JPH0641321Y2 - Circuit breaker - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of application] The present invention relates to a circuit breaker and a circuit breaker, and more particularly to improvement of an electromagnetic trip adjustable device.

[Conventional technology]

5 to 10 are views showing a conventional circuit breaker and circuit breaker disclosed in, for example, Japanese Utility Model Laid-Open No. 52-138267, FIG. 5 is a partially broken configuration diagram, and FIG. Fig. 5 is a detailed configuration diagram of the trip device, Fig. 7 is a sectional view taken along line VII-VII in Fig. 6,
8 is a schematic sectional view taken along the line VIII-VIII in FIG. 6, FIG. 9 is a partial structural view of FIG. 6, and FIG. 10 is a perspective view of an arm.
In FIG. 5, (1) is for opening and closing the contacts of the circuit breaker and circuit breaker, and (2) is the cover of the case made of an insulating material,
(3) is the base of the case also made of an insulator, (4)
The conductor inside the chopsticks and circuit breaker, and (5) is a trip device that detects an abnormal overcurrent and activates the circuit breaker. 6 and 7 are detailed views of the trip device (5) for three poles, (6) is a trip base made of an insulating material, and (7)
a), (7b), (7c) are conductors (4a), (4b), (4) of each pole.
c) through the U-shaped fixed iron core, (8a), (8b), (8
c) is a movable iron core that is rotatably supported, and includes a spring (9a),
It is biased counterclockwise by (9b) and (9c).
Thus, the conductor, the movable iron core, and the fixed iron core form an electromagnet. (10a), (10b), (10c) are rebet (1
1a), (11b), (11c), the fixed core (7a),
Brackets fixed to (7b) and (7c), and bent supports (10d), (10e), and (10f) are formed at one end. Reference numeral (12) is a trip bar rotatably supported by the trip base (6).
a), (12b), and (12c) are formed. (13a),
(13b) and (13c) have one end having the movable cores (8a) and (8
b) and (8c) are fixed actuating shafts, the free ends of which penetrate between the opposed protrusions (12a), (12b) and (12c). (14a), (14b), (14c) are engaging pieces, (15) is a latch formed on the other side of the trip bar (12), (16)
Is a latch, and (17) is a connecting rod made of a rigid insulator.
As shown in the figure, elongated holes (17a), (17b), (17c) are formed. The above brackets (10a), (10b), (10
Supports (10d), (10e), (10f) formed on c)
Are elongated holes (17a), (17b), (17c) of the connecting rod (17)
It is engaged with and supports this. (19a), (19b),
(19c) has elongated holes (20a), (20b), (2
0c), which is a support shaft (21a), (21b),
Brackets (10a), (10b), (10c) by (21c)
It is rotatably supported on the top. (22a), (22b),
Reference numeral (22c) is a support shaft planted in the connecting rod (17), and is fitted in the elongated holes (20a), (20b), (20c). (twenty three
a), (23b), (23c) are the arms (19a), (19
b) Screws screwed into the screw holes of (19c), the tips of which are engaged with the free ends of the movable iron cores (8a), (8b), (8c). Reference numeral (24) is an adjustment button exposed from the base (6), which causes the cam (26) to face one end of the arm (19b) at the center pole via the cam shaft (25). (2
7) and (28) are an upper iron core and a lower iron core that constitute a transformer for each pole, and a coil heater (29) is wound around the iron core (27). (30) is an overcurrent detecting bimetal thermally joined to the heater (29), (31a) and (31b) are ambient temperature compensating bimetals arranged in the center between adjacent poles, one end of each of which is the above-mentioned Install the screws (32a), (3
2b). (33) is an insulating connecting rod,
The other ends of the compensating bimetals (31a) and (31b) are connected to each other by screws (34a) and (34b). (35a),
(35b) and (35c) are adjusting screws, (36) is a spacer, (3
Numeral 7) is a snap-action iterative spring attached to the trip base (6) with a screw (38), and rotatably supports the other end of the cam shaft (25) at the adjusting button (24). (39) is the ribbed (11) on the trip base (6).
The cam support table attached in b) rotatably supports one end of the cam shaft (25).

