KR20150057451A - Magnetic contactor - Google Patents

Abstract

The present invention relates to a magnetic contactor which applies an external current to a coil without a separate conductive line and prevents a disconnection risk. The magnetic contractor includes the coil, absorbs an operational core when the current is applied, and has a bobbin. Provided is the magnetic contractor which includes an operation circuit board which is arranged on one side of the bobbin, an external power input terminal which is installed on one side of the bobbin, a conducting unit which is installed on one end of the bobbin and provides a conduction path between the external power input terminal and the operation circuit board, a coil terminal which is installed on the other end of the bobbin and provides a conduction path between the operation circuit board and the coil, and a holder which is installed on the operation circuit board and combines the operation circuit board with the conducting unit of the bobbin and the coil terminal. By the magnetic contractor according to the present invention, the external power is conducted to the coil without connecting the conductive line.

Description

MAGNETIC CONTACTOR

The present invention relates to an electromagnetic contactor. More particularly, to an electromagnetic contactor capable of applying an external current to a coil without a separate lead, thereby preventing the danger of disconnection.

Generally, a magnetic contactor (MC) is a device that opens and closes a power (current) flowing in a main circuit by using an electromagnet principle. The electromagnetic contactor can be classified into a medium-sized and small-sized product of less than 130A and a large-capacity product of 130A to 800A, for example, depending on the current capacity.

FIG. 1 is an exploded perspective view schematically showing the construction of a general middle / small capacity electromagnetic contactor. The electromagnetic contactor includes an upper frame 11, a movable core 12, a back spring 13, a bobbin 14, A fixed core core 15, and a lower frame 16.

A magnetic field is generated around the coil 14a when an external power source is applied to the coil 14a wound on the outer surface of the bobbin. The magnetic field causes the bobbin 14 to rotate around the E- The core 15 is magnetized and becomes an electromagnet.

The stationary core core 15 thus electromagnetically attracts the movable core core 12 of the conductor by the magnetic force and pulls it down so that the movable core member 12 mechanically connected to the movable core core core 12 is lowered, The current flows through the main circuit.

At this time, when the power applied to the coil 14a disappears, the magnetic field around the coil 14a disappears, so that the movable core core 12 located on the restoring spring 13 rises to its original position due to the elastic restoring force of the restoring spring 13 The movable contact and the fixed contact are separated and the current flowing in the main circuit is cut off.

FIG. 2 is a plan view schematically showing an assembling structure of a bobbin of a conventional electromagnetic contactor, and FIG. 3 is a perspective view schematically showing an assembling structure of a bobbin of a conventional electromagnetic contactor.

2 and 3, there is an external power input terminal 25 through which external power is input, and a power input via the external power input terminal 25 is connected to the coil 23).

At this time, the power input from the external power input terminal 25 is applied to the operation circuit board 21, and when the operation circuit board 21 is applied to the coil, the power is transmitted through the lead 22.

However, since a wire is used between the operation circuit board and the coil during the process of applying power from the outside, a separate wire is required. In addition, when a disconnection occurs, a current is not properly applied to the operation circuit board, Causing a malfunction of the whole system.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide an electromagnetic contactor which is directly fastened without providing a conductive wire in a process of applying power from an operation circuit board to a coil.

It is also an object of the present invention to provide an electromagnetic contactor in which the operation circuit board is directly coupled to the bobbin.

According to an aspect of the present invention, there is provided an electromagnetic contactor including a coil and including a bobbin for attracting the movable core when a current is applied, ; An external power input terminal provided on one side of the bobbin; A conductive unit provided at one end of the bobbin and providing a current path between the external power input terminal and the operation circuit board; A coil terminal provided at the other end of the bobbin for providing a current carrying path between the operating circuit board and the coil; And a holder provided on the operation circuit board, for fastening the operation circuit board to the conductive portion of the bobbin and the coil terminal.

Here, the operation circuit board is supported by the bobbin and coupled by the holder.

Here, the holder may include: a first holder for applying a current, which is applied through the power supply unit, from the external power input terminal to the operation circuit board; And a second holder for applying a current to the coil terminal to the operation circuit board, wherein the operation circuit board includes an energizing rod for allowing a current to flow from the first holder to the second holder .

The current-passing portion is disposed at one end of the bobbin in a width direction, and has a current-carrying end portion contacting the holder. The coil terminal is spaced apart from the other end portion of the bobbin in the width direction, And a holder contact portion to be contacted.

