JP2505007B2 - Remote control breaker - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a remote control breaker having an electromagnet part that can be remotely operated.

BACKGROUND ART FIG. 10 shows a conventional remote control breaker having this type of remotely controllable electromagnet. Fixed contact 101
A handle 103 for opening and closing the movable contact 102 and a movable contact 102 is rotatably connected to a remote-controlled electromagnet section 104 via a link 105. The electromagnet section 104 is such that when power is applied to the operation terminal 106 provided outside, the coil 107 is excited and the internal plunger 108 is suction-driven. Therefore,
When the electromagnet portion 104 is driven, the handle 103 is rotated to the ON position about the shaft 109 via the link 105 by the suction operation of the plunger 108. Handle 103
When is rotated, the contacts 101 and 102 are closed by the levers 110 and 111 via the link mechanism, and at the same time, the trip mechanism is reset to prepare for the abnormal current.

In such a conventional remote control breaker, the electromagnet section
Even if 104 is operated or the handle 103 is turned on, the two are connected via the link 15, so that the contacts 101, 102 can be opened and closed. Therefore, even if the remote control is turned off to shut off the main circuit, and the work is performed, the main circuit will be energized if the handle 103 is operated on the remote control breaker side. There was a problem that became. In other words, since the main circuit can be freely opened and closed on the remote control side and the remote control breaker side, the above problems can occur.

[Object of the Invention] The present invention has been provided in view of the above points,
An object of the present invention is to provide a remote control breaker that can safely perform work on the remote control side by not energizing the main circuit unless both the breaker side and the remote control side are turned on.

DISCLOSURE OF THE INVENTION (Structure) The present invention is directed to an auxiliary contact that is turned on by turning on a handle, an external switch that is connected in series with the auxiliary contact and is installed remotely, and an overcurrent detection sensor that detects an overcurrent. And a contact portion that opens a contact by the signal of the overcurrent detection sensor, an electromagnet portion that attracts and drives the movable iron core when the external switch, the auxiliary contact, and the contact portion are both in the on state, and the movable iron core is attracted. A link mechanism that turns on the contact of the main circuit by operation, a short-circuit current detection sensor that detects a short-circuit current, and a trip mechanism that releases the latch of the link mechanism by the output of the short-circuit current detection sensor to turn off the contact of the main circuit. With the provision of the external switch and the contact portion, which are connected in series with the auxiliary contact which is turned on by turning on the handle, and which are installed remotely, The electromagnet part cannot be turned on unless the auxiliary contact, external switch, and contact part are both turned on, and when an overcurrent is detected, the signal from the overcurrent detection sensor does not go through a mechanical trip mechanism. It is characterized in that the electromagnet portion is driven to release the latch of the link mechanism and the contact of the main circuit is opened.

(Example) Hereinafter, the Example of this invention is described with reference to drawings. FIG. 2 shows an exploded perspective view of the entire breaker, and the breaker of the present invention comprises an electromagnet block A and a contact opening / closing mechanism section B controlled by the electromagnet block A. Also,
This breaker has a three-pole structure for three phases.

First, the electromagnet block A will be described. An upper surface is opened, and a storage recess 2 is formed in a box-shaped mounting base 1 made of an insulating material, and an electromagnet portion 3 is stored and arranged in the storage recess 2. The electromagnet unit 3 includes a coil 5 wound around the outer periphery of the coil bobbin 4, a fixed iron core 6, a movable iron core 7 attracted to the fixed iron core 6 by the magnetic attraction of the coil 5, and the like. The fixed iron core 6 is formed in a substantially U-shape, and the iron core portions 6a on both sides are inserted into the coil bobbin 4 through the insertion holes 8a of the damper 8.
Is inserted and arranged in the through hole 4a so that the end face of the iron core 6a slightly projects from the opening face. The movable core 7 is fixed in a U-shaped fixed plate 9, and is disposed between the movable core 7 and the coil bobbin 4 with a spring 10 interposed therebetween.
The spring 10 is mounted on a projection 4b projecting between the upper and lower projecting pieces 4c of the coil bobbin 4.

