KR20090091045A - Circuit breaker - Google Patents

Abstract

A circuit breaker is provided to miniaturize a bobbin and a main body by parallel winding a first coil and a second coil to the bobbin. A load connection part and a power connection part are arranged in a main body. A contact part includes a fixed contact(2A,2B) and a movable contact(3A,3B). The fixed contact and the movable contact are arranged in a current path between the load connection part and the power connection part. An electromagnetic release part(47) includes a movable iron core(58), a first coil(68B), and a second coil(68A). If an overcurrent flows to the current path, the movable iron core is sucked by a magnetic force generated in a fixed iron core. If a leakage current flows to the current path, the first coil excites a stator iron core. If a short-circuit current flows to the current path, the second coil performs a release operation. The first coil and the second coil are parallel wound in a bobbin.

Description

Circuit breaker {CIRCUIT BREAKER}

The present invention relates to a circuit breaker.

Conventionally, the circuit breaker which wound two windings to one bobbin is provided (for example, refer patent document 1). The circuit breaker combines two types of large bobbins and small bobbins of different diameters to coincide with each other to form a bobbin, and windings are wound around the large bobbin and the small bobbin, respectively.

Patent Document 1: Japanese Patent Application Laid-Open No. 2000-40456 (paragraph [0009] -paragraph [0011], and, FIG. 2)

In the circuit breaker shown in Patent Document 1 described above, since the bobbin winding the winding is formed from two small and large bobbins combined so that their center axes coincide with each other, the bobbin becomes larger in the radial direction, and as a result, the entire circuit breaker It was to enlarge the width direction.

The present invention has been made in view of the above problems, and an object thereof is to provide a circuit breaker miniaturized in the width direction.

The invention as set forth in claim 1 is a contact portion comprising a load connection portion to which a load is connected and a power supply connection portion to which a power supply is connected, a fixed contact portion and a movable contact provided at a converter between the load connection portion and a power supply connection portion, and contacting and separating the contact portion. And a movable iron core attracted by magnetic force generated on the magnetic pole surface of the fixed iron core when an excessive current flows in the converter, and forcibly opening the contact portion through the switching iron core by the movable iron core. When the electromagnetic release portion is provided, the electromagnetic release portion is a winding for generating a magnetic field, the first winding for exciting the fixed iron core when the leakage current flows in the converter, and the current flowing through the converter and the short circuit current flows through the converter Having a second winding for executing a release operation by a magnetic force generated in the first and second windings The bobbin is wound side by side in the axial direction.

The invention of claim 2 is characterized in that the first and second windings are wound in the same direction.

According to the invention of claim 1, in the same bobbin, the first and second windings are arranged in the axial direction of the bobbin and wound so that the bobbin can be made smaller in the radial direction than in the prior art. It can be miniaturized in the direction, and as a result, it is possible to provide a circuit breaker miniaturized in the width direction. In addition, since it is only necessary to arrange and wind the 1st and 2nd windings with respect to a bobbin at the time of electromagnetic release assembly, assembling compared with the case where both bobbins are assembled after winding each winding of 2 bobbins large and small like a conventional example. This has the effect of ease. Moreover, since a bobbin can be made into a longitudinal length, when the bobbin is arrange | positioned in the horizontal direction, there exists an effect that the height dimension of a circuit breaker can be made low.

According to the invention of claim 2, by winding the first and second windings in the same direction, even if a short circuit accident occurs during a short circuit, for example, the direction of magnetism generated in the fixed iron core becomes the same direction. There is an effect that the circuit breaker can be reliably protected because it does not disturb the suction of the iron core.

Embodiment of this invention is described based on FIGS. The circuit breaker of the present embodiment is attached to, for example, a power distribution board such as a house, and is used as a protection switch that supplies power to a connected load and cuts off the power supply when an abnormality occurs. In addition, although the circuit breaker of this embodiment is equipped with the contact structure of two poles, only one pole is demonstrated about the same structure in the following description. In addition, unless otherwise indicated in the following description, the direction of the arrow a-b in FIG. 4 will be described as an up-down direction, the direction of the arrow c-d as a left-right direction, and the direction of the arrow e-f as a front-back direction.

As shown in Figs. 1 to 4, the circuit breaker changes the height in the base 1 formed by opposing the base members 1A and 1B on the left and right sides made of synthetic resin, and changes the height to the left and right directions (perpendicular to the ground in Fig. 1). Two fixed contacts 2A, 2B arranged in one direction) and movable contacts 3A, 3B opposing to each of these fixed contacts 2A, 2B so as to be able to contact and disconnect (i.e., contact or open separation). Two movable contacts 4A and 4B fixed and attached, and an opening and closing mechanism 5 for driving these two movable contacts 4A and 4B, and the opening and closing mechanism by the on / off operation of the handle 6 are provided. The movable contact 3A, 3B is contacted and separated from the corresponding fixed contact 2A, 2B via (5), and each fixed contact 2A, 2B and each movable contact 4A, 4B Is placed at different height positions in the vertical direction and interposed between the two fixed contacts 2A and 2B in the vertical direction. Each of the movable contacts 3A and 3B from each of the fixed contacts 2A and 2B to the fixed contact 2A for contacting and separating the movable contact 4B of the movable contact 4B and the movable contact 3A of the other movable contact 4A. It is arrange | positioned in the height position which does not intersect in the width direction of the base 1 in the state which isolate | separated open.

