KR102391245B1 - Magnetic Contactor for Forword and Reverse - Google Patents

Abstract

The present invention relates to a reversible magnetic contactor used for forward/reverse operation of a motor or reverse-phase braking,
MCF (Magnetic Contactor Forward) for opening and closing the forward circuit and MCR (Magnetic Contactor Reverse), and the MCF and the MCR form an interlock that electrically implements a simultaneous input prevention device between the magnetic contactors using each auxiliary contact, wherein the MCF is the first It is configured to include a starting terminal 1 to a first starting terminal 3 and a first connection terminal 1 to a first connection terminal 3, and the MCR is a second connection terminal 1 to a second connection terminal 3 and a second starting terminal 1 to a second starting terminal. and a terminal 3, electrically connecting the first starting terminal 1 and the second starting terminal 1, the first starting terminal and the second starting terminal 2, and the first starting terminal 3 and the second starting terminal 3, The three insulated conductive plates connected to MCF and MCR are 'ST terminal/first terminal/second terminal', 'SS terminal/first terminal/second terminal', 'SR terminal/first terminal/second terminal, respectively. ', wherein the ST electrically connects the first connection terminal 1 and the second connection terminal 2, the SS electrically connects the first connection terminal 2 and the second connection terminal 1, and the SR is The first connection terminal 3 and the second connection terminal 3 of the MCR are electrically connected, and the MCF and the MCR form a mutually symmetric structure so that the main circuit wiring of each phase can be easily installed. At the connection part of the second connection terminal 1, a bent part is provided so that it can be bent at a predetermined angle, it passes through the lower end of the magnetic contactor and is fastened to the connection terminal. We propose a reversible magnetic contactor characterized in that the rotation direction of the forward or reverse direction is selectively operated and controlled.
Therefore, the reversible magnetic contactor according to the present invention is one by supplying the power supply R, S, T of the main forward rotation magnetic contactor and the reverse rotation magnetic contactor to the lower end of the magnetic contactor through a busbar-type insulating conducting plate. It is easy to attach and detach the magnetic switch in combination, the number of terminals of the power wiring is reduced compared to the existing product, and the number of wiring strands of the power wiring is reduced. There are advantages that can be

Description

Reversible Magnetic Contactor {Magnetic Contactor for Forward and Reverse}

The present invention relates to a reversible magnetic contactor used for forward/reverse operation or reverse-phase braking of a motor. Reversible that can be performed electrically using auxiliary contacts and can be safely switched from forward to reverse or from reverse to forward using each operation switch, simplifying the wiring circuit and switchgear configuration It is about a type magnetic contactor.

In addition, in order to change the rotational direction of the three-phase induction motor, the present invention provides a positive and negative output power of three-phase input power of R, S, and T stages to U1, V1, and W1 stages of a forward and reverse rotation motor because it is enough to change the phase of two of the three phases. In case of reverse rotation with the rotary magnetic switch, connect a plurality of insulated conduction plates (SR, SS, ST) for main power supply so that R power is the same and S and T are connected in reverse order to form a magnetic switch for reverse rotation. To provide a reversible magnetic contactor configured to enable forward rotation and reverse rotation of a three-phase induction motor, respectively.

In general, the reversible type magnetic contactor is manufactured by molding a conductor so that the main circuit wiring of each phase of the magnetic contactor that connects the plurality of electromagnetic contactors side by side interlockingly between the electromagnetic contactors can be fastened to an electric wire or the electromagnetic contactor, and the distance between the conductors It is configured to include a spacer member that can be assembled by maintaining a constant.

In addition, the reversible magnetic contactor produced with a structure that can prevent a short circuit caused by disproportionate proximity of phases and phases by being integrated with the separation distance between a plurality of conducting conductors maintained at a constant level is used for forward and reverse operation of the motor, reverse phase braking and It is manufactured and marketed as a product suitable for commercial, non-commercial, and conversion purposes.

However, in the prior art, there is no known technique that is implemented in a way that a current is supplied in one direction by installing reversible magnetic contactors side by side, so that the current direction of the magnetic contactor can be changed by controlling the power connection internally.

The present invention is to solve the above problems, in which two magnetic switches, which are conventional wiring methods, are connected to the magnetic contactor for forward rotation and the supply power R, S, and T of the magnetic contactor for reverse rotation to the lower end of the magnetic contactor in a busbar method. An object of the present invention is to provide a reversible magnetic contactor that is commonly supplied through an insulated conducting plate.