The substantially U-shaped conversion shaft 11 converts the horizontal movement of the movable core 7 in the vertical direction, and the shaft 13 is inserted into a shaft hole 11a drilled in the axial direction. This axis 13
Is a groove 14a formed on the upper surface of the step portion 14 of the mounting base 1.
Both ends thereof are rotatably supported, and the conversion shaft 11 is rotatable. A hole in the central projection 12 that is provided in the center of the conversion shaft 12.
A U-shaped pin 16 is inserted into 12a and a hole 17a of a connecting piece 17 formed in the fixing plate 9, and the conversion shaft 11 is rotatably connected to the movable iron core 7 by the U-shaped pin 16. You. Also, connecting pins 18 are inserted into holes 15a of side pieces 15 formed on both sides of the conversion shaft 11.
Are connected to each other by inserting one end 18a. Then, the electromagnet portion 3 having the above-described structure is mounted on the side surface of the fixed iron core 6 in the storage recess 2 of the mounting base 1.
It is housed and equipped with 19. A terminal storage portion 20 is formed at an end of the mounting base 1 on the side of the storage recess 2, and a notch portion 21 is formed in the terminal storage portion 20.
An auxiliary terminal 22 is attached to 21.

Next, the contact opening / closing mechanism B will be described. On the upper surface of the body 23 made of an insulating material, three mechanism housing portions 25 are formed with a partition wall 24 interposed therebetween. Interlocking plate with 3 poles and interlocking insulation
Three holes 26a are formed in the hole 26, and the movable contact 27 and the contact spring 28 are inserted into the holes 26a. A protrusion 26b is integrally provided on the lower surface of the interlocking plate 26, and the interlocking plate 26 is attached to the protrusion 26b.
The upper part of the opening spring 29 for urging 26 upward is mounted, and the opening spring 29 is attached to the body 23 as shown in FIG. 3 (b).
Are housed and arranged in a recess 30 formed therein. Link plate 26
Are inserted into the slits 31 of the partition wall 24 of the body 23 and are arranged so as to extend over the respective mechanism storage sections 25. A sensor for detecting an overcurrent or a short-circuit current is arranged in the mechanism housing portion 25, and the movable contactor 27 has a projection 37a formed by the interlocking plate 26 in a substantially U-shape as shown in FIG. 4 (b). Receives a force in the clockwise direction. Further, as shown in FIG. 4 (b), the base portion of the movable contactor 27 is urged downward by the spring 35, and therefore similarly receives a clockwise force about the protrusion 37a as an axis.
An arc horn 38 having a U-shaped tip is provided from one end of the yoke 32, and a bimetal 39 for detecting an overcurrent is provided at the other end. This bimetal 39 constitutes an overcurrent detection sensor.

Next, the contact portion 88 driven by the bimetal 39 will be described. In FIGS. 1 and 2 and FIG. 5 showing the electric circuit, the contact portion 88 arranged on the body 23 is composed of a contact arranged on a base 96 made of an insulating material. That is, the base 96 has a conductive terminal plate 89.
Is fixed, the base of the reversing spring 90 is fixed to the terminal plate 89, and the movable contact 90a is fixed to the tip of the reversing spring 90. Further, a short-circuit coil 33 is provided in a conductive bent yoke 32 in which a fixed contact 91a facing the movable contact 90a is fixed.
A drive pin 34 that can project from the upper and lower surfaces of the yoke 32 is mounted in the short-circuit coil 33. The base of the movable contactor 27 having the movable contact 36 fixed to the lower surface of the tip and the contact pressure spring 28
The base and the base are fixed together by caulking, and the contact pressure spring 28 is positioned above the movable contact 27. A conical spring 35 is interposed between the lower surface of the yoke 32 and the upper surface of the base of the contact pressure spring 28 and the like.

