JPH0755794Y2 - Remote control type circuit breaker - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of application] The present invention relates to improvement of a remote control type circuit and disconnector.

[Conventional technology]

3 to 8 are views showing a conventional remote control type circuit and breaker as described in, for example, Japanese Patent Laid-Open No. 61-230231, and FIG. 3 is a view showing disconnection and breakage of both contacts. Off-state diagram of the vessel,
Fig. 4 is a state in which both contacts are closed and the breaker is in the ON state. Fig. 5 is a state in which the tripping latch has been activated to open both contacts. Fig. 6 is a state in which an insulation barrier is attached. 3 is the same as FIG. 3, FIG. 7 is a state diagram in which a micro switch or the like is attached to FIG. 6, and FIG. 8 is a remote control circuit diagram.

In FIGS. 3 to 5, (1) is a breaker case consisting of a base (1a) and a cover, and each figure is a view with the cover removed. (2) is an operation handle rotatably attached to the breaker case (1) by the handle shaft (2a), and has an operation pin (3) and a resetting projection (4) on the inner side. In (5), the recess (5a) at one end is the operation pin (3).
A first link slidably and rotatably engaged to
(6) is a second link whose one end is rotatably connected to the other end of the first link (5), and (7) is a second link (6)
A movable element frame, one end of which is rotatably connected to the other end and which is rotatably supported by a first pivot pin (8) of the disconnector case (1), and an intermediate part, Pivot pin (8)
The movable contact held by the movable element frame (7) while being pivotally supported by the movable contact, the movable contact (10), and the fixed contact (11) connected to the load terminal (13) by the arc runner (12). It
(14) The second pivot pin (15) of the chopstick and breaker case (1)
The lever whose rotatably supports the intermediate portion thereof supports the intermediate portion of the first link (5) by the link pin (16) at one end. (17) A trip latch having an intermediate portion rotatably supported by a third pivot pin (18) of the ladder or disconnector case (1), which can be engaged with and disengaged from the other end of the lever (14). Engage. (19) is a trip drive spring for urging the lever (14) in the direction of engaging the trip latch (17) (counterclockwise in the figure), and (20) is the trip latch (17). Lever (1
4) Reset spring for resetting that urges in the direction to engage (clockwise in the figure), and (21) is an overcurrent detection device that operates the trip latch (17), which is composed of an electromagnet (21a) and bimetal (21a). 2
It consists of 1b) and. Bimetal (21b) has adjustment screw (22)
Presses the upper side of the trip latch (17) against the return spring (20), and the electromagnet (21a) resists the return spring (20) below the trip latch (17) by the blunger (23). And press. (24) is a power supply terminal connected to the bimetal (21b), (25) is an operation electromagnet for turning the handle (2) on and off by a remote control signal, and is connected to the handle (2) by the operation link (26). To be done. (27) is a remote control circuit terminal of the operating electromagnet (25), (28) is an arc extinguishing chamber, (29) is a bimetal (21b) and an electromagnet (21a).
Flexible copper stranded wire that connects with the coil of (30) is an electromagnet (21
It is a flexible copper stranded wire that connects the coil of a) and the movable contactor (9).

In FIGS. 6 and 7, (31) is a frame cover, which is a handle shaft (2a), a first pivot pin (8), a second pivot pin (15), and a third pivot pin ( 18) One end is pivotally supported to hold and form the opening / closing operation mechanism. (32) is a switching switch such as a micro switch for on / off switching, which is positioned by a positioning pin (31a) of the frame cover (31) and fixed to the frame cover (31).
Reference numeral (34) is an operating piece of the switching switch (32), which is pressed by an actuator (35) provided integrally with the handle (2) in the ON state. (36) is a micro switch for disconnecting the circuit at the time of trip, which is positioned by the positioning pin (33a) of the insulation barrier (33).
Fixed to 3). (38) is an actuating piece of the micro switch (36), which is linked to the link pin (16) which moves in the direction of the arrow (39) at the time of tripping.
It is released by release from 0). (41) is a lead wire for switches that connects both switches (32) and (36) via a diode (42), and (43) is a micro switch (36).
For connecting terminal to terminal (c) of terminal (27) for remote control circuit, (44) is switch (32)
Remote control circuit terminal (27) via diode (45)
Terminal connecting lead wire for connecting to the terminal (b) of
(46) is a terminal connecting lead wire for connecting one end of the coil (described later) of the operating electromagnet (25) to the terminal (a) of the remote control circuit terminal (27), and (47) is the operating electromagnet. (2
The other end of the coil of 5) (described later) and the switching switch (32)
It is a lead wire for connecting with.