Inside the front and rear one end side (left side in FIG. 1) of the base | substrate 1, the partition member 7 which consists of synthetic resin molded articles is arrange | positioned so that it may be sandwiched between both base members 1A and 1B, and the partition member 7 The terminal block 10B in which the lower fixed contact 2B was provided at one end is accommodated in the space comprised by the recessed part 9 provided in the left side of (), and the side wall (outer wall) of the base member 1B. In addition, one side of the upper fixed contact 2A is provided in a space formed by a recess (not shown) inside the side wall (outer wall) of the base member 1A on the right side and the longitudinal wall portion of the partition member 7. 10A provided in the terminal block is accommodated.

As shown in FIG. 1, the terminal block 10B includes a terminal plate 11 and a lower portion of the terminal plate 11 that are distorted into a substantially "c" shape in which one side surface (the surface on the gas member 1B side) opens. 11 d of extension members integrally extended upward from one end side of the member 11e, and the extension member 11c extended integrally downward from the one end side of the lower member 11e of the terminal plate 11 downward. A fixed contact 12B extending integrally to the side, a fixed contact 2B caulking and fixed to an upper surface of one end of the fixed contact 12B, and a terminal plate 11 mounted on the lower member 11e of the terminal plate 11. It consists of the locking spring 13B of a substantially "m" shape accommodated in it. The terminal plate 11 mounts the lower member 11e on the horizontal wall portion 24 constituting the bottom portion of the recessed portion 9 of the partition member 7, and has a vertical wall (one end of the recessed portion 9) The extension member 11c is concave by fitting the one end of the terminal plate 11 to the cutout formed between the lower end of the vertical wall 25 and the one end of the transverse wall 24 at the same time as the extension member 11d. When the partition member 7 overlaps each other toward the base member 1A, the front end portion of the fixed contact 12B, that is, the bottom surface of the fixed member 2B, is disposed so as to extend out of the portion 9. It is mounted on the ribs 26 and 26 provided in the bottom part. At this time, the lower end portion of the fixed contact 2B protruding toward the lower surface side of the fixed contact 12B is disposed in the recess formed between the ribs 26 and 26. Moreover, the protrusion 23 which is inserted in the press piece 13b of the locking spring 13B, and prevents the ratching of the locking spring 13B is integrally formed in the side surface of the side piece of the terminal board 11. As shown in FIG.

The above-described locking spring 13B and the terminal plate 11 constitute a fastening terminal that is a conductor connecting portion, and the wire insertion hole 16B formed obliquely downward on one end side (left side in FIG. 1) of the base 1 in the front and rear direction. A core wire of an electric wire (not shown) inserted from the outside is connected between the upper member 11b of the terminal plate 11, the upper end of the locking member 13a of the locking spring 13B, and the upper end of the pressing piece 13b. As the tip of the locking member 13a penetrates into the core wire, the core wire is locked in the drawing direction of the electric wire, and the core wire is inserted from the upper end surface of the pressing piece 13b to the upper member 11b of the terminal plate 11. By sticking in, the core wire is electrically connected and mechanically held.

Here, the release handle 17 is for releasing the above-described electric wire locking, and the release handle 17 has a pivot shaft (not shown) provided on the lower one side surface (the surface on the side of the partition member 7). The shaft part (not shown) which is axially supported by the axial hole (not shown) provided in the longitudinal wall part of (7), and protruded to the inner side surface of the base member 1B is provided with the lower other side (gas member ( 1B), which is axially rotatably supported by the concave portion 37 provided on the side of the side 1B), and manually rotated the operating portion 17a exposed to the outside of the base 1 to rotate in the counterclockwise direction in FIG. At this time, the driving protrusion 19 provided at the lower end side is capable of pressing the distal end of one end of the locking member 13a of the locking spring 13B to bend the locking member 13a so that the locking on the core wire can be released. . In addition, the release handle 17 is always rotated and pressed in the clockwise direction in FIG. 1 by a return spring (not shown). In addition, two release handles 17 are arranged so as to correspond to the respective poles in the horizontal direction (the direction perpendicular to the surface of FIG. 1) with the partition member 7 interposed therebetween.

On the other hand, the terminal block 10A, like the terminal block 10B, consists of a terminal plate 11, a locking spring (not shown), and a fixed contact 12A in which a fixed contact 2A is caulked and fixed on the front end side. However, unlike the terminal plate 11 of the terminal block 10B, the terminal plate 11 of the terminal block 10A has an extension member 11a extending upward from one end side of the lower member 11e. The fixed contact 12A is extended so that it may become perpendicular to the extension member 11a from the upper end of the extension member 11a. This terminal block 10A mounts the lower member 11e of the terminal plate 11 on a bottom surface (not shown) inclined downward of the recessed portion of the base member 1A, and stands on one end side of the recessed portion. While arranging the extension member 11a along the wall (not shown), the fixed contact 12A is led out of the recess beyond the top of the standing wall, and stands up from the standing wall and the bottom of the gas member 1A. Terminal block 10A is arrange | positioned in the said recessed part by arrange | positioning the front-end | tip part of the fixed contact 12A on the fixed contact arrangement | positioning part 15 inclined similarly to the said bottom surface of the recessed part between the partition 14 provided, and integrally formed. do. At this time, the lower end portion of the fixed contact 2A protruding toward the lower surface side of the fixed contact 12A is disposed in the concave portion 15a formed on the upper surface of the fixed contact placing portion 15.