L-shaped mounting pieces 37 are integrally formed on both sides of the lower portion of the short-circuit coil 33 and the yoke 32 forming a magnetic circuit, and projections 37a are integrally formed on the inner sides of both mounting pieces 37 so as to project. Movable contact 27
A concave portion 27a having a lower surface depressed upward is formed at a substantially central portion of the movable contact 27 along with the contact pressure spring 28 so that the movable contact 27 is located between the two mounting pieces 37. The projection 37a of the mounting piece 37 is engaged. At this time, since the movable contactor and the contact pressure spring 28 are inserted into the hole 26a of the interlocking plate 26, the interlocking plate 26 biased upward by the opening spring 29 causes the terminal plate 91 to move.
Is fixed to the base 96. A shaft 92 is provided on the base 96, and the shaft 92 is inserted into the holes 94a of the shaft support pieces 94 formed on both sides of the movable piece 93 at substantially the center thereof so that the movable piece 93 is rotatably attached to the base 96. are doing. The movable piece 93 is located on the side of the reversing spring 90, and the pressing piece 95 formed at the tip of the movable piece 93 when the movable piece 93 rotates changes the spring piece 90b that drives the reversing spring 90 to reverse. It is designed to be pressed. When the movable piece 93 is not driven, both contacts 90a and 91a are closed as shown in FIG.
When 0 is driven in reverse, both contacts 90a and 91a are opened. Here, the terminal plate 89 is connected to the power supply side terminal, and the other terminal plate 91 is connected to the electromagnet section 3. FIG. 5 shows a circuit diagram in this case. The card 87 made of an insulating material is for interlocking the bimetal 39.
Groove 78a for inserting 39 is provided with one side open to the crocodile,
As shown in FIG. 1 (e), the endmost bimetal 39 is arranged such that the end face of the card 87 is a little distance from the crocodile.
In addition, the card 87 has a cover 80 as shown in FIG.
The card 80 is positioned between the protrusion 80b and the partition wall 24 of the body 23, and the end of the card 87 is close to or in contact with the side surface of the movable piece 93.

A frame 41 formed in a substantially U shape is shown in FIG. 3 (a).
As shown in the figure, the body 42 is
Fixed at 23. An arc-shaped long hole 44 is formed in both side plates 43 of the frame 41, and a U-shaped latch plate 48 and a leg 46 of a substantially H-shaped link 45 are located on the outer surface of the long hole 44. The rotary shaft 50 is inserted through the hole 46 a of the leg 46, the long hole 49 of the latch plate 48, and the long hole 44 of the frame 41, and is linked by the rotary shaft 50.
The 45 and the latch plate 48 are rotatably connected to the frame 41. On the other hand, a hole 48b is drilled at a substantially central portion of the side piece 48a of the latch plate 48, and a latch plate 48 is provided between the shaft support piece 51 extending upward from the lower portion of the frame 41 and the side plate 43.
Side piece 48a is located, the hole 51a of the shaft support piece 51 and the hole of the latch plate 48
By inserting the pin 52 into the hole 48a and the hole 41a of the side plate 43, the latch plate 48 is rotatably supported by the frame 41 around the pin 52.

A shaft support 53a formed at the center of the latch engagement plate 53
Are located between the projecting pieces 54 formed on the rear side of the frame 41, and the pin 55 is a hole 54a of the projecting piece 54 and a hole of the shaft support 53a of the latch engagement plate 53.
The latch engagement plate 53 is rotatably supported on a pin 55 inserted through the projecting piece 54 of the frame 41 as an axis. Three engaging portions 56 are provided on the front side of the latch engaging plate 53, and the engaging portions 56 are driven by a drive pin as shown in FIG. 4 (a).
34 is located below the head 34a and engages with the head 34a. Further, an engaging piece having an L-shaped tip from the lower surface of the latch engaging plate 53
A projection 57 is provided, and this engagement piece 57 engages with an engagement recess 58 formed in the central piece 48c of the latch plate 48, and the latch engagement plate 53
And the latch plate 48 are engaged. An arm piece 59 is formed on the front side of the frame 41, and a hole 59a is formed at the tip of the arm piece 59.
Is perforated. The lower part of the handle 60 is located between the arm pieces 59, the handle shaft 61 is inserted through the hole 59a of the arm piece 59 into the hole 60a drilled in the handle 60, and the handle 60 is inserted into the frame 4
The handle shaft 61 is attached to the shaft 1 so as to be rotatable. A protrusion 60b is provided so as to project from the side surface of the handle 60, and one end of a reversing spring 62 for positioning the OFF position and the ON position of the handle 60 beyond the dead center is locked to the protrusion 60b. The latch plate 48, the latch engagement plate 53, and the like constitute a trip mechanism, and the link 45, the conversion shaft 11, and the interlocking plate.
The link mechanism is composed of 26 etc.