Next, the operation will be described. In FIG. 8, (48) is the coil of the operating electromagnet (25), and FIG.
FIG. 8 shows the ON state, FIG. 8B shows the OFF state, and FIG.
FIG. 5C corresponds to the trip state of FIG. 5, respectively.

First, a case where the remote ON operation is performed in the OFF state of FIGS. 3 and 8B will be described. To perform a remote ON operation, a positive DC current (remote control signal) is applied to the terminal (a) in the state shown in FIG. At this time, this DC current is applied to the coil (48), the switching switch (32) and the diode (45).
Through to the terminal (b), the coil (48) is biased in the ON direction. As a result, the plunger of the operating electromagnet (25) rotates in the direction of the arrow (49), the first link (5) rotates counterclockwise around the link pin (16) as a fulcrum, and the second link (6). The movable element frame (7) rotates in the direction of the arrow (50) around the first pivot pin (8) as a fulcrum via the The moving contact (10) closes. At that time, since the lever (14) and the tripping latch (17) are engaged with each other by being pressed by the springs (19) and (20), the relationship between them does not change.
During this time, the handle (2) is rotated clockwise, and the switching switch (32) is switched to the position shown in FIG. 8 (a) by the actuator (35), and the on state of FIG. 4 and FIG. 8 (a) is set. Become. In this ON state, each member is held in the state shown in FIG. 4 by the attraction force of the operating electromagnet (25). The reason why the changeover switch (32) is changed over as described above is to prevent the coil (48) from being burned due to long-time energization.

Next, a case where the remote off operation is performed in the on state of FIGS. 4 and 8 (a) will be described. At this time, a negative DC current (remote control signal) is supplied to the terminal (a). In other words, a positive direct current is supplied to the terminal (c). As a result, the coil (48) is energized in the opposite direction to that in the case of FIG. 8 (b) by the direct current flowing through the diode (42) and the micro switch (36). As a result, the plunger of the operating electromagnet (25) rotates in the direction of the arrow (51), and the first
The link (5) rotates clockwise around the link pin (16) as a fulcrum, and the mover frame (7) passes through the second link (6) around the first pivot pin (8) as a fulcrum. (52)
The movable contact (9) rotates together with the movable element frame (7) to open the movable contact (10). During this time,
The handle (2) rotates counterclockwise, and the actuator (35) switches the switching switch (32) to the position shown in Fig. 8 (b) to turn it to the off state shown in Figs. 3 and 8 (b). Return. Here, the changeover switch (32) is changed over to prevent the coil (48) from being burnt out due to the energization for a long time.

Further, a case where an overcurrent flows in the ON state of FIGS. 4 and 8A will be described. In Figure 4, the current is
Power terminal (24) → Bimetal (21b) → Flexible copper stranded wire (2
9) → coil of electromagnet (21a) → flexible copper stranded wire (30) → movable contact (9) → movable contact (10) → fixed contact (11) → load terminal (13). Now, an overcurrent flows and the bimetal (21b) bends, and the tripping latch (1
Rotate 7) in the direction of arrow (53) against the return spring (20), or the plunger (23) of the electromagnet (21a).
Is activated to rotate the trip latch (17) against the return spring (20) in the direction of the arrow (53), the lever (14) is disengaged from the trip latch (17) and the drive spring ( The spring force of 19) causes the second pivot pin (15) to rotate in the direction of the arrow (54) about the fulcrum. At this time, since the handle (2) is held by the attraction force at the ON position of the operating electromagnet (25), the operating pin (3) does not move. Therefore, the first link (5) together with the link pin (16) in the direction of the arrow (54) with the operation pin (3) as a fulcrum with the recess (5a) engaged while sliding the operation pin (3). And the movable element frame (7) is connected to the first pivot pin (8) via the second link (6).
Is rotated in the direction of the arrow (52) around the fulcrum as a fulcrum, and the movable contact (9) is rotated together with the movable element frame (7) to move the movable contact (1
0) opens. This is called a trip state and is shown in FIG.

