JP5588337B2 - Circuit breaker - Google Patents

Description

  The present invention relates to a circuit breaker.

  2. Description of the Related Art Conventionally, there is a circuit breaker in which a contact portion can be switched between an open state (a state where the contact is open) and a closed state (a state where the contact is closed) by a handle operation. In the circuit breaker, as shown in FIG. 12, the contact portion is in an open state or a closed state, or an abnormal current is detected and the contact portion is forcibly opened (trip). There is also a display member 26 that displays whether or not (state) (see Patent Document 1, for example).

  The display member 26 has a display plate 260 that is rotatably provided in the body of the circuit breaker, is provided at a position facing a window hole (not shown) formed in the body, and displays a contact state. ing. The display plate 260 is formed in a substantially rectangular plate shape along the rotation direction, and slits 26a are formed in the vicinity of both ends in the width direction orthogonal to the rotation direction from one side to the other side in the rotation direction. Has been.

  At both ends in the width direction of the display panel 260, elastic pieces 261 whose tip portions are elastically deformable toward the slit 26a are formed. The elastic piece 261 is formed in a substantially rod shape, and a bulging portion 263 that bulges outward in the width direction is formed at the tip.

  Further, between the pair of elastic pieces 261, a trip display unit 26A indicating a trip state, an off display unit 26B indicating an open state, and an on display unit 26C indicating a closed state are sequentially provided along the rotation direction. A display portion 262 is formed. The display member 26 passes from the trip position where the trip display portion 26A faces the window hole to the off position where the off display portion 26B faces the window hole and the on position where the on display portion 26C faces the window hole. The moving range is set. Here, the display units 26A to 26C are formed, for example, by color-coding the display unit 262 with three different colors.

  When the circuit breaker is changed from the closed state to the open state by the handle operation, the display member 26 rotates from the on position to the off position in accordance with the handle operation. It engages with a restricting protrusion 271 standing on the inner surface of the body. Thereby, the display member 26 is restricted from turning to the trip position side.

  In addition, when an abnormal current flows through the contact portion in the closed state, the display member receives the spring force of a spring (not shown) and rotates more rapidly toward the trip position than when the display member rotates with the handle operation. To do. Then, the bulging portion 263 comes into contact with the restricting protrusion 271, the elastic piece 261 is bent inward, the bulging portion 263 gets over the restricting protrusion 271, and the display member 26 rotates to the trip position.

JP 2009-212065 A

  However, in the above circuit breaker, the slit 26a and the bulging portion 263 are formed on the display plate 260 in order to display the display member 26 on a trip, so that the structure of the display plate 260 becomes complicated and the manufacturing cost increases. There was a problem. In addition, since the bulging portion 263 rides over the restriction protrusion 271 while being in sliding contact with the restriction protrusion 271, at least one of the protrusion 263 and the restriction protrusion 271 may be worn. In that case, the engagement between the bulging portion 263 and the restricting protrusion 271 becomes insufficient, and there is a possibility that the display member 26 rotates to the trip position and an incorrect display is made despite the open state. there were.

  Moreover, since the elastic piece 261 bends at the time of a trip, there existed a possibility that the erroneous indication which shows a trip state might be performed, although the said elastic piece 261 raise | generates fatigue deformation, for example, although it is a contact open state.

  The present invention has been made in view of the above reasons, and an object of the present invention is to provide a circuit breaker capable of performing trip display with a simple structure and preventing erroneous display.

  In order to solve the above-mentioned problems, a circuit breaker according to the present invention includes a container having a window hole, a fixed contact, and a movable contact that contacts and separates from the fixed contact. A closed position where the movable contact is brought into contact with the fixed contact and the movable contact. A handle that rotates between an opening position that is spaced apart from the fixed contact, a link mechanism that moves the movable contact to and away from the fixed contact according to a rotation operation of the handle, and A trip mechanism that performs a trip operation that opens the contact portion during a trip that detects a flowing abnormal current, and one end side is fixed to the handle, and the handle is biased in a direction to rotate from the closed position to the open position. Han consisting of torsion coils A spring display, a trip display portion that is rotatably supported by the body, and indicates that the trip operation has been performed; an off display portion that indicates an open state of the contact portion; and a closing of the contact portion An on-display unit indicating a state is provided, and the trip-display unit faces the window hole from the on-position where the on-display unit faces the window hole, and the off-display unit passes the off-position facing the window hole. A display member that rotates to a position, and a biasing spring that includes a torsion coil that presses the display member and biases the display member in a direction to rotate from an on position to a trip position. The member is formed with a restricting protrusion that engages with the other end side of the handle spring at the off position to restrict the rotation of the display member toward the trip position side, and at the time of the trip, the other end of the handle spring is formed. Side is due to the link mechanism The engagement being displaced is released Te, wherein the display member, characterized in that rotates from the ON position to the trip position.