A notch 63 formed at the upper end of the frame 41 is engaged with a projection 64a protruding from both sides of the auxiliary contact device 64, so that the auxiliary contact device 64 is disposed on the upper portion of the frame 41. I have. An auxiliary fixed contact 66 is fixed to the lower surface of one fixed plate 65a located on the handle 60 side of the auxiliary contact device 64 as shown in FIG. 4 (a), and a tip is attached to the lower surface of the other fixed plate 65b. A conductive auxiliary contact spring 67 is provided which is located up to the handle 60. Further, a protrusion 60c for pressing the auxiliary contact spring 67 is integrally formed on the side surface of the handle 60 above the auxiliary contact spring 67. As shown in FIG. 4 (a), when the handle 60 is turned to the on position, the protrusion 60c separates from the auxiliary contact spring 67, and the auxiliary contact spring 67 returns to the upper side to assist the auxiliary contact spring 67. It will be closed with the fixed contact 66. The handle 60 is shown in FIG. 4 (c).
When the lever is in the off position as shown in FIG.
Pushes the tip of the auxiliary contact spring 67 downward to separate the auxiliary contact spring 67 from the auxiliary fixed contact 66 so that the auxiliary contact spring 67 and the auxiliary fixed contact 66 are opened. In addition, as shown in FIG. 3 (c), the handle 60 has a link to set the link 45 to the initial position when the handle 60 is set to the off position.
A pressing piece 68 for pressing the 45 downward is formed.

The electromagnet block A and the contact opening / closing mechanism B are connected as follows. That is, a through hole 69 penetrating the upper and lower surfaces of the body 23 is bored in the partition wall 24 of the body 23, the connecting pin 18 is inserted and arranged in the through hole 69, and one end 18a of the connecting pin 18 has a conversion shaft 11 formed therein. Through the hole 15a, the other end 18b of the connecting pin 18 through the hole 47a of the arm piece 47 of the link 45,
The conversion shaft 11 and the link 45 are connected by the connection pin 18. With these connection configurations, the horizontal movement of the electromagnet section 3 is converted into the vertical movement by the connection pin 18, and the movement of the electromagnet section 3 is transmitted to the link 45. Mechanism storage section 25
A power source side terminal portion 70 is disposed at one end of the. This terminal
70 includes a terminal screw 70a, a fastening plate 70b, a terminal plate 70c, and the like. The tip of the terminal plate 70c and the lower end of the short-circuit coil 33 are fixed to each other, and the short-circuit coil 33 and the upper end of the bimetal 39 are connected by a braided wire 71, and the lower portion of the bimetal 39 is a braided wire. It is connected to the base of the movable contactor 27 via 72.

A load-side terminal portion 73 is arranged on the other side of the mechanism housing portion 25. The terminal part 73 includes a terminal screw 73a, a clamping plate 73b, and a terminal plate 73c.
And so on. An arc portion 73d curved in an arc shape is formed on both sides inside the terminal plate 73c, and an arc horn 74 is provided on the front side of the arc portion 73d. Also, the arc
A fixed contact 75 facing the movable contact 36 is fixed on the terminal plate 73c inside 73d. The arc portion 73d is formed on the terminal plate 73c because the electromagnetic force generated by the current flowing through the arc portion 73d urges the arcs generated at the contacts 36 and 75 when the contacts are open to the arc extinguishing device 76 side. The arc is quickly extinguished and the movable contact 27 is quickly opened. The arc-extinguishing device 76 includes two side plates 77 and two side plates 77.
It is composed of a plurality of grid plates 78 arranged in parallel with each other, an insulating plate 79 for covering them, and the like. Where both arc horns
As shown in FIG. 4 (a), 38 and 74 are arranged side by side with a grid plate 78 in an insulating plate 79.