In addition, when using a common power supply by using an insulated current plate and other power supply members as the center of the magnetic contactor for forward and reverse operation, the power supply R, S, T of the magnetic contactor for forward rotation and reverse rotation is used. Since it is installed in the lower part, in order to prevent electromagnetic induction between the respective power sources caused by the narrow distance between the current-carrying part and the main power supply line of the coil installed under the inside of the magnetic contactor, the main power supply line and the coil Another object of the present invention is to provide a reversible magnetic contactor that is separated by an electromagnetic blocking plate.

In the reversible magnetic contactor according to the present invention, the power supplied through the R, S, T lines of the main power is supplied to the MCF (Magnetic Contactor Forward) for opening and closing the forward rotation circuit by a plurality of insulated conducting plates composed of a busbar method for power supply. and MCR (Magnetic Contactor Reverse) for opening and closing the reverse rotation circuit electrically, and the MCF and MCR form an interlock that electrically performs the simultaneous input prevention device between the magnetic contactors using each auxiliary contact. In the electromagnetic contactor, the MCF is configured to include a first starting terminal 1 to a first starting terminal 3 and a first connection terminal 1 to a first connection terminal 3, the MCR is a second connection terminal 1 to a second connection terminal 3 and It is configured to include a second starting terminal 1 to a second starting terminal 3, and the first starting terminal 1 and the second starting terminal 1, the first starting terminal and the second starting terminal 2, the first starting terminal 3 and the second starting terminal Terminal 3 is electrically connected, and the three insulated conductive plates connected to the MCF and MCR are 'ST terminal/first terminal/second terminal', 'SS terminal/first terminal/second terminal', 'SR', respectively. terminal/first terminal/second terminal', wherein the ST electrically connects the first connection terminal 1 and the second connection terminal 2, and the SS is the first connection terminal 2 and the second connection terminal 1 to electrically connect, the SR electrically connects the first connection terminal 3 and the second connection terminal 3 of the MCR, and the MCF and the MCR form a mutually symmetric structure so that the main circuit wiring of each phase can be easily installed, The insulating conducting plate is provided with a bent portion so that it can be bent at a predetermined angle at the connection portion of the first connection terminal and the second connection terminal 1, passes through the lower end of the magnetic contactor and is fastened to the connection terminal, according to the operation of the MCF and MCR Its technical feature is to selectively operate and control the rotation direction of the motor in the forward or reverse direction by changing the phases of 2 phases among 3 phases.

The reversible magnetic contactor according to the present invention is combined into one by supplying the power supply R, S, T of the magnetic contactor for forward rotation and the magnetic contactor for reverse rotation to the lower end of the magnetic contactor through a busbar-type insulating conducting plate in common. It is easy to attach and detach the magnetic switch, the number of power wiring terminals is reduced compared to existing products, and the number of power wiring wiring is reduced. There are advantages.

1 is a schematic diagram of a reversible magnetic contactor according to the present invention;
2 is a pattern diagram of an insulating conductive plate according to the present invention;
3 is a circuit diagram of a reversible magnetic contactor according to the present invention;
4 is a pattern diagram of a reversible magnetic contactor according to the present invention.

A preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In the present invention, as shown in FIG. 1 , MCF (Magnetic Contactor Forward) 10 and MCR (Magnetic Contactor Reverse) 20 forming a mutually symmetrical structure are connected to the R, S, T lines of the main power supply 100. The power supplied through the is electrically connected by a plurality of insulated conducting plates 40 . (In the drawing, the upper frame and lower frame, which maintain the overall shape, are detached to show the internal structure.

In one embodiment of the present invention, the MCF 10 for the forward direction and the MCR 20 for the reverse direction include cross bars 11 and 21 installed in an inner space formed by an upper frame and a lower frame, respectively, and the cross bar 11 ) (21), the movable cores (12, 22) connected to the lower part, the fixed cores (14, 24) installed at a predetermined distance below the movable cores (12, 22), and the fixed core (14) The operating coils 13 and 23 installed at both ends of the 24 and back springs 15 and 25 installed inside the movable core 12 and 22 are included, and the crossbar 11 ( The movable contacts 17 and 27 are installed on the upper part of the 21), and are configured to electrically contact the fixed contacts 16 and 26 at the time of each coil excitation.

That is, in the reversible magnetic contactor according to the present invention, the MCF (Magnetic Contactor Forward) 10 for opening and closing the forward rotation circuit and the MCR (Magnetic Contactor Reverse) 20 for opening and closing the reverse rotation circuit prevent simultaneous input between the magnetic contactors, respectively. The MCF (10) and the MCR (20) have a plurality of insulated conducting plates ( 40) is a method of fastening.