  In this circuit breaker, the link mechanism includes a thrust bar, one end of which is rotatably supported by the handle, and the other end of the thrust bar, which is rotatably supported by the container body, And a latch member that engages with the other end of the thrust bar when the handle is in a closed position, and the latch member is rotated during the trip so that the latch member and the thrust bar are engaged with each other. When the latch member is released and rotated to the other side, the other end of the thrust bar rotates around one end to contact the other end of the handle spring, and the other end of the handle spring Is preferably displaced.

  The present invention has an effect of providing a circuit breaker that can perform trip display with a simple structure and can prevent erroneous display.

The schematic which removed the 1st half of the circuit breaker in embodiment is shown. The principal part enlarged view of the ON state of the circuit breaker in the same as the above is shown. The principal part enlarged view of the trip state of the circuit breaker in the same as the above is shown. The schematic perspective view of the circuit breaker in the same as the above is shown. The external view of the circuit breaker in the same as above is shown. The perspective view of the handle spring with which the circuit breaker in the same as the above is provided is shown. The principal part enlarged view of the circuit breaker in the same as the above is shown. The perspective view of the support arm with which the circuit breaker in the same as the above is provided is shown. The perspective view of the display member with which the circuit breaker in the same as the above is provided is shown. The perspective view of the display member with which the circuit breaker in the same as the above is provided is shown. The principal part enlarged view at the time of the trip of the circuit breaker in the same as the above is shown. The perspective view of the display member with which the circuit breaker in a prior art example is provided is shown.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiment)
A first embodiment of the present invention will be described with reference to the drawings.

  In this embodiment, the current can be turned on, turned on, and turned off under normal circuit conditions, and the current can be turned on, turned on for a certain period of time and turned off under defined abnormal circuit conditions such as a short circuit. It is a vessel. In the following, description will be made with reference to the vertical and horizontal directions in FIG.

  As shown in FIGS. 1, 4, and 5, the circuit breaker according to the present embodiment includes a container body 10 including a first half 11 and a second half 12, a contact mechanism including a fixed contact 130 and a movable contact 132. 13 and a handle 140 having an operation knob 14a, the link mechanism 14 configured to turn on and off the electrical connection between the fixed contact 130 and the movable contact 132 via the handle 140, and the fixed contact 130. When an abnormal current (short-circuit current and overload current) is detected between the movable contact 132 and the trip mechanism (electromagnetic release means 150 and thermal release means 151) that causes the link mechanism 14 to perform a trip operation to forcibly open the contact. ), A synthetic resin display member 16 for displaying the on / off state of the contact, and an arc extinguishing for quickly extinguishing the arc generated when the contact is opened Device 17, a first terminal block 18 for electrically connecting a first external electric wire or the like (not shown), and a second external electric wire or the like (not shown) for electrically connecting A second terminal block 19.

  The circuit breaker of the present embodiment takes different states as shown in FIGS. As the different states that can be taken by the circuit breaker of the present embodiment, first, there is an off state in which the movable contact 132 is separated from the fixed contact 130 and the operation knob 14a of the handle 140 is on the right side as shown in FIG. Further, there is an ON state in which the movable contact 132 contacts the fixed contact 130 and the operation knob 14a of the handle 140 is on the left side as shown in FIG. Further, there is a trip state in which the movable contact 132 is separated from the fixed contact 130 and the operation knob 14a of the handle 140 is on the right side of the off state as shown in FIG.

  As shown in FIG. 5, the container 10 includes two round hole-shaped tool insertion openings 100 and 100. Screw stoppers 101 are formed in the back of the tool insertion slot 100, respectively. Moreover, the container 10 is provided with the 1st insertion port 102, the 2nd insertion port 103, and the exhaust port 104 in the both right and left sides, respectively. The vessel body 10 includes an operation opening 105 at the top. A rectangular window hole 11 o is formed in the upper portion of the first half 11. The side portion including the first insertion port 102 determines the thickness of the vessel body 10, and the left and right side portions where the first insertion ports 102 and 102 are provided determine the length of the vessel body 10. The circuit breaker of the present embodiment is used with the upper part where the operation opening 105 is formed as the front side.