In the trip state shown in FIG. 5, the link pin (16) causes the actuator (40) to rotate by the link pin (16) to release the operating piece (38) of the micro switch (36).
As shown in FIG. 8 (c), the operating electromagnet (25) is disconnected from the remote control circuit to be in the "trip state". Therefore, in this "trip state", the operation electromagnet (25) cannot be operated, and the reset operation is performed by manually turning off the handle (2). When the micro switch (36) is not provided, it is possible to perform the reset by remote control. At this time, the switching switch (32) returns to the state shown in FIG. In FIG. 5, handle (2) (reset)
When turned off, the pin (7) at the other end of the first link (5)
The first link (5), the link pin (16), and the lever (14) rotate in the direction of the arrow (55) against the drive spring (19) around 0) as the center of rotation, and finally tripped. Latch (17)
Locked in. At this time, the trip latch (17) is also returned by the return spring (20). By returning the lever (14), the lever is returned to the off state shown in FIG.

By the way, the operating electromagnet (25) has a coil (48) biased by a remote control signal and a permanent magnet, and the magnetic flux of the coil (48) and the permanent magnet are superposed to superimpose the coil (48). The one that opens and closes the handle (2) when the urging direction changes is used. An example of such an electromagnet for operation is disclosed in Japanese Utility Model Publication No. 62-58005.
This will be described with reference to FIGS. 9 to 16.

FIG. 9 is a plan view of the operating electromagnet (25) with the cover (1b) of the chopstick and breaker removed, and FIG. 10 is a sectional view taken along the line XX of FIG. 9 with the cover (1b) attached. Fig. 11, Fig. 11 is an exploded perspective view, Fig. 12 is a plan view of an armature having a coil (48) wound thereon, Fig. 13 is a right side view of Fig. 12, and Fig. 14 is a perspective view of a first yoke. FIG. 15 is a perspective view of a permanent magnet, and FIG. 16 is a perspective view of a second yoke. In the figure, (56) is an armature, (57) is a bobbin around which a coil (48) is wound, and the bobbin (57) is fitted on the armature (56). The bobbin (57) has flanges (571), (572) at both ends and a central flange (573), and the flange (573) serves as a fulcrum for pivotally supporting the armature (56). 574) and (575) are integrally formed.
The coil (48) has a section (481) wound between the flanges (571) and (573) and a section (482) wound between the flanges (573) and (572). (481), (48
2) are connected to each other by a lead wire (483) passing through a groove (576) formed in a central flange (573) and have terminal leads (484) and (485), and the terminal lead (48)
4) is inserted into the groove (577) formed in the flange (573) and the groove (578) formed in the flange (571), and the terminal lead (485) is formed in the flange (571). Groove (57
It is fitted in 9) so that the wiring process can be performed easily. The terminal lead (484) is connected to the lead wire (46), and the terminal lead (485) is connected to the lead wire (47). The armature (56) penetrates the center opening of the bobbin (57) and has both ends protruding from the bobbin (57). The left and right sides of this protruding part are attached to the suction parts (561), (5
62), (563), and (574).