The locking spring of the terminal block 10A and the terminal plate 11 constitute a fastening terminal that is a conductor connection as in the case of the terminal block 10B, and have a wire insertion hole formed obliquely downward on the rear side of the base 1. (Not shown), the wire is inserted from the outside, the core wire is locked by the locking member of the locking spring, and the wire is pushed by the pressing piece to the upper member 11b of the terminal plate 11 to electrically connect the wire. It is intended to be mechanically locked.

And when releasing the wire lock mentioned above, the drive protrusion 19 provided in the lower side at the time of manually operating the operation part 17a (refer FIG. 4) and rotating it anticlockwise rotation similarly to the terminal block 10B. Is pressed so that the locking member is bent by pressing the distal end of the locking member of the locking spring, thereby releasing the locking to the core wire. The load connection part is comprised by the terminal block 10A, 10B here, and the contact part is comprised by the fixed contact 2A, the movable contact 3A, and the fixed contact 2B, and the movable contact 3B.

Next, a connection in which two conductive bars (not shown) disposed at different height positions in the distribution panel (not shown) are respectively inserted and inserted into the other end side (right side in FIG. 1) of the base body 1 in the front and rear directions. The accommodating parts 90 and 90 which accommodate and arrange | position the terminals T1 and T2 are arrange | positioned in the up-down direction at the lower surface side of the base 1, and are provided. Further, inserting portions 209a and 209b for inserting conductive bars formed by abutting substantially L-shaped cutout grooves formed over the end walls and the sidewalls of both base members 1A and 1B, respectively, are provided with respective storage portions ( 90, 90) is provided. In addition, the insertion part 209a communicates with the upper housing part 90, and the insertion part 209b communicates with the lower housing part 90, respectively.

The connecting terminals T1 and T2 each have a substantially 'c' shape, and are formed of a spring that extends over the tip after the ends of the two sides parallel to each other are adjacent to each other, thereby expanding the tip. The conductive bar can be easily inserted, and the conductive bar can be sandwiched in the vicinity of the center. Here, the power supply connection part is comprised by connection terminal T1, T2, the accommodating part 90, and the insertion part 209a, 209b.

Here, the opening / closing mechanism 5 for opening and closing the movable contacts 4A and 4B includes a step-shaped locking portion for locking the operation plate 43 serving as a latch member, the crossbar 40 and one end of the operation plate 43. It consists of the drawing board 41 in which 57 was formed, the handle 6, the link 44 of a substantially "C" shape, etc.

The handle 6 is comprised of the operation part 6a, the rotation part 6b, and the handle shaft 6c, and the handle member 6c which protruded in the center part of the both sides of the rotation part 6b has the base member 1A, 1B. It is held between both base members 1A and 1B by being rotatably inserted into the axial hole (not shown) formed in the inner side of the operation part, and the operation part 6a is a base body in the state which opposes both base members 1A and 1B. It faces the window hole 50 formed in the upper surface of (1). A torsion spring (not shown) is attached to the handle shaft 6c, and the handle 6 is always pressed in the off operation direction by the torsion spring. Moreover, as shown in FIG. 1, the shaft hole 52 is provided in the lower end of the rotation part 6b, and it inserts the upper shaft of the link 44 so that rotation is possible to the operation plate 43 via the link 44. FIG. Connected.

The operating plate 43 is connected to the handle 6 via the link 44 by passing the lower shaft of the link 44 through the bearing holes provided in the central portions on both sides in the left and right directions (the direction perpendicular to the ground in FIG. 1). It is arrange | positioned so that up-and-down movement is possible in (1).

The crossbar 40 is formed between the two gas members 1A and 1B by inserting the shaft portions 40a protruding from both sides of the upper portion into the shaft holes (not shown) formed in the inner surfaces of the gas members 1A and 1B. In the side of the gas member 1A side slightly lower than the shaft portion 40a, as shown in FIG. 7, a cutout groove 54 into which the movable contactor 4A is inserted from the side is further provided. In the side of the side (1B), the cutout groove 55 into which the movable contact 4B is inserted from the side is provided, respectively. And in the cross-section of the crossbar 40 in the front-back direction one end side (left side in FIG. 1), the locking piece 130 protruding to the partition member 7 and both base members 1A, 1B, respectively (in FIG. 1, Only the locking piece 130 provided in the base member 1A] is separated from each of the fixed contacts 2A and 2B by the movable contacts 3A and 3B (the state shown in Fig. 2 or 3). The concave grooves 131 are inserted along the width direction so as to be hooked and inserted into the bottom portion.