The holder includes: a fixing part provided at one end of the holder and fixed to the operation circuit board; a contact part provided at the other end of the holder and elastically supported so as to be able to engage with the member drawn in the gap; And a connecting portion connecting the fixed portion and the contact portion.

Here, the holder may be made of an elastic material having a thin plate structure.

Here, the contact portions are formed so as to be spaced apart from each other toward the conductive portion or the coil terminal, and guide insertion of the conductive portion or the coil terminal.

Here, the connection portion may be curved.

In addition, the current-carrying end and the holder contacting portion may have a tapered chamfer at an end thereof toward the holder.

According to the electromagnetic contactor of the present invention, the external power source can be energized to the coil without connecting the wire.

In addition, the circuit operation board can be coupled to the bobbin by the holder provided on the circuit operation board.

In addition, the circuit operation board can be disposed on the side surface of the bobbin to provide a structurally compact and miniaturized magnetic contactor.

Moreover, the holder provided on the circuit operation board can be attached to and detached from the power supply unit and the coil terminal, thereby facilitating repair and replacement due to failure of the circuit operation board.

1 is an exploded perspective view schematically showing the structure of a conventional general magnetic contactor.
2 is a plan view schematically showing the structure of a bobbin of a conventional electromagnetic contactor.
3 is a perspective view schematically showing the structure of a bobbin of a conventional electromagnetic contactor.
4 is an exploded perspective view showing components of an electromagnetic contactor according to an embodiment of the present invention.
5 is an assembled perspective view of an electromagnetic contactor according to an embodiment of the present invention, and is a partial cutaway view of a power source side surface portion of a frame.
6 is an exploded perspective view of a fixing unit according to an embodiment of the present invention.
7 is a longitudinal cross-sectional view of a fixing part according to an embodiment of the present invention.
8 is a perspective view showing a direction in which the bobbin and the operation circuit board of the embodiment shown in FIG. 4 are combined.
9 is a perspective view of the bobbin and the operation circuit board of the embodiment shown in FIG.
10 is a perspective view showing a current flow after the bobbin and the operation circuit board of the embodiment shown in FIG. 9 are combined.
Fig. 11 is an exploded perspective view showing the main parts of the bobbin and the operation circuit board of the embodiment shown in Fig. 8; Fig.
FIG. 12 is a cross-sectional view showing the combined state of the bobbin and the operation circuit board of the embodiment shown in FIG.
13 is a cross-sectional view illustrating a holder according to an embodiment of the present invention.

It is noted that the technical terms used herein are used only to describe specific embodiments and are not intended to limit the scope of the technology disclosed herein. Also, the technical terms used herein should be interpreted as being generally understood by those skilled in the art to which the presently disclosed subject matter belongs, unless the context clearly dictates otherwise in this specification, Should not be construed in a broader sense, or interpreted in an oversimplified sense. In addition, when a technical term used in this specification is an erroneous technical term that does not accurately express the concept of the technology disclosed in this specification, it should be understood that technical terms which can be understood by a person skilled in the art are replaced. Also, the general terms used in the present specification should be interpreted in accordance with the predefined or prior context, and should not be construed as being excessively reduced in meaning.

Also, the singular forms "as used herein include plural referents unless the context clearly dictates otherwise. In this specification, the terms "comprising ", or" comprising "and the like should not be construed as necessarily including the various elements or steps described in the specification, Or may be further comprised of additional components or steps.

Further, in the description of the technology disclosed in this specification, a detailed description of related arts will be omitted if it is determined that the gist of the technology disclosed in this specification may be obscured. It is to be noted that the attached drawings are only for the purpose of easily understanding the concept of the technology disclosed in the present specification, and should not be construed as limiting the spirit of the technology by the attached drawings.

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an electromagnetic contactor in which a current carrying path between an operating circuit board and a coil is improved.

The present invention has been made in view of the above problems, and it is an object of the present invention to provide a magnetic contactor which has an energizing path using a wire between an operation circuit board and a coil terminal, The electromagnetic contactor of the present invention is connected to the operation circuit board and the coil terminal through a direct contact connection without requiring a wire between the operation circuit board and the coil terminal, So that there is no risk of disconnection or the like.