  The first half 11 and the second half 12 constituting the container body 10 are each formed in a box shape with one surface opened by an insulating synthetic resin. As shown in FIG. 4, through holes 11 a are formed at the four corners and the center of the inner wall portion of the first half 11. Further, the left and right side walls of the first half 11 are provided with locking portions 11b and 11b having openings, respectively. Bosses (not shown) project from the four corners and the center of the inner wall of the second half 12. Further, as shown in FIG. 5, locking claws 12 b are provided on the left and right side walls of the second half 12, respectively. The first half 11 and the second half 12 align the opening edges of the respective openings, and the bosses of the second half 12 are inserted into the through holes 11a of the first half 11, respectively. Each latching portion 11b is hooked and latched.

  The tool insertion opening 100 of the container 10 includes a semicircular concave groove 11 c provided at the upper opening edge of the first half 11 and a semicircular concave groove provided at the upper opening edge of the second half 12 ( (Not shown). The screw stopper 101 is formed by a rib 11e provided on the inner wall portion of the first half 11 and a rib (not shown) provided on the inner wall portion of the second half 12. Each of these ribs is formed with a concave groove that is recessed in a semicircular shape. The first insertion port 102 has a square hole-like concave groove 11 g provided at the opening edges of the left and right side walls of the first half 11 and a square hole shape provided at the opening edges of the left and right side walls of the second half 12. Are respectively formed by recesses (not shown). The second insertion port 103 has a square hole-like concave groove 11 i provided at the opening edge of the left and right side walls of the first half 11 and a square hole shape provided at the opening edge of the left and right side walls of the second half 12. Are respectively formed by recesses (not shown). The exhaust port 104 has a square hole-like concave groove 11k provided at the opening edges of the left and right side walls of the first half 11, and a square hole-like concave groove provided at the opening edges of the left and right side walls of the second half 12. (Not shown), respectively. The operation opening 105 is formed by a rectangular hole-shaped concave groove 11 n provided at the opening edge of the upper portion of the first half 11 and the opening edge of the second half 12.

  As shown in FIG. 1, the contact mechanism 13 includes a fixed contact plate 134 provided with a fixed contact 130 and a movable bar 136 provided with a movable contact 132. The fixed contact plate 134 and the movable bar 136 are formed by punching and bending a metal plate having a predetermined thickness.

  The fixed contact plate 134 includes a fixed contact 130 and is fixed at a predetermined position in the container 10.

  The movable bar 136 is T-shaped, and a movable contact 132 is provided at the bottom. Further, as shown in FIG. 1, a spring receiving piece 136a is provided on the left side of the upper portion of the movable bar 136, and a stopper piece 136b is provided on the right side of the upper portion as shown in FIG. One end of a braided wire 137 is fixed to an intermediate portion in the longitudinal direction of the movable bar 136. The movable bar 136 can move between the position where the movable contact 132 contacts the fixed contact 130 and the position where the movable contact 132 separates from the fixed contact 130 by interlocking with the link mechanism 14. ing.

  Next, the structure of the link mechanism 14 will be described with reference to FIGS. The link mechanism 14 includes a handle 140, a support arm 141, a latch member 142, first and second interlocking links 143 and 144, a latch spring 145, a link spring 146, a handle spring 147, and a pressure spring 148. And first and second rotating shafts 14e and 14o.

  The handle 140 is formed of a synthetic resin in a cylindrical shape, and a substantially rectangular parallelepiped operation knob 14a is formed on the outer peripheral surface thereof. The support arm 141 and the latch member 142 are formed by punching and bending a metal plate having a predetermined thickness. The thrust bar 143 and the stop bar 144 are formed in a substantially U shape by bending both ends of a round bar-shaped metal bar in one direction. Each of the latch spring 145, the link spring 146, the handle spring 147, and the pressure spring 148 is formed of a torsion coil spring having both ends protruding in opposite directions. The first rotation shaft 14e and the second rotation shaft 14o are each formed from a round bar-shaped metal rod.

  A shaft hole 14b is formed in the handle 140, and a long hole-shaped guide groove 14c is formed on the front surface along the circumferential direction. The handle 140 is rotatably supported by a handle shaft 11 p provided in the first half 11 with a shaft hole 14 d in a state where the operation knob 14 a is exposed from the operation opening 105 of the container body 10. Then, the operation knob 14a is rotatable between an opening position (right side in FIG. 1) for opening the contact mechanism 13 and a closing position (left side in FIG. 1) for closing the contact mechanism 13. ing.