In addition, the lower end of the crossbar 40 is pressurized by the coil spring 62A compression-arranged between the lower end part and the partition 63 standing upright at the bottom part of the base member 1A, and the clockwise direction of FIG. The rotating force is pressurized. Here, the crossbar 40 has the on-rotation position (position shown in FIG. 1) which the movable contacts 3A and 3B and the fixed contacts 2A and 2B contact, and the movable contacts 3A and 3B and the fixed contact. (2A, 2B) is rotatably held in the base 1 between the off-rotation positions (positions shown in FIG. 2 or 3) in which the openings are separated, and the cut-out groove 55 has the crossbar 40 turned on the on-rotation. Between rotating from the position to the off-rotation position, the cross section of the side closer to the rotation point (shaft part 40a) of the crossbar 40 is provided so that it may displace in the opposite direction to the movable contact 4B from the position of an on state.

Here, the movable contact 4A is formed of a rigid conductive metal plate, is inserted into the cutout groove 54 of the crossbar 40 from the side, and is provided with a recess 54a provided on the front side of the cutout groove 54 ( 7 is pressurized upward by a coil spring (not shown) for contact, which is compressed and disposed between the bottom of the movable contact 4A and the bottom of the movable contactor 4A, and the crossbar 40 is centered on the shaft portion 40a. At the time of rotation, the movable contactor 4A rotates around the opening projection of the incision groove 54, so that the movable contact 3A caulked and fixed to the free end may be contacted or opened with respect to the fixed contact 2A. It is.

In addition, the movable contact 4B is formed of a rigid conductive metal plate similarly to the movable contact 4A, is inserted from the side into the cutout groove 55 of the crossbar 40, and the partition 63 of the gas member 1A. The shaft is rotatably supported by the shaft groove (63a) provided in the). In addition, one end side of the coil spring 62B, which is compressed and disposed between the bottom surface of the base member 1A, is fixedly attached to the lower surface of the movable contact 4B, and the shaft groove 63a is attached by the coil spring 62B. As a point, the rotational force in the clockwise direction is pressed in FIG. 1. Here, the crossbar 40 is disposed between the fixed contact 2B and the shaft groove 63a as shown in FIG. 2, and the coil spring 62B is disposed on the shaft groove 63a side with respect to the crossbar 40. It is. Then, when the crossbar 40 rotates in the clockwise rotation direction, the movable contactor 4B rotates in the clockwise rotation direction about the shaft groove 63a by the pressing force from the coil spring 62B, and the crossbar 40 rotates. When rotating in the counterclockwise direction, it rotates in the counterclockwise direction around the shaft groove 63a in response to the pressing force from the coil spring 62B. The movable contact 3B, which is caulked and fixed on the distal end side, is fixed to the fixed contact ( Contact or open separation with respect to 2B).

The lead plate 41 is integrally formed with a shaft portion 41a, a projection portion 41b that protrudes above the shaft portion 41a, and a corner portion 41c that projects below the shaft portion 41a. ) Is axially rotatably supported between both base members 1A and 1B by inserting the left and right end portions of each side into the axial hole (not shown) provided in the inner surfaces of both base members 1A and 1B. Moreover, the locking part 57 which the one end (right end in FIG. 1) of the operation plate 43 engages is formed in the upper end part of the protrusion part 41b, and the bimetal 46 is provided in the front end side of each part 41c. 41d of plate parts which are driven by pressure protrude in the left-right direction, and are provided. In addition, a torsion spring 81 is attached to the lead-out plate 41, and is constantly pressurized in the counterclockwise direction by the torsion spring 81.

Next, as shown in FIG. 1, as for the electrically conductive plate 71B which consists of a thick plate metal material, the screw hole through which the adjustment screw 77 screw-engages is provided through one end side (right side in FIG. 1), and the other end side is provided. A pair of caulking shafts protrude from the lower surface. The pair of holes is provided in a pair of holes in which an adjusting plate 72 made of a thin plate metal material having a substantially L-shaped bimetal 46 constituting the heat transfer release device is welded and fixed to the other end thereof. The caulking shaft is attached to the lower surface side of the conductive plate 71B by inserting and caulking the caulking shaft. In addition, the adjusting screw 77 is for changing the distance between the adjusting plate 72 and the conductive plate 71B, and is capable of adjusting the lower position of the bimetal 46, that is, the sensitivity of the heat transfer releasing device.

On the welded portion of the adjusting plate 72 of the bimetal 46, the other end side of the electric wire 79A having one end connected to the connecting terminal T1 is welded, and the braided wire welded at one end to the movable contact 4B ( The other end side of 79C is welded to a substantially central portion in the vertical direction of the bimetal 46, and the connection terminal T1, the electric wire 79A, the conductive plate 71B, the bimetal 46, the braided wire 79C, The movable contact 4B is electrically connected. Moreover, the other end side of the electric wire 79E which one end side was connected to the connection terminal T2 via the winding 68A and the electric wire 79B to the welding part of the bimetal (not shown) already provided in the one electrode side. The other end side of the braided wire 79D, which is welded and one end side is welded to the movable contact 4A, is welded to a substantially central portion in the vertical direction of the bimetal, and the connection terminal T2, the electric wire 79B, and the winding ( 68A), electric wire 79E, conductive plate (not shown), bimetal, braided wire 79D, and movable contact 4A are electrically connected.