The interlock refers to a circuit or component that prevents a malfunction in which two different devices operate at the same time, and when one of the two contacts operates, the contact is opened to block the operation of another device.

In addition, the MCF (10) is provided with first starting terminals (18a, 18b, 18c) and first connection terminals (19a, 19b, 19c), the MCR (20) is provided with second connection terminals 1 (28a, 28b) , 28c) and second starting terminals 29a, 29b, and 29c are provided.

For reference, the first starting terminal includes a first starting terminal 1 (18a) / a first starting terminal 2 (18b) / a first starting terminal 3 (18c), the second starting terminal is a second starting terminal 1 (29a) ) / second starting terminal 2 (29b) / second starting terminal 3 (29c), and the first connection terminal is a first connection terminal 1 (19a) / first connection terminal 2 (19b) / first connection terminal 3 (19c), and the second connection terminal includes a second connection terminal 1 (28a/second connection terminal 2 (28b)/second connection terminal 3 (28c)).

On the other hand, as shown in FIG. 2 , the plurality of insulated conducting plates 40 connected to the MCF 10 and the MCR 20 are configured in a busbar type for power supply, and as an embodiment of the present invention, the main The ST terminal 40a connected to 'T' of the power source 100, the first terminal 41a connected to the MCR 20, and the second terminal 42a connected to the MCF 10; an SS terminal 40b connected to 'S' of the main power supply 100, a first terminal 41b connected to the MCR 20, and a second terminal 42b connected to the MCF 10; It includes an SR terminal 40c connected to 'R' of the main power supply 100 , a first terminal 41c connected to the MCR 20 , and a second terminal 42c connected to the MCF 10 .

Accordingly, the ST 40a of the insulating conducting plate 40 electrically connects the first connecting terminal 1 19a of the MCF 10 and the second connecting terminal 2 28b of the MCR 20 to the insulating conducting plate SS (40b) of (40) electrically connects the first connection terminal 2 (19b) of the MCF (10) and the second connection terminal 1 (28a) of the MCR (20), the SR of the insulated conducting plate (40) (40c) electrically connects the first connection terminal 3 (19c) of the MCF (10) and the second connection terminal 3 (28c) of the MCR (20), according to the operation of the MCF (10) and the MCR (20) Phase 2 of the 3 phases is changed, and the rotation direction of the motor is selectively controlled to be forward or reverse.

In particular, the insulating conductive plate 40 has a bent portion 43a so as to be bent at the predetermined angle at the connection portion between the first connection terminals 19a, 19b, 19c and the second connection terminals 1 28a, 28b, 28c. (43b) and (43c) may be provided.

thus. When power is applied to the working coil of the MCF 10 , the backspring 15 is compressed while the movable core 12 comes into contact with the fixed core 14 by the suction force generated from the coil. At this time, as the crossbar 11 connected to the movable core 12 moves downward together, the movable contact 17 comes into contact with the fixed contact 16, so that power flows in the forward direction.

Conversely, when the power of the working coil is cut off, the suction force of the coil disappears and the backspring 15 expands and the movable core 12 moves upward. Accordingly, the movable contact 17 is separated from the fixed contact 16 .

At this time, when power is applied to the working coil of the MCF 20 , the movable core 22 comes into contact with the fixed core 24 by the suction force generated from the coil, and the backspring 25 is compressed. At this time, as the crossbar 21 connected to the movable core 22 moves downward together, the movable contact 27 comes into contact with the fixed contact 26, so that power flows in the reverse direction.

In another embodiment of the present invention, an electrical connection between the first starting terminals 18a, 18b, 18c of the MCF 10 and the second starting terminals 29a, 29b, and 29c of the MCR 20 is established, respectively. 1 starting terminal 1 (18a) and the second starting terminal 1 (29a), the first starting terminal 2 (18b) and the second starting terminal 2 (29b), the first starting terminal 3 (18c) and the second starting terminal 3 ( 29c) to produce a product, there will be significant advantages in constructing an electromagnetic contactor.

On the other hand, the supply power of the electromagnetic contactor according to the present invention is inevitably electronic because it is preferable to install it through the lower end of the electromagnetic contactor when using a common power supply using a plurality of insulated conducting plates 40 and other power supply lines. When the coil installed under the inside of the contactor is energized, the distance between the coil and the main power supply line is inevitably narrowed, so a problem may occur due to electromagnetic induction between each power source.