  As shown in FIG. 6, the handle spring 147 includes a winding portion 147a, one end portion 147b extending from one end of the winding portion 147a in one direction orthogonal to the axial direction, and the other end of the winding portion 147a. The other end portion 147c is formed in a crank shape extending in the other direction orthogonal to the axial direction. Here, the other end portion 147c includes an extending piece 147d extending from the other end of the winding portion 147a, an engaging piece 147e formed by bending the tip of the extending piece 147d by approximately 90 degrees, It is comprised from the bending piece 147f by which the front-end | tip of the piece 147e is bent about 90 degree | times.

  The handle spring 147 is disposed between the handle 140 and the first half 11, and as shown in FIG. 1, the handle shaft 11p is inserted through the winding portion 147a. Further, one end 147 b of the handle spring 147 is locked to an arc-shaped rib 140 a formed along the outer edge of the handle 140.

The extension part 147c itself functions as a spring, and the extension piece 147d is locked to the groove part 11r of the semi-cylindrical rib 11m provided in the first half 11, as shown in FIG. Here, the extending portion 147 extends to the vicinity of an engaging portion A described later, and is disposed between the engaging portion A (see FIG. 7) and the display member 16.
Here, the handle spring 147 is biased in a direction in which the diameter of the central hole is increased. The handle 140 is elastically urged in the direction from the closed position toward the open position (clockwise direction in FIG. 1) by the urging force of the handle spring 147.

  As shown in FIG. 8, the support arm 141 includes a first side plate 141a on the first half 11 side, a second side plate 141b on the second half 12 side, and an intermediate for connecting the first side plate 141a and the second side plate 141b. And a piece 141c. From the upper end of the second side plate 141b, there is formed an engagement protrusion 141d extending obliquely upward. In addition, a substantially L-shaped projecting piece 141e with a tip projecting upward is formed at a substantially center of the side edge of the first side plate 141a. The intermediate piece 141c connects the upper end of the side edge of the first side plate 141a and the upper end of the side edge of the second side plate 141b. Further, an engaging piece 141f facing the stopper piece 136b of the movable bar 136 is formed to project downward from the lower end of the intermediate piece 141c.

  Two insertion holes 141g and 141h are formed in the first side plate 141a and the second side plate 141b of the support arm 141 along the vertical direction from above. And the 2nd rotating shaft 14o is penetrated by each penetration hole 141g. The second rotation shaft 14 o is fixed to a shaft hole 11 h provided in the inner wall surface of the first half 11 and a shaft hole (not shown) provided in the inner wall surface of the second half 12.

  The upper part of the movable bar 136 is interposed between the first side plate 141a and the second side plate 141b of the support arm 141. Then, the first rotating shaft 14e is inserted through an insertion hole (not shown) formed in the movable bar 136 and an insertion hole 141h of the support arm. Accordingly, when the support arm 141 rotates around the second rotation shaft 14o, the movable bar 136 moves together with the support arm 141. The first rotating shaft 14e is configured to be fitted to an arcuate guide rib 11r provided on the inner wall of the first half 11, and to move along the guide rib 11r. The support arm 141 includes a separation position (see FIG. 1) where the first rotation shaft 14e is farthest from the fixed contact 130, and a contact position where the first rotation shaft 14e approaches the fixed contact 130 (see FIG. 2). ) Around the second rotation shaft 14o.

  As shown in FIG. 1, the pressure spring 148 has a second rotating shaft 14o inserted through the winding portion 148a, one end portion 148b abutting against a spring receiving projection (not shown) provided in the first half 11, and the other end. The portion 148c contacts the spring receiving piece 136a on the left side of the movable bar 136. The pressurizing spring 148 applies an urging force to the movable bar 136 in the direction from the movable contact 132 toward the fixed contact 130 around the first rotation shaft 14e (the direction rotating counterclockwise in FIG. 1). ing. Further, when the stopper piece 136b of the movable bar 136 is in contact with the engaging piece 141f of the support arm 141, the clock shown in FIG. 2 is rotated around the second rotation shaft 14o with respect to the movable bar 136 and the support arm 141. A biasing force in the direction of rotating around is applied.

  As shown in FIG. 7, the latch member 142 includes an L-shaped claw piece 142a on one upper end side (left side in FIG. 7) and an L-shaped spring receiving piece 142b on the other upper side (right side in FIG. 7). Is provided. Further, a first pressing piece 142c extends from the lower reporting side edge of the latch member 142, and a substantially L-shaped second pressing piece 142d extends from the other lower side edge of the latch member 142. The latch member 142 has a second rotation shaft 14o inserted through substantially the center thereof, and is pivotally supported around the second rotation shaft 14o. The first rotating shaft 14e is engaged with a substantially rectangular cutout 142e formed at the lower end.