Here, the conductive plate 71B and the bimetal 46 are held by the partition member 31 interposed between the base members 1A and 1B. The partition member 31 is made of a synthetic resin molded article having an insulating property, and is provided with a substantially rectangular concave portion 31c through which a side surface (surface on the gas member 1B side) opens, and the concave portion 31c is provided. The conductive plate 71B and the bimetal 46 are accommodated in the base 1 by press-fitting the conductive plate 71B into the base 1. In the present embodiment, a plurality of projections 31d (four in Fig. 1) are protruded and provided on the upper and lower surfaces of the recess 31c, and the conductive plate 71B is formed between these projections 31d. ), The conductive plate 71B and the bimetal 46 are held. Moreover, the notch part 31e for making the adjustment screw 77 facing outward is provided in the upper surface of the recessed part 31c, and it heats by adjusting the adjustment screw 77 through this notch part 31e. It is possible to adjust the sensitivity of the mobile release device. In addition, since the adjustment screw 77 does not need to be adjusted after the adjustment, the cutout portion 31e is closed with a cover (not shown), and the adjustment screw 77 is inadvertently operated, or foreign matter such as dust may be trapped. 1) Intrusion is prevented. In addition, between the base member 1A and the partition member 31, a different conductive plate and bimetal are held in the partition member 31 similarly to the conductive plate 71B and the bimetal 46 described above. .

Here, in the circuit breaker of this embodiment, when the short circuit current flows in the main circuit or the leakage current flows in a closed electrode state, the said opening / closing mechanism 5 is released and the said contact part is opened. The electromagnetic release part 47 is provided. As shown in FIGS. 1 and 6, the electromagnetic release part 47 is wound around the coil bobbin 69 and the coil bobbin 69 having an elongated shape in a front and rear direction (left and right direction in FIG. 6). The secondary outputs generated in the windings 68A and 68B, the image current transformer ZCT for detecting the leakage current flowing through the main circuit, and the secondary winding (not shown) of the image current transformer ZCT are input, The circuit board 73 in which the earth leakage detection circuit which detects a leakage current based on the said secondary output is provided is provided.

The coil bobbin 69 is formed of an insulating material such as a synthetic resin, and the collars 69C are provided at both ends and the middle part in the axial direction (left and right directions in FIG. 6), and the hoisting between the collars 69C is performed. The drum parts 69A and 69B are arranged in the front-back direction (left-right direction in FIG. 6). Further, in the coil bobbin 69, a fixed iron core 57 made of magnetic metal is attached to the front side (right side in FIG. 6), and a movable iron core made of magnetic metal and movable in the axial direction on the back side. 58) is stored. Moreover, the release lever 58A of substantially L shape is attached to the front-end | tip (left end) of the movable iron core 58 when viewed from the cross section engaging with the protrusion part 41b of the drawing board 41 mentioned above. Further, a return spring 70 is attached to one end (right end in FIG. 6) of the release lever 58A, and the release lever 58A and the movable iron core 58 are always pressed to the rear (leftward direction in FIG. 6). have. That is, the position shown in FIG. 6 becomes the initial position (return position) of the release lever 58A and the movable iron core 58. As shown in FIG.

Here, the above-described winding 68A is wound around the hoisting drum section 69A of the coil bobbin 69, and one end side of the winding 68A is connected to the connection terminal T2 via the electric wire 79B. The other end side is connected to the movable contact 4B via a wire 79E or the like. On the other hand, the above-described winding 68B is wound around the hoisting drum section 69B, and both ends of the winding 68B are connected to an output circuit (not shown) formed on the circuit board 73. That is, in the circuit breaker of this embodiment, the windings 68A and 68B are wound side by side in the axial direction of the coil bobbin 69, and the windings 68A and the winding 68B are in the same direction (back side in this embodiment). Wound in clockwise rotation). Here, the second winding is constituted by the winding 68A, and the first winding is constituted by the winding 68B.

In the current transformer ZCT, the wires 79A and 79E, which form the paths of both voltage poles, pass through the through-hole provided in the center, and when the leakage current flows in the main circuit, the image current transformer ZZ is unbalanced. Current flows into the secondary winding to produce a secondary output. The secondary output is input to the circuit board 73. When the input secondary output is compared with a predetermined threshold by the ground fault detection circuit, and it is determined that a leakage current larger than the reference value flows, the output circuit is wound by the output circuit ( 68B) is intended to be energized.

Here, in the circuit breaker of this embodiment, the upper surface side which arises by arrange | positioning the connection terminal T1, T2, the accommodating part 90, and the insertion part 209a, 209b which comprise a power supply connection part to the lower surface side of the base | substrate 1 The circuit board 73 and the coil bobbin 69 constituting the electromagnetic release portion 47 are disposed in the space of the space.