The same or similar elements are denoted by the same reference numerals regardless of the reference numerals, and redundant explanations thereof will be omitted. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

4 is an exploded perspective view showing components of an electromagnetic contactor according to an embodiment of the present invention. The electromagnetic contactor of the present invention includes a coil and a movable core 131 that is attracted to the movable core 131 when a current is applied and includes a bobbin 150 and is disposed on one side of the bobbin 150 171) an external power input terminal 151 provided at one side of the bobbin, a current carrying part 152 provided at one end of the bobbin and providing a current path between the external power input terminal and the operation circuit board, And a coil terminal (155) installed on the operating circuit board to provide a current path between the operating circuit board (171) and the coil, and a holder (160) provided on the operating circuit board for fastening the operating circuit board to the current- Lt; / RTI >

The electromagnetic contactor according to an embodiment of the present invention includes an upper frame 111, a crossbar 120, a movable portion 130, an elastic member 140, a fixing portion 180, an operation circuit portion 170, 112, and the like.

The upper frame 111 and the lower frame 112 form an outer skeleton of the product in the form of a rectangular box.

The cross bar 120 includes a column member 121 vertically disposed in the center of the column, a base member 122 disposed at the lower end of the column member 121, And includes a three-phase movable contact 123 provided therein.

The movable part 130 includes a cylindrical movable core 131, a connecting member 132 provided at the upper end of the movable core 131 for connecting the crossbar 120 to the movable core 131, And a supporter 134 installed on the connecting member 132 for supporting the movable core core 131 on the crossbar 120.

The movable core core 131 has a smaller diameter than the inner diameter of the bobbin 150 located at the fixed portion 180. The diameter of the movable core 131 is much smaller than the length of the conventional "E" movable core 131 in the left and right longitudinal direction of the upper frame 111, It is long. The movable core core 131 having such a structure can be inserted into the bobbin 150 in the axial direction (upward and downward in the drawing). The diameter of the bobbin 150 can be reduced by the movable core core 131 having such a structure and the side space between the inner surface of the lower frame 112 and the bobbin 150 can be reduced to the installation space of the operation circuit portion 170 Can be utilized.

The elastic member 140 serves to restore the movable part 130 and the cross bar 120 to their original positions by an elastic restoring force when the external power applied to the coil 156 disappears, A coil spring in which the coil is wound in a spiral shape can be used.

The fixing part 180 includes a bobbin 150 having a coil 156 to generate a magnetic field and a yoke 160 coupled to the bobbin 150 in a box shape on the widthwise side of the bobbin 150.

The operation circuit unit 170 includes an operation circuit board 171 vertically disposed on the power source side space of the bobbin 150 and an inversion switch 172 and a capacitor 173 mounted on the operation circuit board 171 do.

The inversion switch 172 is inverted by pressing the inversion switch in response to the movement of the movable core 172. At the same time the inversion switch 172 is inverted, the external power supply flows to the coil through the voltage- And serves to lower the voltage applied from the power source.

5 is an assembled perspective view of an electromagnetic contactor according to an embodiment of the present invention, showing the internal components by partially cutting the power source side surface portion of the frame 110. As shown in FIG.

5, the lower frame of the upper frame 111 opened downward and the upper frame of the lower frame 112 opened upward are assembled so that the upper frame 111 and the upper frame 111 are assembled together, The movable frame 130, the fixing portion 180, the elastic member 140, and the operation circuit portion 170 are accommodated in the lower frame 112 and the lower frame 112, respectively.

The crossbar 120 is vertically movably installed in the upper frame 111. A pressing part 124 is formed at the upper end of the cross bar 120. The pressing part 124 is formed in the upper frame 111 111, so that the user can manipulate the crossbar 120 manually.

A movable contact 123 is vertically movably provided on one side of the crossbar 120 among the components housed inside the product such that the front side (power source side) of the upper frame 111 is cut and the movable contact 123 123 are resiliently supported by a spring.

A main power terminal is provided in three phases (R, S, and T phases) in the upper frame 111 and a fixed contact 113 is fixed to the end of the main power terminal on the power source side so as to be vertically spaced apart from the movable contact 123 The moving part 130 and the cross bar 120 are lowered by the suction force of the electromagnet generated when the user presses the pressing part 124 of the cross bar 120 or when the external power source is applied to the coil 156, The movable contact 123, which operates in unison with the fixed contact 113, can be lowered to be brought into contact with the fixed contact 113.

Further, the fixing member for the main power terminal can be separately provided for each of the three phases on the fixed contact 113 inside the upper frame 111, and the power source side and the load side electric wire terminal can be inserted and fixed on the main power terminal by using the fixing member.

The movable part 130 includes a rectangular plate-shaped connecting member 132 disposed at an upper portion of the movable core core 131, a switch operating part 133 protruding horizontally at one side of the connecting member 132, And a switch operating projection 133a protruded downward on the bottom surface of the switch 133.