  In the thrust bar 143, the upper leg portion 143a is pivotally supported in a shaft hole 14b provided in the handle 140, and the lower leg portion 143b is engaged with the claw piece 142a on the latch member 142 and the upper portion of the support arm 141. Engageably engages with an engaging portion A composed of the projecting piece 141d.

  In the stop bar 144, the upper leg portion 144a is engaged with the guide groove 14c provided in the handle 140, and the lower leg portion 144b is hooked and locked to the engagement piece 141f of the support arm 141.

  The latch spring 145 is provided so that the second rotating shaft 14 o is inserted into the winding portion, one end is locked to the spring receiving piece 142 b of the latch member 142, and the other end is in contact with the display member 16. The latch spring 145 applies a biasing force in the direction of rotating clockwise around the second rotation shaft 14o to the latch member 142 in FIG.

  As shown in FIG. 7, the link spring 146 has the handle shaft 11 p inserted through the winding portion and one end abutting against the handle 140. Further, the other end portion of the link spring 146 contacts the upper leg portion of the stop bar 144, and the stop bar 144 is elastically biased in one direction (right direction in FIG. 7) in the guide groove 14c.

  As shown in FIG. 1, the electromagnetic release means 150 as a trip mechanism includes a coil 152 made of a rectangular winding, a coil bobbin 153, a fixed iron core (not shown) made of a magnetic material, and a movable iron core (not shown). ), An urging spring (not shown), a pressing pin 154, and a yoke 155. A fixed contact plate 134 is fixed to one end of the coil 152. The pressing pin 154 is coupled to the movable iron core. The yoke 155 is formed of a magnetic material into a hollow rectangular frame shape having a notch, and the coil bobbin 153 is disposed so as to be surrounded by the yoke 155. An insertion hole 15a (see FIG. 4) through which the pressing pin 154 is inserted is formed on the left side of the yoke 155. In the electromagnetic release means 150, when no current is flowing through the coil 152, the movable iron core is separated from the fixed iron core by the urging force of the return spring, and the pressing pin 154 connected to the movable iron core has the right end in FIG. It is comprised so that it may reverse | retreat to the position of. When an excessive current such as a short circuit current flows through the coil 152, the movable iron core moves so as to approach the fixed iron core against the biasing force of the return spring, and the pressing pin 154 connected to the movable iron core moves to the left. Project to And the front-end | tip part of the press pin 154 presses the 1st press piece provided in the lower right side of the latch member 142 to the left side.

  As shown in FIG. 1, the thermal release means 151 that is a trip mechanism includes a strip-shaped bimetal plate 156. As the bimetal plate 156, a direct heating type that is curved by self-heating or a side heating type that is laminated with plate-like heaters and is curved by heating with the heater can be used. The bimetal plate 156 is fixed to the other end of the braided wire 137 whose one end is fixed to the movable bar 136 at an intermediate position. One end of a braided wire 138 (see FIG. 1) is fixed to the lower part of the bimetal plate 156. The bimetal plate 156 is not curved during normal times. When an excessive current such as an overload current flows, the temperature of the bimetal plate 156 increases due to the overload current. Thereby, the bimetal plate 156 is curved, and the tip of the bimetal plate 156 presses the second pressing piece 142d of the latch member 142 to the left side.

  As shown in FIG. 10, the display member 16 includes a substantially trapezoidal plate-like base plate 161 having a rotation hole 16 a formed on the lower end side, and a substantially fan-shaped extending portion extending from the upper end of the base plate 161. 162 and a display portion 163 formed along the upper edge of the extended portion 162.

  The base plate 161 has a substantially rectangular parallelepiped contact piece 16d formed on one end of one surface thereof, and a substantially semicircular cutout 16b formed on the side edge on the other end of the one surface. And from the lower end of the notch 16b, the locking piece 164 extended toward the other surface side of the base board 161 and extended further is formed. The locking piece 164 has a locking projection 16c formed substantially at the center of its tip. The locking projection 16c is formed to be inclined toward one side (right side in FIG. 2) in the rotation direction of the display member 16 as it goes upward.

  The display part 163 is formed substantially perpendicular to the extended part 162 and is formed in a substantially rectangular plate shape along the rotation direction. As shown in FIG. 9, the display surface 160 on the upper surface of the display unit 163 has a trip display unit 16 </ b> A indicating the trip state of the contact mechanism 13, an off display unit 16 </ b> B indicating the open state of the contact mechanism 13, and the contact mechanism. On-display portions 16 </ b> C indicating thirteen closed states are sequentially formed along the rotation direction of the display member 16. Here, the display units 16A to 16C are formed by coating the display unit 160 with different colors, for example.