The cover 80 that covers the upper surface of the body 23 is made of an insulating material, and a window hole 81 that allows the operation portion 60d of the handle 60 to protrude from the upper surface is formed in a substantially central portion of the cover 80. In addition, a display window 82 is formed in the side of the window hole 81 so that a display projection 26c projecting above the interlocking plate 26 can be projected. This display projection 26c
Indicates that the movable contact 36 and the fixed contact 75 are closed if they do not protrude from the display window 82, that is, the energized state where the main circuit is connected.If the display projection 26c protrudes from the display window 82, the movable contact 36 And that the fixed contact 75 is open, that is, that the main circuit is shut off. Further, notches 83 are formed at both ends of the cover 80, and the terminal portions 70 and 73 are located in the notches 83 as shown in FIG. 1 (a). Further, the mounting base 1 in which the electromagnet block A is housed and arranged is attached to the lower surface of the body 23 by the assembling screw 84 as shown in FIG.
It is fixed to the upper surface of 23 with the assembly screw 85. Here, the upper surface of the electromagnet block A is insulated by the bottom portion of the body 23 made of an insulating material.
From the connecting pin 18 through the through hole 69 of the body 23.
It projects to the 23 side.

FIG. 5 shows an electric circuit diagram in which a series circuit including a short-circuit coil 33, a bimetal 39, contacts 36 and 75 is inserted between the terminal portions 70 and 73. In addition, the auxiliary contact SW ₁ composed of the auxiliary fixed contact 66 and the auxiliary contact spring 67 has one auxiliary terminal 2
2 and the coil 5 of the electromagnet part 3 and the contact part 88
A series circuit with a switch SW ₃ composed of both contacts 90a and 91a is connected to the other auxiliary terminal 22. The external switch SW ₂ is is connected to the auxiliary terminal 22. The feature of this breaker is that the external switch SW ₂
The contacts 36 and 75 are not turned on and the main circuit is not energized unless the operator operates. And
If you turn off the handle 60 to turn off the auxiliary contact SW ₁ ,
Since the auxiliary contact SW ₁ is inserted in series with the coil 5 of the electromagnet section 3, the electromagnet section 3 is cut off and the contacts 36, 7
5 is opened and the main circuit is cut off. Also, the external switch S
The contact S ₁ for self-holding is connected in parallel with W ₂ . Although the structure of this contact S ₁ is not shown, it is formed so as to open and close according to the contacts 36, 75 and the like.

Next, the operation of the breaker will be described. 4 shows a sectional view taken along the line AA of FIG. 1 (a), and FIG. 3 shows a sectional view taken along the line BB of FIG. 1 (a). 4 (a) and 3 (a) show an on state, and FIGS. 4 (b) and 3 (b) show an off state when the handle 60 is on and the electromagnet portion 3 is off. , FIG. 4 (c) and FIG. 3 (c) show the off state, and FIG. 4 (d) and FIG. 3 (d) show the trip state.