In the present invention, as shown in FIG. 4 to prevent this, an electromagnetic shielding plate 60 is installed between the coils provided in the MCF 10 and the MCR 20 and the load 30, so that the electromagnetic induction phenomenon It is desirable to prevent

In an embodiment of the present invention, the electromagnetic shielding plate 60 is made of a lead material, and in addition, an alternative or another member capable of shielding electrons and magnetism may be used, and between the lower end of the electromagnetic contactor and the coil. A lead plate is installed in the center, and it is installed based on the direction in which the main power passes through the center.

The reversible magnetic switch of the present invention configured as described above is operated in a connected state as shown in the equivalent circuit diagram of FIG. 3 and the pattern diagram of FIG. 4 , so that the forward and reverse power supply can be easily switched.

Therefore, in the reversible magnetic contactor according to the present invention, the supply power R, S, T of the main magnetic contactor for forward rotation and the magnetic contactor for reverse rotation are commonly supplied to the lower end of the electromagnetic contactor through a busbar-type insulating conducting plate 40. By doing so, the wiring work is easy, and it is easy to attach and detach the magnetic switch by combining it into one.

In addition, the number of terminals of the power wiring is reduced and the size of the distribution box is reduced by the application of the insulated conductive plate 40, resulting in economical savings.

10: MCF (Magnetic Contactor Forward)
20: MCR (Magnetic Contactor Reverse)
11, 21: crossbar 12, 22: movable core
13, 23: action coil 14, 24: fixed core
15, 25: Backspring 16, 26: Fixed contact
17, 27: movable contact 18a, 18b, 18c: first starting terminal
19a, 19b, 19c: first connection terminal 28a, 28b, 28c: second connection terminal
29a, 29b, 29c: second starting terminal
30: Load (FR; Forward Reverse) 40: Insulated conductive plate
40a: ST terminal 40b: SS terminal
40c: SR terminal 41a, 41b, 42c: first terminal
42a, 42b, 42c: second terminal 43a, 43b, 43c: bent portion
60: electromagnetic shielding plate 100: main power

Claims (5)

MCF (Magnetic Contactor Forward) for opening and closing the forward circuit and MCR (Magnetic Contactor Reverse), and the MCF and the MCR form an interlock that electrically implements the simultaneous input prevention device between the magnetic contactors by using each auxiliary contact,
The MCF 10 is configured to include a first starting terminal 1 to a first starting terminal 3 (18a, 18b, 18c) and a first connection terminal 1 to a first connection terminal 3 (19a, 19b, 19c), the MCR ( 20) is configured to include second connection terminals 1 to 2 connection terminals 3 (28a, 28b, 28c) and second starting terminals 1 to 2 starting terminals 3 (29a, 29b, 29c), and the first starting Terminal 1 (18a) and the second starting terminal 1 (29a), the first starting terminal (18b) and the second starting terminal 2 (29b), the first starting terminal 3 (18c) and the second starting terminal 3 (29c) electrically connected,
The three insulating conducting plates 40 connected to the MCF 10 and the MCR 20 are respectively 'ST terminal 40a/first terminal 41a/second terminal 42a', 'SS terminal 40b' / first terminal (41b) / second terminal (42b)', 'SR terminal (40c) / first terminal (41c) / is configured to include a second terminal (42c)', the ST terminal (40a) is The first connection terminal 1 (19a) and the second connection terminal 2 (28b) are electrically connected, and the SS terminal (40b) is electrically connected to the first connection terminal 2 (19b) and the second connection terminal 1 (28a). and the SR terminal 40c electrically connects the first connection terminal 3 19c and the second connection terminal 3 28c of the MCR 20,
The MCF 10 and the MCR 20 have a mutually symmetrical structure so that the main circuit wiring of each phase can be easily installed, and the insulated conducting plate 40 is connected to the first connection terminals 19a, 19b, 19c and the second connection terminal. The bent portions 43a, 43b, and 43c are provided so as to be bent at a predetermined angle at the connection portion of the terminal 1 (28a, 28b, 28c), pass through the lower end of the magnetic contactor and fasten to the connection terminal,
Reversible magnetic contactor, characterized in that by changing the phase of two of the three phases according to the operation of the MCF (10) and the MCR (20), the rotation direction of the motor is selectively operated in a forward or reverse direction.
The method of claim 1,
Reversible, characterized in that the electromagnetic shielding plate 60 is provided between the operating coils 13 and 23 of the MCF 10 and the MCR 20 and each insulating conducting plate 40 to prevent electromagnetic induction. type magnetic contactor. delete delete delete

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