The connecting member 132 has two functions. The first function is a connecting function for connecting the crossbar 120 and the movable core core 131. The second function is a function for connecting the inverting switch 172 (not shown) located below the switch operating part 133 of the connecting member 132 to the switch operating projection 133a The switch operation lever 172a of the switch contacts the switch operation lever 172a to switch the internal contact point (in this case, the inversion means that the internal contact point is switched from the ON position to the OFF position).

The coil spring 140 may be disposed between the lower end of the crossbar 120 and the upper end of the bobbin 150. The upper end portion of the coil spring 140 is contacted with the lower end portion of the cross bar 120 so that an elastic restoring force is applied to the lower end portion of the cross bar 120 And the lower end of the coil spring 140 is fixed to the upper end of the bobbin 150. [

The bobbin 150 of the fixing unit 180 has a conductive part 152 of a conductive material connected to an external power input terminal (not shown) Is directly coupled to one side of the conductive part 152 via the holder 174 so that the external power input from the external power input terminal 151 is supplied to the external power input terminal 151 through a conductive part 152 of the bobbin 150, It can be directly applied to the operation circuit portion 170 without a part. At this time, the conductive part 152 is formed as a part of the bobbin 150, and the conductive part 152 is insulated by a plate-shaped insulating member made of an insulating material such as plastic.

There is an advantage of being advantageous in simplifying the product and miniaturizing the product by utilizing one side space (the front side with reference to Fig. 5) side space of the bobbin 150 as an installation space for the operation circuit board 171 of the operation circuit portion 170 . That is, since the operation circuit board 171 of the operation circuit unit 170 is disposed in parallel with the moving direction of the movable core 131 in the side space of the bobbin 150, interference with the movable core 131 is avoided . When the operation circuit board 171 is horizontally disposed on the upper side of the bobbin 150, the movable circuit board 171 is inserted into the operation circuit board 171 so that the movable core core 131 can be inserted and flowed into the operation circuit board 171 A hole is required to be secured, so that a part of the area of the operation circuit board 171 can not be utilized. In this case, space constraints are imposed on the arrangement of the movable core core 131 and the spring (elastic member 140) due to interference between the movable core core 131 and the operation circuit board 171. [ In addition, a separate processing step for forming an insertion hole for securing the flow is added to the operation circuit board 171, and a space for installing the electronic component on the operation circuit board 171 is reduced by the area of the insertion hole The size of the operation circuit board 171 is inevitably increased, which is a factor that hinders miniaturization of the product.

An inverting switch 172 and a capacitor 173 serving as a voltage drop device are integrally formed on the operation circuit board 171 and a switch operating lever 172a in the form of a strip is provided on one side of the inverting switch 172 An external power source and a coil 156 are connected to each other through an inverting switch 172 whose contact is normally closed and the inverting switch 172 is connected by the switch operating projection 133a of the moving part 130 Causing the external power source to flow through the capacitor 173 to the coil 156. Thereby, the voltage of the external power supply is lowered by the capacitor 173, so that the consumption current applied to the coil 156 can be reduced.

Further, even when the power consumption of the coil 156 is reduced as described above, the attracting force of the electromagnet for maintaining the contact state between the movable contact 123 and the fixed contact 113 can be ensured.

6 is an exploded perspective view of the fixing unit 180 according to an embodiment of the present invention.

6, the fixing portion 180 includes a bobbin 150 and a yoke 160 which is coupled to both side surfaces of the bobbin 150 in the width direction.

The bobbin 150 has a box-shaped yoke inserting portion 153 formed concavely at the upper and lower ends thereof. The yoke inserting portion 153 has an opening formed in a lateral side of the yoke inserting portion 153, ) Are inserted and coupled.

Particularly, at an upper end of the bobbin 150, external power input terminals 151 are provided at both ends in the longitudinal direction, and external power is applied through an external power input terminal 151.

The conductive part 152 is provided at an upper end of the bobbin 150. The power supply unit 152 directly connects between the external power input terminal 151 and the operation circuit unit 170 in a flat plate shape to provide a current path between the external power input terminal 151 and the operation circuit unit 170.

The coil terminal 155 is provided at the lower end of the bobbin 150 and the coil terminal 155 is directly connected to the operation circuit unit 170 to apply a current controlled by the operation circuit unit 170 to the coil 156 .