Reference numeral (58) denotes a U-shaped first yoke, which passes through the side portions (581), (582) opposed to the left and right sides of the armature (56) and the side portion (581) of the armature (56). ),
(582) is composed of a top part (583) which is connected to each other, and is formed by bending a single magnetic plate. (59) and (60) are a pair of permanent magnets arranged inside the side parts (581) and (582) of the first yoke (58), and (61) and (62) are permanent magnets (5).
9) and (60) are flat plate-shaped second yokes arranged inside, wherein the permanent magnets (59) and (60) are the first yoke (5
8) side portions (581), (582) and second yokes (61), (6)
It is sandwiched between 2) and in the shape of a sun-gerch, and the magnetic poles (N), (S) are so arranged as to pass magnetic flux in the same direction to the armature (56) through both yokes (58), (61), (62). It is oriented.

(63) is the first yoke (58), the permanent magnet (59),
A storage recess formed in the base (1a) for holding the (60) and the second yokes (61), (62) in an assembled state, and the tops of the second yokes (61), (62). The protrusion (61
Groove (63) into which 1), (612), (621) and (622) are inserted
1), (632), (633), (634) and the groove (63) into which the lower portions of the side parts (581), (582) of the first yoke (58) are fitted.
5), (636), and the protrusions (611), (612), (62
1), (622) corresponding grooves (631), (632), (63
3) and (634), and the side portions (518) and (582) are fitted into the corresponding grooves (635) and (636), so that the permanent magnets (59) and (60) are first Side of the yoke (58) (58
It is designed to be held in the storage recess (63) while being sandwiched between 1) and (582) in the shape of a sun deer.

(584) is a hole formed in the top portion (583) of the first yoke (58) for accommodating the pin (574) provided in the bobbin (57),
(637) is formed at the bottom of the storage recess (63), and the bobbin (5)
The hole (58) for accommodating the pin (575) provided in (7) is inserted into the hole (584) and the hole (637), so that the armature (56) is It is supported so that it can rotate around (574) and (575). Reference numeral (64) is a plunger fitted in the armature (56) for activating the opening / closing operation mechanism of the shutter and the disconnector.

FIG. 17 and FIG. 18 are diagrams schematically showing a magnetic circuit of the operating electromagnet (25) of FIGS. 9 to 16 described above.
The operation will be described with reference to FIGS. 17 and 18. In the state of FIG. 17 (ON state of FIG. 4), the coil (48) is not energized, and the permanent magnet (59) indicated by the alternate long and short dash line,
The armature (56) is held in a state of being rotated counterclockwise only by the magnetic flux (C) of (60). When the coil (48) is energized in this state to form a magnetic flux (D) in the direction indicated by the dotted line, the magnetic fluxes (C) and (D) are superimposed to form a combined magnetic flux (E) indicated by the solid line, and the attracting portion (561), While the attraction force between the yokes (61) and between the attraction portion (564) and the yoke (62) disappears, the flow of magnetic flux is between the attraction portion (562) and the yoke (62) and between the attraction portion (563) and the yoke (61). Then, the armature (56) is rotated clockwise to the position shown in FIG. 18 (OFF state in FIG. 3). At this time, the direction of the magnetic flux (C) is reversed, and the armature (56) is held at the position shown in FIG. 18 even if the coil (48) is de-energized. Here, the magnetic flux (F) in the direction shown by the dotted line in the coil (48)
When a current is applied to generate the magnetic flux (C) and (F), the combined magnetic flux (G) shown by the solid line is generated, and the attracting portion (56)
2), between the yoke (62) and the suction part (563), the yoke (6
The attraction force between 1) is lost, and the flow of magnetic flux becomes
1), between the yoke (61) and the suction part (564), the yoke (6
2) Change to the direction that passes through the gear tap,
Rotates counterclockwise to the position shown in FIG. At this time, the direction of the magnetic flux (C) is reversed again, and the armature (56) is held at the position shown in FIG. 17 even when the coil (48) is de-energized.

[Problems to be solved by the invention]

In the conventional remote control type circuit breaker as described above, the dimension (L) of the storage recess (63) is the dimension of the operating electromagnet (25) along the rotation direction of the armature (56) (actually, the first The size of the yoke (58) of the above was adjusted and the operation electromagnet (25) was fixed to the breaker case (1) so that it would not move.
After assembly is complete, if it is found that the margins (overtravel of contacts), reset margins, etc. are not properly secured due to variations in mechanical parts, etc., it must be disassembled and parts replaced. However, there was a problem that it was very troublesome.