Next, the assembly method of the circuit breaker of this embodiment is demonstrated. In addition, in the following description, electric wires 79A, 79B, 79E, and braided wires 79C, 79D are assumed to be fixed and attached to a predetermined position in advance. First, the terminal block 10A is accommodated in the recess of the base member 1A on the right side, and the release handle 17 is assembled together with the return spring at a predetermined position. Further, the handle 6 is assembled together with the torsion spring at a predetermined position. Thereafter, the movable contact 4A is inserted into the cutout 54 of the crossbar 40, the coil spring is accommodated in the recess 54a, and the crossbar 40 is placed at a predetermined position on the base member 1A side. It is arrange | positioned so that rotation with the coil spring 62A is possible. In addition, the operation plate 43 is connected to the handle 6 using the link 44 and disposed at a predetermined position.

Thereafter, the connection terminals T1 and T2 are accommodated in the storage units 90 and 90 provided on the other end side (right side in FIG. 1) of the base 1, respectively, and the rear surfaces of the connection terminals T1 and T2 are respectively accommodated. The image current transformer ZCT is housed on the side (left side in FIG. 1), and the circuit board 73 and the windings 68A, 68B are wound in the upper spaces of the connection terminals T1 and T2 and the image current transformer ZCT. The coil bobbin 69 is accommodated.

Next, the movable contactor 4B is inserted into the cutout groove 55 of the crossbar 40, and the shaft contact portion 63a provided in the partition 63 in the vicinity of the bent portion of the movable contactor 4B is axially supported, and the coil One end side of the spring 62B is fixedly attached to the movable contact 4B and the other end side is fixedly attached to the bottom of the base member 1A.

Thereafter, the partition member 31 is accommodated in the base 1A, and the conductive plate 71B is press-fitted into the recessed portion 31c of the partition member 31, so that the conductive plate 71B and the bimetal 46 are formed. It is held by the partition member 31, and the extraction board 41 is arrange | positioned so that rotation with the torsion spring 81 to a predetermined position is possible.

In this way, parts other than the return spring of the partition block 7, the terminal block 10B accommodated in the recessed part 9 of the partition wall member 7, the release handle 17, and the release handle 17 are replaced with the base member 1A. After assembling on the) side, the partition member 7 in which the terminal block 10B, the release handle 17, and the return springs of the release handle are assembled in the recess 9 is disposed so as to overlap the base 1A side.

And in this state, the base member 1B overlaps and joins on the side of the base member 1A. At this time, the hooked hook portion 101 of the tip of the three elastic locking pieces 100 which protruded from the base member 1A side to the base member 1B side was provided corresponding to the base member 1B side. When locked to the locking portion (not shown), respectively, the base member 1A and the base member 1B are combined to assemble the base 1. On the contrary, when removing the base member 1B from the base member 1A, a driver (not shown) is provided from each release hole 150 (see Fig. 4) of the base member 1B opened in correspondence with the edge locking portion. Press to press the latching latch portion 101 of the corresponding elastic latch piece 100 upward or downward, and release the rocking state of the latching latch portion to remove the gaseous member 1B from the gaseous member 1A. Can be.

Here, the initial position of the bimetal 46 is adjusted by moving the adjusting screw 77 disposed toward the cutout portion 31e in the up and down direction using a tool, and after adjustment, the cover is attached to the cutout portion 31e. Occupies.

By the way, as shown in FIG.4 and FIG.5, the protrusion part 105 provided with the insertion through-hole 105a is provided in the upper surface by the side of the base member 1B, and similarly, the test button for generating a short circuit state is carried out. The tip portion 78 is exposed upward from the insertion through hole 105a. Then, the test button 78 is pressurized to enter a short-circuit state so that the trip operation described later can be confirmed.

Next, operation | movement of the circuit breaker of this embodiment is demonstrated based on FIG. FIG. 2 shows an off state. In this off state, the operation part 6a of the handle 6 is in an inverted state from the window hole 50, and the operating plate 43 and the extraction plate 41 are coupled to each other. The state is in the released state. The crossbar 40 is pressurized to rotate in the clockwise direction in FIG. 2 by the coil spring 62A, and the movable contact 4A penetrated into the cutout groove 54 of the crossbar 40 is a free end (movable). The contact 3A side] is moved upward, and the movable contact 4B penetrated into the cutout groove 55 is free end (movable contact 3B side) by the pressing force from the coil spring 62B. It is in the state moved upward. That is, each movable contact 3A, 3B is in the state isolate | separated from the corresponding fixed contact 2A, 2B, respectively.

In this state, when the operation part 6a of the handle 6 is rotated in the clockwise direction, the upper axis of the link 44 is pressed and driven downward, and the link 44 is operated by the lower axis. Push down. When the operation plate 43 is pushed down, one end (right end in FIG. 1) of the operation plate 43 contacts the locking portion 57 of the lead plate 41, and the operation plate 43 rotates the contact portion. It rotates in the counterclockwise direction about the center, the other end (left end in FIG. 1) contacts the protrusion part 84 provided in the upper end of the crossbar 40, and the crossbar 40 resists the pressing force from the coil spring 62A. Rotate it counterclockwise.