First, when the handle 60 is turned on as shown in FIG. 3A from the off state of FIG. 3C, the protrusion 60c of the handle 60 separates from the auxiliary contact spring 67 of the auxiliary contact SW ₁ and the auxiliary contact spring. When 67 is restored, auxiliary contact is made as shown in Fig. 4 (a).
SW ₁ is closed. Therefore, since the bimetal 39 of the contact part 88 is not heated, both contacts 90a, 91a, that is, the switch SW ₃
Is on, the coil 5 of the electromagnet section 3 is excited by turning on the external switch SW ₂ shown in FIG.
As shown in the figure and (a) of FIG. 3, the movable iron core 7 is attracted to the fixed iron core 6. When the movable iron core 7 is attracted, the exchange shaft 11 connected to the movable iron core 7 and the U-shaped pin 16 rotates clockwise around the shaft 13 as a fulcrum, so that the connecting pin 18 rotates the conversion shaft 11. It moves downward with the movement. When the connecting pin 18 moves downward, the link 45 connected to the connecting pin 18 rotates counterclockwise about the rotation shaft 50. Therefore, the interlocking plate 26 arranged below the link 45 is moved downward against the restoring force of the opening spring 29. When the connecting plate 26 moves downward, the movable contact 27 and the contact pressure spring 28 are located in the hole 26a of the interlocking plate 26 as shown in FIG. 28 is moved downward, the movable contact 36 of the movable contact 27 and the fixed contact 75 are brought into contact with each other by the contact pressure of the contact pressure spring 28, and the main circuit is energized.

Next, when the handle 60 is turned off from the on position, as shown in (c) of FIG. 4 and FIG.
When 60c pushes the auxiliary contact spring 67 of the auxiliary contact SW ₁ downward, the auxiliary contact spring 67 is separated from the auxiliary fixed contact 66 and the auxiliary contact SW ₁ is opened. Therefore, by opening the auxiliary contact SW ₁ , the electric current to the electromagnet portion 3 is cut off, and the connecting pin 18 and the like perform the same operation as in the above case to open the contacts 36 and 75.

Next, the case of the trip state will be described. First, a case where the main circuit is short-circuited will be described. In the case of a short-circuit, a large current is flowing, and therefore an electromagnet is generated in the short-circuit coil 33 to perform a trip operation. Here, in a normal state before a short circuit occurs, as shown in FIG. 3 (a), the rotating shaft 50 that pivotally supports the link 45 and the latch plate 48 is located below the elongated hole 44 of the frame 41. Is located in. The latch plate 48 is engaged with the engagement piece 57 of the latch engagement plate 53. Further, the engagement portion 56 of the latch engagement plate 53 is engaged with the head portion 34a of the drive pin 34 as shown in FIG. 4 (a). When a short circuit occurs, the driving pin 34 is driven downward by the electromagnetic force generated in the short circuit coil 33. By the downward movement of the drive pin 34, the engaging portion
56 is pressed and the latch engagement plate 53 rotates counterclockwise about the pin 55. Then, the latch engagement plate 53 and the engagement piece 57
The latch plate 48 disengaged with is in a free state, the link 45 is urged upward through the interlocking plate 26 by the restoring force of the opening spring 29, and the link 45 has the rotation shaft 50 of the long hole of the frame 41. 44
Will move to the top of. Accordingly, when the downward urging force of the interlocking plate 26 is released, the movable contact 27 also moves upward, and the contacts 36 and 75 are separated. At this time, since the drive pin 34 is suddenly sucked downward, the lower end of the drive pin 34 contacts the base of the movable contact 27 to apply the rotational force of the movable contact 27 in the clockwise direction to the movable contact 27. To open the contacts 36 and 75. The display protrusion 26c can freely protrude from the display window 82 according to the vertical movement of the interlocking plate 26.
When the 6,75 are separated, the display protrusion 26c protrudes and the contact 3
When the 6, 75 are open, the display protrusion 26c does not protrude from the display window 82, and the contacts 36, 75 are opened and closed.