The present invention has been made to solve such a problem, and even without disassembling and replacing parts, a simple operation of moving the operation electromagnet in the accommodating recess in the rotation direction of the armature allows the insertion margin. , The purpose is to obtain a remote control type circuit or disconnector that can adjust the margin such as the reset margin.

[Means for solving problems]

In the remote control type circuit breaker according to the present invention, the size of the storage recess is made larger than the yoke in the rotation direction of the armature.
A spacer is inserted into the gap between the thus formed storage recess and the yoke.

[Action]

In this invention, the insertion position of the spacer can be changed to the left and right by moving the yoke to the left and right to move the position of the clearance of the storage recess to the left and right, so that the fixed position of the operating electromagnet can be changed and adjusted in the rotational direction of the armature.

[Example of device]

An embodiment of the present invention will be described below with reference to FIGS. FIG. 1 is a diagram showing a state in which the operating electromagnet is moved to the left, and FIG. 2 is a diagram showing a state in which the operating electromagnet is moved to the right. The description is omitted. In the figure, (63A) is a storage recess of the operation electromagnet (25) formed in the base (1a), and the dimension (L ₁ ) in the rotational direction (left-right direction) of the armature (56) is set to the first yoke (58). The size (L ₂ ) is larger than the size (L ₂ ) to allow a gap (l). (65) is a spacer inserted in the clearance (l), and is composed of a dogleg-shaped leaf spring or the like.

As shown in FIG. 1, the operation electromagnet (25) is accommodated in the recess (63
When the spacer (65) is inserted into the clearance (l) formed to the right of the storage recess (63A) by moving it to the left of A), the operating electromagnet (25) can be fixed to the left side of the storage recess (63A). The closing margin (α ₁ ) can be increased in the ON state of FIG. 1 (the same state as in FIG. 4). Further, as shown in FIG. 2, when the operation electromagnet (25) is moved to the right of the storage recess (63A) and the spacer (65) is inserted into the clearance (l) formed on the left of the storage recess (63A), the operation is performed. Since the use electromagnet (25) can be fixed to the right side of the storage recess (63A), the reset margin (α ₂ ) can be increased in the off state (reset state, the same state as in FIG. 3) of FIG.

In this manner, the spacer (65) is inserted into the gap (l) of the storage recess (63A) to store the operation electromagnet (25) in the storage recess (63).
If you fix it by moving it to the left and right of A), you can adjust the margins such as the throw-in margin and the reset margin to appropriate ones.

When a dogleg-shaped leaf spring is used as the spacer (65) as in the above embodiment, the operation electromagnet (25) is stored in the recess (63).
Can be easily and securely fixed to A).

In the above embodiment, the V-shaped plate spring is shown as the spacer (65), but it may be a simple plate-shaped member, for example, plate-shaped members having different thicknesses may be prepared and inserted into the left and right sides of the operating electromagnet (25). If this is done, the operation electromagnet (2
Position adjustment in 5) is possible.

[Effect of device]

As described above, according to the present invention, it is possible to adjust the allowance such as the insertion allowance and the reset allowance by a simple operation of moving the operating electromagnet in the accommodating concave portion in the rotation direction of the armature, so that the disassembling, the part replacement, and the resetting There is an effect that the number of man-hours can be significantly reduced and the cost can be reduced without requiring labor such as assembling.