The yoke 160 has a structure in which a plate is bent and bent in a "C" cross-sectional shape with one side opened and the other three sides closed, and the upper end 160a of the bending- And a lower end portion 160b of the bobbin 150 are slidably inserted in the width direction of the bobbin 150 to a yoke inserting portion 153 provided at an upper end portion and a lower end portion of the bobbin 150,

At this time, the upper end portion 160a of the yoke 160 is formed with a circular opening, and the movable core core 131 can be inserted into the hollow portion 154 formed inside the bobbin 150 through the opening portion.

The lower end portion 160b of the yoke 160 is blocked in a planar shape and functions as a stopper to prevent the moving core core 131 from falling down by a certain distance (l) when the movable core core 131 descends.

The connecting portion 160c connecting the upper end portion 160a and the lower end portion 160b of the yoke 160 forms a magnetic path with respect to the magnetic field generated around the coil 156, .

7 is a longitudinal cross-sectional view of a fixing part according to an embodiment of the present invention.

7, the external power input terminal 151 is provided at one end (left end) of the upper end of the bobbin 150 so that external power is supplied to the bobbin 150 through the conductive part 152 provided at the upper end of the bobbin 150 May be applied to the circuit portion 170.

The operation circuit portion 170 is directly coupled to the power source side surface of the bobbin 150 through the holder 174 so that the operation voltage of the coil 156 can be received from the outside without a separate component.

The operation circuit unit 170 includes a flat operation circuit board 171 arranged in the vertical direction, an inversion switch 172 mounted on the upper end of the operation circuit board 171, And a capacitor 173 provided so as to be spaced apart from the inversion switch 172 in the width direction of the bobbin 150.

The inversion switch 172 includes a switch operation lever 172a in the form of a strip provided on an upper side of the switch body and a fixed contact and a movable contact in the switch body.

The inversion switch 172 may be a b-contact switch that is normally closed when the internal contact is closed, and operates the internal movable contact when the signal is applied from the outside through the switch operation lever 172a to disconnect the contact from the fixed contact.

The inversion switch 172 connects the external power input terminal 151 and the coil 156 when the external power is applied and transmits the current applied from the external power input terminal 151 to the coil 156.

Also, the inverting switch 172 receives a signal from the outside by the mechanical operation of the moving part 130. That is, as shown in Fig. 5, when the switch operation projection of the movable portion is lowered by the attracting force of the electromagnet, the switch operation lever 172a is pressed to invert the inversion switch 172. [ In this case, "turn on" means to turn off the internal contact (normally ON state) which is normally closed.

The switch operation lever 172a of the inversion switch 172 has a hinge portion bent at the lower end thereof. The hinge portion is embedded in the switch body and the upper end of the switch operation lever 172a is a free end. The movable contact inside the movable contact 113 is separated from the fixed contact 113.

The switch operation lever 172a has a strip structure and has elasticity. When the pushing force of the switch operation projection 133a is released, the switch operation lever 172a is returned to its original position by the elastic restoring force. As shown in FIG. 4, an arc-shaped contact end 172a 'may be formed at the end of the switch operation lever 172a to easily contact the switch operation protrusion of the movable portion.

The operation circuit unit 170 switches the coil 156 by consuming the current to be applied to the coil 156 by causing the current input through the external power input terminal 151 to pass through the capacitor 173 while the inversion switch 172 is inverted, The suction force for maintaining the contact state between the movable contact 123 of the main power source and the fixed contact can be provided even with a small power consumption of the main power source.

The bobbin 150 includes a cylindrical coil winding portion 150a having a hollow portion 154 therein and a flange portion 150b protruding outward from upper and lower ends of the coil winding portion 150a .

The coil winding unit 150a winds a plurality of coils 156 on the outer side of the coil winding unit 150a and generates an electromagnet when an external power source is applied to the coil 156. [ At this time, the coil winding portion 150a is made of an iron core material, and the magnetic field generated inside the coil winding portion 150a can be increased.

The flange portion 150b disposed at the upper and lower ends of the bobbin 150 includes a yoke inserting portion 153 formed inwardly inward to guide and support the rectilinear insertion of the yoke 160 in the width direction.

FIG. 8 is a perspective view showing a coupling relation between the bobbin 150 and the operation circuit unit 170 according to an embodiment of the present invention.

A portion of the bobbin 150 where the external power input terminal 151 and the power supply unit 152 are provided is referred to as an upper surface of the bobbin 150 and the upper surface of the bobbin 150, Is called the lower surface. And the coil terminal 155 is provided on the lower surface.