  The display member 16 is pivotally supported by the container body 10 with the second rotation shaft 14o inserted through the rotation hole 16a. Also. The display member 16 is biased in a direction in which the contact piece 16d is pressed against the other end of the latch spring 145 and rotates in one direction (clockwise direction in FIG. 1). When the handle 140 is in the open position, the locking piece 147e of the handle spring 147 abuts (engages) with the locking protrusion 16c of the display member 16, thereby causing the display member 16 to trip (see FIG. (Clockwise direction in 1) is restricted and stops at the off position. At this time, the off display portion 16B faces the window hole 11o.

  Here, since the locking protrusion 16c is formed as described above, it has an acute gap S between the locking protrusion 16c and the upper edge of the locking piece 164 (see FIG. 10). Is formed. And in the OFF position, the latching piece 147e fits in the clearance S, so that the latching piece 147e is more reliably engaged.

  As shown in FIG. 1, the arc extinguishing device 17 includes an arc travel plate 170 and an arc extinguishing grid 171. The arc traveling plate 170 is formed by bending a strip-shaped metal plate. The arc traveling plate 170 has a base portion of a bimetal plate 156 coupled to one end and an arc extinguishing piece 172 at the other end. The arc extinguishing grid 171 is composed of an arc extinguishing plate 173 composed of a plurality of conductive plates arranged in parallel in the vertical direction at a predetermined interval, and two support plates 174 and 174 formed of an insulating material. Yes. The support plates 174 and 174 cover the both sides of the arc extinguishing plates 173 in the width direction and hold the arc extinguishing plates 173 at a predetermined interval. The arc extinguishing grid 171 is disposed between the arc extinguishing piece 172 and the lower side of the yoke 155. Since the arc extinguishing device 17 can be a conventionally known one, a detailed description thereof will be omitted.

  The first and second external electric wires and the like are connected to the first terminal block 18 or the second terminal block 19, respectively. As shown in FIG. 1, the first terminal block 18 is formed in a hollow rectangular frame shape by a fixed terminal 180 formed in a square bracket shape by a metal plate and fixed to the vessel body 10, and a rectangular metal piece. The movable terminal frame 181, a stopper 182 made of synthetic resin, and a terminal screw 183 are provided. The second terminal block 19 has the same structure as the first terminal block 18, and includes a fixed terminal 190, a movable terminal frame 191, a stopper 192, and a terminal screw 193.

  The other end of the braided wire 138 having one end fixed to the lower portion of the bimetal plate 156 is fixed to the fixed terminal 180 of the first terminal block 18, and the fixed terminal 190 of the second terminal block 19 is connected to the fixed terminal 190 of the coil 152. One end is fixed. With this configuration, when the movable contact 132 is closed to the fixed contact 130, the fixed terminal 180 of the first terminal block 18-braided wire 138-bimetal plate 156-braided wire 137-movable bar 136-movable contact 132-fixed. An electric circuit is formed by the path of the contact 130, the fixed contact plate 134, the coil 152, and the fixed terminal 190 of the second terminal block 19.

  Next, operation | movement of the circuit breaker of this embodiment is demonstrated, referring FIGS.

  First, the operation of each part when the handle 140 is rotated from the open position (see FIG. 1) to the closed position (see FIG. 2) will be described. When the handle 140 is rotated counterclockwise from the open position, the lower end 143b of the thrust bar 143 presses the engagement protrusion 141d of the support arm 141 to the left. As a result, the support arm 141 rotates counterclockwise around the second rotation shaft 14o. At this time, the movable bar 136 pivotally supported by the first rotation shaft 14e also moves to the right side together with the support arm 141. Here, when the upper leg portion 144a of the stop bar 144 is on the left side of the straight line connecting the lower leg portion 144b and the handle shaft 11p, the stop bar 144 is moved downward by the rotation of the handle 140. At this time, the lower leg portion 144b of the stop bar 144 presses the stopper piece 136b of the movable bar 136 downward. That is, the movable bar 136 is pressed in the clockwise direction from the lower leg portion 144b of the stop bar 144 while receiving the counterclockwise biasing force around the first rotation shaft 14e by the pressure spring 148. From this state, when the handle 140 is further rotated counterclockwise and the upper leg portion 144a of the stop bar 144 moves to the left side of the straight line connecting the lower leg portion 144b and the handle shaft 11p, the stop bar 144 moves upward. Be raised. At this time, the lower leg portion 144b of the stop bar 144 moves upward, and the movable bar 136 is not pressed against the stopper piece 136b. When the pressure disappears, the movable bar 136 rapidly rotates counterclockwise around the first rotation shaft 14e by the biasing force of the pressure spring 148. Then, the movable contact 132 abuts against the fixed contact 130 vigorously. Thereby, the movable contact 132 comes into contact with the fixed contact 130 in a short time, and the generation of the arc can be suppressed. The latch member 142 rotates counterclockwise by the biasing force of the latch spring 145. Further, the contact member 16d of the display member 16 is pressed upward by the intermediate piece 141c of the support arm 141, and rotates counterclockwise around the second rotation shaft 14o. Rotates to the on position facing 11o.

