is possible. The rectifier circuits 50o and 50c may be a bridge rectifier circuit as shown in the figure.

When the permanent magnet 30 contacts the iron core 40m magnetized by the coil 40 during the operation of the electromagnetic contactor as described above, the movable contactor 20 contacts between the two fixed contacts 10r and 10e, The permanent magnet in contact with the iron core remains in contact with the iron core 40m due to its own magnetic force, so that even when the power supplied to the coil is cut off, the electromagnetic contactor maintains the input state do.

That is, even if power is supplied to the coil 40 and the magnetic field generated in the iron core 40m is supplied only for a sufficient time to pull or push the permanent magnet 30, the power supplied to the coil is cut off, The contact between the movable contact 20 and the two fixed contacts 10r and 10e is maintained and power is supplied to the load.

Further, a spring 70 is further provided to maintain the opened state of the electromagnetic contactor.

The spring 70 is a compression spring that is resiliently urged in a direction to push out the permanent magnet 30. The permanent magnet 30 is pulled toward the iron core 40m by the magnetic force of the permanent magnet 30 in a state where the electromagnetic contactor is opened So that the movable contactor 20 is kept separated by the two fixed contacts 10r and 10e.

The switch 60 is provided as a means for interrupting the power supplied to the coil 40 in this way.

The switch 60 is operated by the movement of the permanent magnet 30 and uses a tact switch which supplies power to the coil only when the permanent magnet 30 is depressed by the movement of the permanent magnet.

As described above, the means for operating the switch 60 is a permanent magnet 30, and one side of the housing 30h for fixing the permanent magnet is brought into contact with the switch 60 as shown in Fig. .

10r, 10e: fixed contact
20: movable contactor 30: permanent magnet
40: Coil 40m: iron core
50: switching circuit
60: switch 70: spring

Claims (4)

1. A magnetic contactor comprising: a load side fixed contact connected to a load; a power source side fixed contact connected to a commercial power source; and a movable contact contacting the fixed contacts to connect the two fixed contacts,
And a switching circuit for switching a direction of a current supplied to the coil, wherein the switching circuit includes a permanent magnet on one side of the movable contact, and a coil for magnetizing the iron core by receiving external power from the external power source,
The switching circuit is switched to the direction of the current supplied to the coils by the switching circuit so that the magnetic field generated in the coils is formed in the pulling direction of the permanent magnet so that the movable contacts are pushed toward the fixed contacts by the pulling of the permanent magnets, When the power source is shut off, the magnetic field generated in the coil is formed in a direction to push out the permanent magnet, so that the movable contact is separated from the fixed contacts by the pushing of the permanent magnet, And the contact between the contact and the power source side stationary contact is cut off. The electromagnetic contactor is driven by a single coil and a permanent magnet. The method according to claim 1,
Wherein one end of the coil is further provided with a switch for cutting off the power supplied to the coil when power is supplied to the coil and the permanent magnet is pulled or pushed. The method according to claim 1,
Wherein the switching circuit is composed of two diodes that rectify the electric power input from one power source and supply currents in different directions to the coils. The method according to claim 1,
Wherein the switching circuit comprises two rectifier circuits for rectifying the electric power input from the two power sources and supplying currents in different directions to the coils.

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