A description will be given on the assumption that the longer side of the operation circuit board 171 is the upper side and the lower side is the lower side.

The bobbin 150 is connected to an external power input terminal 151 to which external power is input, a power supply unit 152 through which the input power flows, and an end of the power supply unit 152 and is connected to the operation circuit board 171 A hollow portion 154 which is located at the center of the bobbin 150 and into which the movable core can be inserted, a coil winding around the hollow portion 154, a coil winding around the coil, And a coil terminal 155 connected to an end of the coil on a lower surface of the bobbin 150 so that current can be drawn in and drawn out.

The operation circuit board 171 includes a holder 174 that is connected to the bobbin 150 by being connected to the energizing end 152a and the coil terminal 155, And the inverting switch 172 and the capacitor 173 are provided on the outer surface of the operation circuit board 171. [

Meanwhile, the operation circuit board 171 is coupled to one side of the bobbin 150. That is, the current-carrying end located at the end of the current-carrying part 152 provided at the upper end of one side of the bobbin 150 and the coil terminal 155 provided at the lower end of one side of the bobbin 150 . Also, the operation circuit board 171 is coupled to the bobbin 150 by the coupling. That is, even if there is no other supporting member for supporting the operation circuit board 171, it can be coupled to and supported by the bobbin.

The one-dot chain line in the drawing indicates the direction in which the operation circuit board 171 and the bobbin 150 are coupled.

The holder 174 is disposed at an upper portion and a lower portion inside the operation circuit board 171. A holder disposed at the upper portion of the holder 174 is referred to as a first holder, and a holder disposed at a lower portion thereof is referred to as a second holder. The first holder is in contact with and connected to the energizing end, and the second holder is in contact with and connected to the coil terminal 155.

FIG. 9 is a perspective view showing a state where the bobbin 150 and the operation circuit board 171 of the embodiment shown in FIG. 8 are combined.

Referring to FIG. 8, the bobbin 150 and the operation circuit board 171 shown in FIG. 8 are joined together and viewed from the bottom (bottom) of the bobbin 150.

The operation circuit board 171 is supported by the bobbin 150 and is not separated unless a certain amount of force is applied thereto.

When external power is input from the external power input terminal 151, power is supplied through the power supply unit 152, and power is directly applied to the operation circuit board 171 through the power supply end. The operation circuit board 171, to which power is supplied, is supplied with power through the coil terminal 155 after the current flows in the internal circuit. Then, the coil to which the power is applied sucks the movable core as described above.

The direction in which the operation circuit board 171 is coupled to the bobbin 150 is a direction perpendicular to the direction in which the yoke 160 is inserted into the bobbin 150. [ While being supported in this direction, the overall size of the bobbin 150 or the fixing portion can be downsized. The operation circuit board 171 may be coupled to the bobbin 150 in a direction perpendicular to the direction of insertion of the movable core core so as not to interfere with movement of the movable core core. That is, the operation circuit board 171 is positioned on the side surface of the bobbin 150.

10 is a perspective view showing the current flow of the operation circuit board 171 after the bobbin and the operation circuit board 171 of the embodiment shown in FIG. 9 are combined.

Referring to Fig. 10, the energizing rod 179 inside the operation circuit board 171 is shown at the bottom of the drawing.

In the figure, C denotes a capacitor, B / D denotes a rectifying element, and L denotes a coil. The inverting switch 172 is shown between B1 and B2.

When external power is applied to the external power input terminal 151 as described above, power is supplied from the current end 152a to the first holder power input part 177a of the operation circuit board 171. [ This can be expressed as P1.

When power is supplied to P1 of the operation circuit board 171, the current flows to the B1 side. The inversion switch 172 between B1 and B2 is normally closed and the circuit is closed and the current flows to the line between B1 and B2 rather than the path with the capacitor 173. However, in the state in which the inversion switch 172 between B1 and B2 is opened as shown in the drawing, a current flows to the conductor having the capacitor 173.

The rectifier B / D may be formed of a bridge diode. The bridge diode converts an alternating current (AC) power applied via the inversion switch 172 or the capacitor 173 to a direct current (DC) ).

The current converted into the direct current power is applied to the coil through the second holder power take-off part 178b disposed under the operation circuit board 171. [ The second holder power take-off part 178b contacts the coil terminal 155 provided at one side of the bobbin 150. [ This is indicated by A1 in the figure. The current applied to the coil magnetizes the coil to attract the movable core core. The current passing through the coil is again applied to the operation circuit board 171 through the coil terminal 155 and the second holder power supply input 178a provided on the other side of the bobbin 150. [ The current applied to the operation circuit board 171 flows again through the current passing portion 152 through the first holder power supply draw-out portion 177b along the current carrying path, and then exits through the external power supply terminal on the opposite side.