Also, when an overcurrent flows, the bimetal 39 bends,
This bending operation causes the card 87 to be moved as shown in FIG.
Moves to the contact portion 88 side and presses the upper end of the movable piece 93 against the end surface of the card 87. The movable piece 93 that has been pressed contacts rotates about the shaft 92 as a fulcrum in the clockwise direction in the figure. Due to the rotation of the movable piece 93, the tip of the pressing piece 95 of the movable piece 93 presses the spring piece 90b of the reversing spring 90, and the reversing spring 90 is reversed so that both contacts 90a, 91a.
Open (Switch SW ₃ ). When the switch SW ₃ is opened, the coil 5 is de-energized as apparent from FIG. 5, so that the movable iron core 7 is moved to the sprung 10 as shown in FIGS. 4 and 3 (b). It returns to the left in the figure by the return force of. By the movement of the movable iron core 7, the conversion shaft 11
Rotates about the axis 13 in the counterclockwise direction. By rotating the conversion shaft 11 in the counterclockwise direction, the connecting pin 18 is moved upward to rotate the link 45 in the clockwise direction. Therefore the link
The interlocking plate 26 from which the biasing force of 45 has been released is moved upward by the restoring force of the opening spring 29, and the movable contact 27 is also moved upward, and the contacts 36, 7
5 is separated. Further, at this time, the biasing force of the spring 35 biasing the base of the movable contact 27 together with the restoring force of the opening spring 29 causes the protrusion 37a to pivot in a counterclockwise direction to open the pole. Is.

Next, after the trip operation, when the handle 60 is in the on position and the display protrusion 26c is projected and the handle 60 is turned off, the auxiliary contact SW ₁ is turned off and the electromagnet part 3 is turned off. By returning the movable iron core 7,
As shown in Fig. 3 and Fig. 3 (b), a connecting pin is provided on the conversion shaft 11.
18 is moved up to move the link 45 as shown. Further, when the handle 60 is turned off, the connecting portion between the link 45 and the latch plate 48 is pressed downward by the pressing piece 60 of the handle 60, and the latch plate 48 is rotated counterclockwise to rotate the latch plate 48. The engaging recess 58 and the engaging piece 57 of the latch engaging plate 53 can be engaged and reset. At this time, the auxiliary contacts SW ₁ by off operation of the handle 60 is turned off so that, returning to the initial position the movable iron core 7 of the electromagnet 3 is returned. Further, the bimetal 39 of the contact portion 88 is opened by the interruption of the main circuit, the contact S ₁ is also opened, the curved state is restored to the original state, the switch SW ₃ is closed, and the switch S of the contact portion 88 is closed.
W ₃ will be automatically reset.

In this way, the trip by the link mechanism is due to the short-circuit current, which is almost unlikely to occur, so that it is mechanically stable, and in the case of overcurrent detection, it does not go through a link mechanism with a large trip force. In addition, the output of the bimetal 39 is given to the reversing spring 90 via the movable piece 93, and the reversing operation of the reversing spring 90 causes both the contacts 90a and 91a to be opened and closed to shut off the electromagnet section 3, so that the characteristics vary. Therefore, the characteristics of the bimetal 39 are stable. That is, in the case of overcurrent detection, the bimetal 39 itself does not receive an unnecessarily large force, and a force for pressing the card 87 or the movable piece 93 is sufficient, and the characteristics are stable.

6 and 7 show an embodiment in which a reset mechanism for forcibly resetting the contact portion 88 is provided, and the cover 80 has a hole 80.
A is bored, and a reset body 97 is arranged in this hole 80a so as to be vertically movable and urged upward by a spring 98. cover
The reset button is on the top of the reset body 97 located on the upper surface of the 80.
97a is provided, and the lower portion of the reset body 97 is formed with a pressing portion 97c having a tapered surface 97b. This pressing portion 97c faces the lower portion of the reversing spring 90, and by pushing the reset button 97a downward, the reset body 97 is lowered and the lower pressing portion 97c.
The reverse spring 90 is reversely driven by the taper surface 97b of the reverse spring 9b.
0 is reset and both contacts 90a and 91a are closed.

8 and 9 show another embodiment of the reset mechanism. One end of the reset member 99 is connected to the handle 60, and the other end of the reset member 99 is inside the groove 1a formed on the bottom surface of the mounting base 1. It is buried in. The reset member 99 has flexibility, and for example, a release member for a camera is used. When the handle 60 is turned off, the other end of the reset member 99 connected to the handle 60 moves upward as shown by the arrow in FIG. 9, and the taper surface 99a of the reset member 99 causes the reversing spring 90 to move. The lower end of the contact is pressed and the reversing spring 90 is reversed to close both contacts 90a and 91a.
I am trying to reset.