[Brief description of drawings]

FIG. 1 is a view showing a state in which the operating electromagnet is moved to the left, and FIG.
The figure shows the state in which the electromagnet for operation is moved to the right, Fig. 3 shows the conventional device with the cover removed, and the off state of the breaker and breaker. Fig. 4 shows the on state of the breaker and breaker. 5 is a trip state diagram, FIG. 6 is the same diagram as FIG. 2 with a switch base attached, FIG. 7 is a state diagram with a micro switch etc. attached to FIG. 6, and FIG. 8 is remote control. FIG. 9 is a circuit diagram, FIG. 9 is a plan view of the operating electromagnet (25) with the cover (1b) of the breaker and breaker removed, and FIG. 10 is a sectional view taken along line XX of FIG. ) Is attached, FIG. 11 is an exploded perspective view, FIG. 12 is a plan view of the coil-wound coil,
13 is a right side view of FIG. 12, FIG. 14 is a perspective view of a first yoke, FIG. 15 is a perspective view of a permanent magnet, FIG. 16 is a perspective view of a second yoke, FIG. 17 and FIG. FIG. 18 is a diagram schematically showing a magnetic circuit of the operating electromagnet shown in FIGS. 9 to 16. In the figure, (1) a ladder and a breaker case, (2) an operating handle, (3) an operating pin, (5) a first link,
(6) is a second link, (7) is a mover frame, (8) is a first pivot pin, (9) is a movable contactor, (10) is a movable contact, (11) is a fixed contact, (14) is the lever, (15) is the second
Pivot pin, (16) link pin, (17) trip latch, (18) third pivot pin, (21) overcurrent detector, (25) operating electromagnet, ( 26) is the operation link, (4
8) is a coil, (56) is an armature, (57) is a bobbin,
(58) is a yoke, (59) and (60) are permanent magnets, (63A)
Is a storage recess, (65) is a spacer, and (l) is a gap. In the drawings, the same reference numerals indicate the same or corresponding parts.

Claims (1)

[Scope of utility model registration request] 1. A shroud breaker case, an operating handle, a movable contact having a movable contact that is brought into contact with and separated from a fixed contact by the handle, and an opening / closing arranged between the movable contact and the handle. An operating mechanism, an overcurrent detecting device for opening the movable contactor by an overcurrent, and an operating electromagnet for on / off controlling the handle by a remote control signal,
A remote control type circuit breaker having a storage recess provided in the casing and the breaker case and storing the operation electromagnet, wherein the opening and closing operation mechanism is slidable by an operation pin at one end on the handle. A first link rotatably engaged, a second link having one end rotatably connected to the other end of the first link, and one end rotatably connected to the other end of the second link A movable element frame that is connected and has an intermediate portion rotatably supported by the first pivot pin of the shroud and disconnector case, and the intermediate portion can be rotated by the second pivot pin of the shank and disconnector case A lever that is rotatably supported at one end of the intermediate portion of the first link by a link pin,
And a tripping latch rotatably supported at an intermediate portion by a third pivot pin of the casing and breaker case and releasably engaged with the other end of the lever. An electromagnet, an armature that penetrates the center opening of a bobbin around which a coil is wound, has both ends protruding from the bobbin, and has both left and right sides of the protrusion as adsorbing parts, and yokes disposed on both left and right sides of this armature. A permanent magnet that is provided between the yokes and allows magnetic flux to pass through the armature through the yoke, and the magnetic flux formed by the coil is superimposed on the magnetic flux of the permanent magnet of the operating electromagnet to reversibly reversing the armature. When the handle is rotated or the handle is manually operated, the first link rotates about the link pin as a fulcrum, and the mover frame moves to the first frame via the second link. The support pin is rotated as a fulcrum to bring the movable contact of the movable contactor into contact with and separated from the movable contact, and the tripping latch is operated by the overcurrent detection device to rotate about the third pivot pin as a fulcrum. Then, the lever disengages from the trip latch and rotates about the second pivot pin as a fulcrum, the first link rotates about the operation pin as a fulcrum, and the second link passes through the second link. In the remote control type circuit breaker or breaker, in which the movable element frame is rotated about the first pivot pin as a fulcrum to open the movable contact of the movable contactor, The fixing position of the operation electromagnet is set in the rotation direction of the armature by making the armature larger than the yoke in the rotation direction and inserting a spacer in the gap of the storage recess formed with the yoke. Remotely controlled circuit to or disconnection device being characterized in that to allow further adjusted.