Fig. 11 is an exploded perspective view showing a main portion of the bobbin 150 and the operation circuit board 171 of the embodiment shown in Fig.

Referring to FIG. 11, the bobbin 150 has a bobbin frame. The bobbin case provides a space in which the conductive part 152, the yoke, the coil terminal 155, and the like can be housed. Also, since the bobbin case is made of an insulating material, it is possible to prevent an electric shock accident that may occur due to the current flowing out of the conductive part 152 or the like.

The bobbin case includes a hollow portion 154 into which a movable core can be inserted, an upper surface of the bobbin frame having the conductive portion 152, and a lower surface of the bobbin frame in which the coil terminal 155 is housed .

The first holder 177 located on the operation circuit board upper surface 171a and the second holder 178 located on the operation circuit board lower surface 171b are disposed on the operation circuit board 171, Respectively.

The first holder 177 is connected to the current-carrying end 152a. The current-carrying end 152a is vertically formed in a direction descending from the upper surface to the lower surface of the bobbin frame. Therefore, the first holder 177 is formed in such a manner that the first holder 177 is extended right and left with respect to the current-carrying end 152a.

The coil terminal 155 is inserted into the bobbin 150 in a horizontal direction on the lower surface of the bobbin frame. Also, a portion where the coil terminal 155 contacts the second holder 178 is formed horizontally on the lower surface of the bobbin frame. The second holder 178 is formed to extend upward and downward to be coupled to the coil terminal 155.

Therefore, the first holder 177 and the second holder 178 are arranged by rotating the holders 174 of the same shape by 90 degrees. Such an angle difference of 90 degrees can increase the fixing force of the operation circuit board with respect to the bobbin. That is, the holders can be fixed to the bobbin without being biased in a specific direction, rather than being arranged in the same direction. Of course, the direction of the holder 174 is not necessarily the same as the above-described arrangement, but may be changed according to the forming direction of the current-carrying end 152a and the protruding direction of the coil terminal 155. [

The coil terminal 155 includes a coil connecting portion 155a connected to a coil wound inside the bobbin 150, a holder contacting portion 155b contacting with the holder 174 to which a current is applied, And a terminal supporting portion 155c for supporting the coil terminal 155 is provided.

The recessed grooves 175 are formed at both ends in the longitudinal direction of the operation circuit board lower surface 171b. As shown in the figure, the coil connection part 155a protrudes toward the operation circuit board 171, and the concave groove 175 is formed to allow the coil connection part 155a to pass without being caught by the operation circuit board .

The operation circuit board 171 is connected to the bobbin 150 and fastened and supported in a direction in which a one-dot chain line is drawn.

12 is a cross-sectional view showing the main part of the operation circuit board 171 coupled to one side of the bobbin 150 after the bobbin 150 and the operation circuit board 171 of the embodiment shown in FIG. 11 are combined .

Referring to FIG. 12, an operation circuit board 171 is coupled to one side of the bobbin 150. An inverting switch 172 and a capacitor 173 are disposed on the outer surface of the operation circuit board 171.

The bobbin 150 is provided with a current carrying portion 152 and a current carrying end 152a, a yoke inserting portion 153 and a coil terminal 155. [

Since the current-carrying end 152a is vertically lowered from the upper surface of the bobbin 150 in the lower surface direction, the first holder 177 is connected to the current-carrying end 152a in such a manner that they contact each other.

The coil terminal 155 is inserted in a horizontal direction with respect to the lower surface of the bobbin 150 so that the second holder 178 extends upward and downward to be in contact with the coil terminal 155.

The operating circuit board 171 is provided with the concave groove 175 and the coil connecting portion 155a protrudes from the concave groove 175. [

The current-carrying end 152a and the holder contact 155b may have a tapered chamfer at an end of the holder 174 toward the holder 174. This is so that by having a tapered chamfer, the entry into the holder 174 can be facilitated.

13 is a cross-sectional view showing a holder 174 according to an embodiment of the present invention.

The holder 174 includes a holder fixing portion 174a connected to the operation circuit board 171, a contact portion 174c contacting the energizing end 152a and the coil terminal 155, the holder fixing portion 174a, There is a connection portion for connecting the contact portion 174c. The holder 174 is made of a resilient member. The holder 174 has a thin plate structure. This is because the holder 174 is intended to energize and support, so that the energization can be performed well, and a desired desired elastic force is properly obtained.