  Next, the operation of each part when the handle 140 is rotated from the closed position (see FIG. 2) to the open position (see FIG. 1) will be described. When the handle 140 is rotated clockwise from the closed position, the lower leg portion 143b of the thrust bar 143 is pulled upward. As a result, the force with which the thrust bar 143 presses the support arm 141 is eliminated. The movable bar 136 is rotated counterclockwise around the first rotation shaft 14e by the biasing force of the pressure spring 148, and the support arm 141 is rotated by the second rotation shaft 14o by the biasing force of the pressure spring 148. Rotate clockwise around The support arm 141 stops at a position where the first rotation shaft 14e has moved to the end position of the guide rib 11r, and the movable bar 136 stops at a position where the stopper piece 136b contacts the engagement piece 141f of the support arm 141. . Then, the movable contact 132 is separated from the fixed contact 130. Here, the handle 140 is biased by the handle spring 147 in a direction toward the opening position (clockwise direction). When the upper leg portion 143a of the thrust bar 143 passes the line connecting the handle shaft 11p and the lower leg portion 143b of the thrust bar 143 from right to left, the handle 140 is rapidly rotated in the direction toward the opening position. As a result, the movable contact 132 is rapidly detached from the fixed contact 130, and the generation of an arc can be suppressed. The latch member 142 is pulled by the lower leg portion 143b of the thrust bar 143 and rotates clockwise around the second rotation shaft 14o. Further, the display member 16 is rotated from the on position to the off position by the urging force of the latch spring 145, and the locking piece 147e of the handle spring 147 contacts the locking protrusion 16c of the display member 16 at the off position. Contact (engage). Thereby, the rotation of the display member 16 toward the trip position side (clockwise direction in FIG. 1) is restricted and the rotation is stopped, and the off display portion 16B faces the window hole 11o.

  Further, each part when the electromagnetic release means 150 or the thermal release means 151 detects an abnormal current to shift from the ON state (see FIG. 2) to the trip state (see FIG. 3) in which the contact is forcibly opened. Will be described.

  When the electromagnetic release means 150 or the thermal release means 151 detects an abnormal current, the first pressing piece 142c of the latch member 142 is pressed by the pressing pin 154, or the second pressing piece 142d is pressed by the bimetal plate 156. . Then, the latch member 142 rotates clockwise around the second rotation shaft 14o, and the pressing by the lower leg portion 143b of the thrust bar 143 against the second side plate 141b of the support arm 141 is eliminated. Then, the movable bar 136 and the support arm 141 are moved around the second rotation shaft 14o by the urging force of the pressure spring 148 in a state where the stopper piece 136b of the movable bar 136 is in contact with the engagement piece 141f of the support arm 141. To rotate clockwise. As a result, the movable contact 132 is separated from the fixed contact 130. At that time, as shown in FIG. 11, the lower leg portion 143 b of the thrust bar 143 rides on the spring receiving piece 142 b of the latch member 142. Thus, the thrust bar 143 rotates clockwise around the upper leg portion 143a, and the lower leg portion 143b comes into contact with the extension portion 147c of the handle spring 147 from below to bring the extension portion 147c upward. Displace. Here, the thrust bar 143 is prevented from excessively rotating in the clockwise direction in FIGS. 2 and 3 (counterclockwise in FIG. 11) by the lower leg portion 143b coming into contact with the extending piece 147c.

  Further, the display member 16 is rotated clockwise from the ON position by the urging force of the latch spring 145. Here, since the other end portion 147c of the handle spring 147 is pushed up by the lower leg portion 143b of the thrust bar, the display member 16 has the engagement protrusion 16c engaged with the engagement piece 147e of the handle spring 147. Instead, it further turns clockwise through the off position. The display member 16 is rotated to the trip position and the display unit 160 comes into contact with the handle 140 to stop the rotation. The trip display unit 16A faces the window hole 11o.