The movable contact 4B penetrated into the cutout groove 55 of the crossbar 40 by this rotation rotates in the counterclockwise direction against the pressing force from the coil spring 62B, and the movable contact provided on the free end side thereof ( 3B) is brought into contact with the fixed contact 2B. In addition, the movable contact 4A penetrated into the cutout 54 rotates in the counterclockwise direction as with the movable contact 4B, and the movable contact 3A provided on the free end side thereof contacts the fixed contact 2A. Let's do it.

And when the handle 6 is further rotated in the clockwise rotation direction, the upper axis moves to the left direction as shown in Fig. 1 than the line connecting the position of the lower axis of the link 44 and the rotation center of the handle 6, In this state, the torsion spring of the handle 6, the coil spring 62A to press the crossbar 44, the elastic force of the coil spring 62B to press the movable contact 4B, and the like are balanced. The latch state of one end and the locking part 57 of the extraction plate 41 is maintained, and the on state shown in FIG. 1 is maintained.

Next, when the operation part 6a of the handle 6 is rotated in the counterclockwise direction in the on state, the position of the upper axis of the link 44 goes beyond the line connecting the rotation center of the handle 6 and the lower axis beyond the right direction. Since it moves upward, the latch state of the right end of the operating plate 43 and the locking portion 57 of the drawing plate 41 is released, and the crossbar 40 is rotated in the clockwise direction by the pressing force of the coil spring 62A. At the same time, the handle 6 rotates rapidly to the off side by the pressing force of the torsion spring. By the rotation of the crossbar 40 in the clockwise direction, the movable contactor 4A rotates in the clockwise direction to move the free end upward, and the movable contact 3A is opened and separated from the fixed contact 2A. Further, the movable contact 4B rotates in the clockwise direction with the shaft groove 63a as the rotation center by the pressing force from the coil spring 62B, and moves the free end upward, and moves the movable contact 3B to the fixed contact ( Open separated from 2B).

Here, when an excessive load current flows through the bimetal 46 in the on state shown in FIG. 1, the bimetal 46 generates heat due to the overcurrent and causes a curved displacement. In this embodiment, the lower end of the bimetal 46 is displaced so as to move to the rear side (left direction in FIG. 1), and the flat plate portion 41d of the lead plate 41 is pushed to the left side, and the lead plate 41 is pulled out by this pressing force. ) Rotates in the clockwise direction about the shaft portion 41a.

Then, when the takeout plate 41 rotates in the clockwise rotation direction, the latch state of the locking portion 57 of the takeout plate 41 and one end (right end) of the operation plate 43 is released, and the operation plate 43 is It rotates in the clockwise direction about the lower axis of the link 44. Therefore, the restriction of the crossbar 40 by the other end (left end) of the operation plate 43 is eliminated, and the crossbar 40 is rotated in the clockwise direction by the elastic force of the coil spring 62A, and is shown in FIG. 3. As shown in the figure, the movable contacts 4A and 4B are returned to the off state, and the movable contacts 3A and 3B are opened and separated from the fixed contacts 2A and 2B, respectively.

After that, the bimetal 46 is returned to its original state by disconnection of the converter, and the extraction plate 41 is rotated and returned to its original position by pressurization of the torsion spring 81. Further, the handle 6 is rotated in the off direction (counterclockwise direction) by the pressure of the torsion spring.

In addition, when an excessive current such as a short-circuit current flows in the winding 68A wound on the coil bobbin 69 in the on state shown in FIG. 1, the magnetic force is applied to the fixed iron core 57 constituting the electromagnetic release portion 47. Is generated and the movable iron core 58 is sucked in the right direction. In doing so, the release lever 58A adhered to the movable iron core 58 pulls the projection 41b of the lead-out plate 41 forward (in the right direction in FIG. 6) against the pressing force of the return spring 70, The lead plate 41 rotates in a clockwise rotation direction about the shaft portion 41a.

Then, as in the case where the excessive load current flows, when the extraction plate 41 rotates in the clockwise rotation direction, the latch state of the locking portion 57 of the extraction plate 41 and one end (right end) of the operation plate 43 is changed. It is released and the operation plate 43 is rotated in the clockwise direction about the lower axis of the link 44. Therefore, the restriction of the crossbar 40 by the other end (left end) of the operating plate 43 is eliminated, and the crossbar 40 rotates in the clockwise direction by the elastic force of the coil spring 62A, and the movable contact 4A , 4B is returned to the off state, and the movable contacts 3A and 3B are opened and separated from the fixed contacts 2A and 2B, respectively. That is, the release operation forcibly opening the contact portion is performed by the magnetic force generated by the short circuit current flowing through the winding 68A. In addition, since the winding 68A energizes with the electric current which flows through a converter, although the fixed iron core 57 is excited even in the state in which the short circuit current does not flow, the magnetic force which generate | occur | produces in this state is movable iron core 58 It is the size which cannot suck up, and it does not perform the said release operation.

Then, when the magnetic force does not generate | occur | produce in the fixed iron core 57 of the electromagnetic release part 47 by a converter interruption, the movable iron core 58 and the release lever 58A are returned to the original state by the elastic force of the return spring 70. It returns and the drawing board 41 rotates back to an original position by the pressurization of the torsion spring 81. FIG. Further, the handle 6 is rotated in the off direction (counterclockwise direction) by the pressure of the torsion spring.