The holder fixing portion 174a is a portion where the holder 174 is fixed to the operation circuit board 171. [ The fixing may be performed by soldering, or by various methods such as bolting and riveting.

The contact portion 174c has an elastic force. Therefore, the contact portion 174c is opened by a predetermined length. The energized end 152a or the coil terminal 155 is inserted into the gap. The thickness of the energizing end 152a or the coil terminal 155 is thicker than the width of the gap. This is because the operating circuit board 171 can be coupled to and supported by the bobbin 150 by using an elastic force to recover as much as the contact portion 174c is widened.

The contact portion 174c is formed to be spaced apart from the operation circuit board. This is for guiding and guiding the insertion of the energizing end 152a or the coil terminal 155. [

The connection portion 174b is a portion that connects the contact portion and the holder fixing portion 174a. The connecting portion 174b may have a curved shape. This is for the purpose of giving the effect of the buffering to the force that the contact portion makes when the energizing end 152a or the coil terminal 155 is inserted.

The holder 174 may be integrally formed with the contact portions formed on both sides to the connecting portion and the fixing portion 180. Of course, the contact portions facing each other may be formed of two units, each of which may have a holder fixing portion, a connection portion, and a contact portion.

Although the present invention has been described in connection with certain exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the appended claims and equivalents thereof.

150: Bobbin 150a: Coil winding part
150b: flange portion 151: external power input terminal
152: conductive part 152a: energized end
153: yoke inserting portion 154: hollow portion
155: coil terminal 155a: coil connection
155b: holder contact portion 155c:
160: yoke 160a: upper portion
160b: lower end portion 160c:
170: Operation circuit part 171: Operation circuit board
171a: Operation circuit board upper surface 171b: Operation circuit board lower surface
172: inverting switch 172a: switch operating lever
172a ': contact end 173: capacitor
174: holder 175: concave groove
177: first holder 177a: first holder power input part
177b: first holder power take-off part 178: second holder
178a: second holder power take-off part 178b: second holder power input part
179: energizing rod 180:
B / D: Bridge diode C: Capacitor
L: Coil P1, P2: Power input terminal

Claims (10)

An electromagnetic contactor comprising a coil, which attracts the movable core when a current is applied and includes a bobbin,
An operating circuit board disposed on one side of the bobbin;
An external power input terminal provided on one side of the bobbin;
A conductive unit provided at one end of the bobbin and providing a current path between the external power input terminal and the operation circuit board;
A coil terminal provided at the other end of the bobbin for providing a current carrying path between the operating circuit board and the coil; And
A holder provided on the operation circuit board and for fastening the operation circuit board to the conductive portion of the bobbin and the coil terminal;
And an electromagnetic contactor.
The method according to claim 1,
And the operating circuit board is supported and coupled to the bobbin by the holder.
2. The apparatus of claim 1, wherein the holder
A first holder for applying a current, which is applied from the external power input terminal through the power supply unit, to the operation circuit board; And
And a second holder for applying a current, which is applied to the operation circuit board, to the coil terminal,
Wherein the operation circuit board includes an energizing rod that allows current to flow from the first holder to the second holder.
4. The apparatus of claim 3, wherein the second holder
And is arranged to be shifted by 90 degrees from the first holder.
The method according to claim 1,
Wherein the conductive portion has a conductive end portion which is disposed at one end portion of the bobbin in the width direction and is in contact with the holder,
Wherein the coil terminal has a holder contact portion which is disposed at the other end portion of the bobbin in the width direction and is in contact with the holder.
The method according to claim 1,
Wherein the holder comprises:
A fixing unit provided at one end of the holder and fixed to the operation circuit board,
A contact portion provided at the other end of the holder so as to be elastically supported so as to be able to engage a member drawn in between the clearance,
And a connection portion connecting the fixing portion and the contact portion.
The method according to claim 1,
Wherein the holder is made of a thin plate structure.
The method according to claim 6,
Wherein the contact portions are formed so as to be spaced apart from each other toward the conductive portion or the coil terminal, and guide insertion of the conductive portion or the coil terminal.
The method according to claim 6,
And the connecting portion is bent in a curved shape. 6. The method of claim 5,
Wherein the energizing end and the holder abutting portion are provided with a tapered chamfer at an end toward the holder.

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