[Advantages of the Invention] As described above, the present invention provides an auxiliary contact that is turned on by turning on a handle, an external switch that is connected in series with the auxiliary contact and is installed remotely, and an overcurrent detection that detects an overcurrent. A sensor, a contact portion that opens a contact by the signal of the overcurrent detection sensor, an electromagnet portion that attracts and drives the movable iron core when both the external switch, the auxiliary contact and the contact portion are in the ON state, and the movable iron core A link mechanism for turning on the contact of the main circuit by suction operation, a short-circuit current detection sensor for detecting a short-circuit current, and a trip mechanism for releasing the latch of the link mechanism by the output of the short-circuit current detection sensor to turn off the contact of the main circuit. Because it is equipped with
The auxiliary switch that is turned on when the handle is turned on is connected in series and the externally installed external switch and contact section prevent the electromagnet section from turning on unless the auxiliary contact, external switch, and contact section are both turned on. West,
Therefore, unless the external switch is turned on at the remote control side, the contact is not turned on because the electromagnet part is not driven even if the handle is turned on at the breaker side.Therefore, the main circuit is not energized and remote control is performed. This has the effect of being safe for those who work on the side. Further, the phone remote control breaker can be handled at the same intervals as when two general breakers and two electromagnetic contactors are inserted in the main circuit. When an overcurrent is detected, the signal from the overcurrent detection sensor should be used to drive the electromagnet without the mechanical trip mechanism to release the link mechanism latch and open the main circuit contact. In the case of overcurrent detection, the electromagnet section is driven without going through a link mechanism with a large tripping force, so there is an effect that the main circuit can be shut off without variations in characteristics. Is.

[Brief description of drawings]

1 (a) to 1 (e) are a plan view, a side view, a BB sectional view of FIG. 1 (a), and an A- of FIG. 1 (a) of an embodiment of the present invention.
A sectional view and a side sectional view, FIG. 2 is an exploded perspective view of the whole of the same as above, FIG. 3 is a BB sectional view of FIG. 1 (a) above, and FIG. Sectional view, the same figure (b) is a sectional view when the electromagnet portion is in an off state, the same figure (c) is a sectional view in the off state, the same figure (d) is a sectional view in the trip state, and FIG. 4 is the same as above. 1A is a sectional view taken along line AA in FIG. 1A, in which FIG. 1A is a sectional view in an ON state, FIG. 1B is a sectional view in a case where an electromagnet portion is in an OFF state, and FIG. ) Is a sectional view in an off state, FIG. 5D is a sectional view in a trip state, FIG. 5 is an electric circuit diagram of the same, FIG. 6 is a side sectional view of another embodiment of the reset mechanism of the same, and FIG. The figure shows an enlarged cross-sectional view of the main part of the above, No. 8.
FIG. 9 is a sectional view of yet another embodiment of the reset mechanism of the above, FIG. 9 is a side sectional view of the same, and FIG. 10 is a sectional view of a conventional example. 3 is an electromagnet part, 7 is a movable iron core, 60 is a handle, 88 is a contact part, SW ₁ is an auxiliary contact, and SW ₂ is an external switch.

Claims (1)

(57) [Claims] 1. An auxiliary contact that is turned on by turning on a handle, an external switch that is connected in series with the auxiliary contact and is installed remotely, an overcurrent detection sensor that detects an overcurrent, and this overcurrent detection sensor. The contact part that opens the contact by the signal of, the electromagnet part that attracts and drives the movable core when the external switch, the auxiliary contact, and the contact part are all in the on state, and the contact of the main circuit by the attraction operation of the movable core. A remote control breaker comprising a link mechanism for turning on, a short-circuit current detection sensor for detecting a short-circuit current, and a trip mechanism for releasing a latch of the link mechanism by the output of the short-circuit current detection sensor to turn off a contact of a main circuit.