  After the trip operation is completed, the handle 140 rotates clockwise to the open position by the biasing force of the handle spring 147. Here, the lower leg portion 143 b of the thrust bar 143 is pressed downward by the restoring force of the other end portion 147 c of the handle spring 147. Accordingly, the lower leg portion 143b of the thrust bar 143 moves to the right along the spring receiving piece 142b of the latch member 142 and comes into contact with the claw piece 142a. That is, the lower leg portion 143b of the thrust bar 143 automatically returns to the engaging portion A by the restoring force of the extending portion 147c in the handle spring 147.

  In the trip state, by rotating the handle 140 to the closed position, each part operates in the same manner as when the handle 140 is rotated from the open position to the closed position, and the closed state is established. Can do. At that time, the display member 16 is rotated counterclockwise in accordance with the handle operation, and the obtuse angle P (see FIG. 3) formed between the locking protrusion 16c of the display member 16 and the locking piece 164 is observed. The locking piece 147e of the handle spring 147 slides. Thereby, the display member 16 can be smoothly returned from the trip position to the closed position.

  As described above, the circuit breaker according to the present embodiment merely forms the locking protrusion 16c on the display member 16, and further bends the other end 147c of the handle spring 147 to form the locking piece 147e. In addition, the configuration in which the display member 16 displays a trip can be easily realized. Therefore, unlike the circuit breaker in the conventional example, the display member 16 does not have a complicated configuration in which the slit 26a and the bulging portion 263 are provided, and the display member 16 can be configured simply and the manufacturing cost can be reduced. be able to.

  Further, since the locking piece 147c of the handle spring 147 is displaced at the time of trip, it does not contact the locking projection 16c of the display member 16, so the locking piece 147e and the locking projection 16c are not worn. Incorrect display can be prevented.

  The operation when shifting from the state after the end of the trip operation to the on state is the same as that when shifting from the off state to the on state, and thus the description thereof is omitted.

  In addition, since the extended portion 147c has elasticity, the lower leg portion 143b of the thrust bar 143 that is detached from the engaging portion A automatically returns to the engaging portion A by the restoring force of the extended portion 147c. The return from the trip state is performed smoothly.

  Further, in the circuit breaker according to the present embodiment, the lower leg portion 143b of the thrust bar 143 is not in direct contact with the display member 16, and the load applied to the display member 16 can be reduced. Can be prevented, and the failure of the circuit breaker can be suppressed.

10 Body 11o Window hole 13 Contact mechanism (contact part)
14 Link mechanism 14a Operation knob (operation unit)
16 Display member 16c Locking protrusion 140 Handle 143 Thrust bar 145 Latch spring (biasing spring)
147 Handle spring 147e Locking piece 150 Electromagnetic release means (trip mechanism)
151 Thermal release means (trip mechanism)

Claims (2)

A vessel formed with a window hole;
A contact portion provided in the body with a fixed contact and a movable contact contacting and separating from the fixed contact;
An operating portion exposed to the outside of the container body is rotatably supported with respect to the container body, and a closed position for bringing the movable contact into contact with the fixed contact and the movable contact from the fixed contact A handle that pivots between an open position to be spaced apart;
A link mechanism for moving the movable contact toward and away from the fixed contact in accordance with the turning operation of the handle;
A trip mechanism that performs a trip operation to open the contact portion when a trip is detected that detects an abnormal current flowing in the contact portion at the time of closing;
One end side is fixed to the handle, and a handle spring comprising a torsion coil that urges the handle in a direction to rotate from the closed position to the open position,
A trip display unit that is rotatably supported by the container and indicates that the trip operation has been performed, an off display unit that indicates an open state of the contact unit, and an on state that indicates a closed state of the contact unit A display unit is provided, and from the ON position where the ON display unit faces the window hole to the trip position where the OFF display unit passes through the OFF position facing the window hole and the trip display unit faces the window hole. A display member that rotates
A biasing spring comprising a torsion coil that presses the display member and biases the display member in the direction of turning from the on position to the trip position;
The display member is engaged with the other end side of the handle spring at the off position to form a locking projection that restricts the rotation of the display member to the trip position side. The other end side of the circuit breaker is displaced by the link mechanism, the engagement is released, and the display member rotates from the on position to the trip position. The link mechanism includes a thrust bar, one end of which is rotatably supported by the handle, and the other end of the thrust bar, which is rotatably supported by the container body, so that the handle is in a closed position. A latch member that engages with the other end of the thrust bar when
The latch member is rotated during the trip to release the engagement between the latch member and the thrust bar, and with the rotation of the latch member to the other side, the other end of the thrust bar becomes one end. The circuit breaker according to claim 1, wherein the circuit breaker is rotated about the rotation center so as to contact the other end of the handle spring and displace the other end of the handle spring.

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