In addition, when a leakage current flows in the main circuit in the on state shown in Fig. 1, an unbalanced current flows in the video current transformer ZCT, and a secondary output is generated in the secondary winding. The winding 68B is energized. When the winding 68B is energized, a magnetic force is generated in the fixed iron core 57 constituting the electromagnetic release portion 47 to suck the movable iron core 58 in the right direction. In doing so, the release lever 58A attached to the movable iron core 58 pulls the projection 41b of the lead-out plate 41 forward (rightward direction in FIG. 6) against the pressing force of the return spring 70, The lead plate 41 rotates in a clockwise rotation direction about the shaft portion 41a.

Then, as in the case where the short-circuit current flows, when the drawing plate 41 rotates in the clockwise rotation direction, the latch state of the locking portion 57 of the drawing plate 41 and one end (right end) of the operating plate 43 is released. , The operating plate 43 is rotated in the clockwise direction about the lower axis of the link 44. Therefore, the restriction of the crossbar 40 by the other end (left end) of the operating plate 43 is eliminated, and the crossbar 40 rotates in the clockwise direction by the elastic force of the coil spring 62A, and the movable contact 4A And 4B are returned to the off state, and the movable contacts 3A and 3B are opened and separated from the fixed contacts 2A and 2B, respectively.

Then, when the magnetic force does not generate | occur | produce in the fixed iron core 57 of the electromagnetic release part 47 by a converter interruption, the movable iron core 58 and the release lever 58A are returned to the original state by the elastic force of the return spring 70. It returns and the drawing board 41 rotates back to an original position by the pressurization of the torsion spring 81. FIG. Further, the handle 6 is rotated in the off direction (counterclockwise direction) by the pressure of the torsion spring.

In the circuit breaker of this embodiment, the winding 68A, 68B is wound side by side in the axial direction of the coil bobbin 69 in the same coil bobbin 69, and the coil bobbin 69 is downsized in the radial direction compared with the conventional example. Since the base body 1 which accommodates the coil bobbin 69 can be downsized in the width direction, the circuit breaker downsized in the width direction can be provided as a result. In addition, when assembling the electromagnetic release portion 47, it is only necessary to arrange and wind the windings 68A and 68B with respect to the coil bobbin 69. The assembling becomes easier as compared with the case of assembling the bobbin. Moreover, since the coil bobbin 69 can be made into a longitudinal length, when the coil bobbin 69 is arrange | positioned sideways like this embodiment, the height dimension of a circuit breaker can be made low.

Further, by winding the windings 68A and 68B in the same direction with respect to the coil bobbin 69, for example, even when a short circuit accident occurs in the case of a short circuit, the direction of the magnetic field generated in the fixed iron core 57 is the same. Therefore, the suction of the movable iron core 58 is not disturbed, and the circuit breaker can be reliably protected.

In addition, in this embodiment, the case where the winding 68A, 68B was wound by the coil bobbin 69 so that clock rotation may be seen from the left side in FIG. 6 was demonstrated as an example, but the winding 68A, 68B is a coil bobbin 69. As shown in FIG. ) May be wound in the same direction, and the windings 68A and 68B may be wound so as to be counterclockwise as viewed from the left side in FIG. 6.

1 is a side view showing a closed electrode state of a circuit breaker according to the present embodiment, with the gas member on the left side removed;

Fig. 2 is a side view of the open circuit state of the circuit breaker of the present embodiment, with the gas member on the left side removed.

3 is a side view of a state in which the circuit breaker of the present embodiment is tripped, and the gas member on the left is removed;

4 is a perspective view of a circuit breaker of the present embodiment;

5 is a right side view of the circuit breaker of the present embodiment;

6 is a partially broken cross-sectional view of the circuit breaker of the present embodiment as seen from below;

7A and 7B are perspective views of a crossbar used for the circuit breaker of the present embodiment.

※ Explanation of code for main part of drawing

1: gas 1A, 1B: gas absence

2A, 2B: fixed contact 3A, 3B: movable contact

5: opening and closing mechanism 47: electronic release part

57: fixed iron core 58: movable iron core

68A: winding (second winding) 68B: winding (first winding)

69: coil bobbin

Claims (2)

A body provided with a load connecting portion to which a load is connected and a power connecting portion to which a power source is connected, A contact portion comprising a fixed contact and a movable contact provided in a converter between the load contact and the power supply contact; An opening and closing mechanism for contacting and separating the contact portion; An electromagnetic release portion having a movable iron core attracted by a magnetic force generated on a magnetic pole surface of a fixed iron core when an excessive current flows in the converter, and forcibly opening the contact portion via the opening / closing mechanism by the movable iron core; Equipped, The electromagnetic release portion is a winding that generates a magnetic field, and is generated when the leakage current flows through the converter and is energized by a first winding that excites the fixed iron core, and a current flowing through the converter and a short circuit current flows through the converter. It has a 2nd winding which performs a release operation by magnetic force, The said 1st and 2nd winding were wound side by side in the axial direction in the same bobbin, It characterized by the above-mentioned.  Circuit breaker. The method of claim 1, The first and second windings are wound in the same direction, characterized in that Circuit breaker.

Images