In the circuit or breaker configured as described above, when a relatively small overcurrent flows, the bimetal (30) bends due to the heat generated by the heater (29), which causes the adjustment screw (35
Pressing a), (35b), (35c) and pulling it out (12)
Is rotated clockwise in FIG. 7 to disengage the latch (15) from the latch (16) and open the contact (not shown). When a large overcurrent flows, the movable iron cores (8a), (8b), (8
c) is attracted to the fixed iron cores (7a), (7b), (7c), and the trip bar (12) is turned through the operating shafts (13a), (13b), (13c), and the contacts are made in the same manner as above. open.

The adjustment operation will be described next. When the adjustment button (24) is turned, the cam (26) rotates, and the arm (19b) and screw (23b)
The movable iron core (8b) is moved through the two iron cores (7b),
The gap width between (8b) is adjusted. Meanwhile, the arm (19b)
When is rotated, the connecting rod (17) is supported by the supporting portions (10d), (10e), (10f) due to the relationship between the elongated hole (20b) and the support shaft (22b), and a straight line is obtained to the left or right. Moving. Therefore, the poles (22a) and (22c) are used to connect the bipolar arms (19
The a) and (19c) are turned to adjust the gap width between the two iron cores (7a) and (8a).

[Problems to be solved by the invention]

In the conventional circuit breaker and disconnector as described above, the arm (19b)
The arm (19b) due to a fitting error between the rotation fulcrum pin (not shown) and the hole (21) and the cam (26) falling down.
There is play in the arm and distortion occurs due to the stress of the arm (19b). Therefore, when the adjustment button (24) is rotated to change the gear tap between the movable iron core (8b) and the fixed iron core (7b), There was a problem that the gear tape was not correctly set to the initial setting value due to the backlash and distortion of (19b).

The present invention has been made to solve such a problem. By adjusting the pivotal fulcrum of the arm, the play and distortion of the arm can be absorbed, and the movable core and the fixed core of the electromagnetic tripping device can be absorbed. The purpose is to obtain a circuit and breaker in which the gears of and are correctly set to the initial setting values.

[Means for solving problems]

In the circuit breaker and the circuit breaker according to the present invention, the rotation fulcrum of the arm is adjustable so that the arm can be adjusted in the rotation direction.

[Action]

In this invention, since the pivotal fulcrum of the arm is adjustable, the pivotal fulcrum of the arm can be adjusted while the arm is in contact with the iron core to absorb the play of the arm due to backlash and distortion.

[Example of device]

An embodiment of the present invention will be described below with reference to FIGS. FIG. 1 is a vertical cross-sectional side view, and FIG. 2 is an enlarged view showing the electromagnetic trip-adjustable device of FIG. 1. The same or corresponding parts as those of the conventional device are designated by the same reference numerals, and the description thereof will be omitted. In the figure, (40) is a stator fixed to the base (3) and has a fixed contact (40a). (41) is a frame installed on the base (3) with screws (42), (4)
3) is an operation handle that rotates around the protrusion (41a) of the frame (41) as a fulcrum, (44) is a cradle rotatably attached to the operation handle (43), and (45) is provided on the operation handle (43). The upper link pin (46) is a link mechanism, and the upper link (46a) is connected by the connecting pin (47).
And the lower link (46b). (48) is a tension spring,
The upper link (46a) is locked to the upper link pin (45) by urging the connecting pin (47) toward the operation handle (43). (Four
9) is a crossbar rotatably installed with respect to the base (3), and the lower link pin (50) connects the lower link (46b).
Are connected. A mover (51) is rotatably held by the mover shaft (52) on the crossbar (49) and has a movable contact (51a). (53) is a fixed conductor fixed to the base (3), (54) is a flexible conductor connecting the fixed conductor (53) and the mover (51), and (55) is an electromagnetic wave installed on the base (3). The trip device has a movable iron core (55a). (56) is a bimetal of the thermal trip device arranged in parallel with the electromagnetic trip device (55), (57) is a heater, (58)
Is an adjusting screw provided above the bimetal (56), and (59) is a screw (6) on the yoke (55b) of the electromagnetic trip device (55).
U-shaped cam support, attached by (0), (61)
Is a hole for inserting the bimetal (56) provided in the cam support base (59), (62) is a duller hole provided in the cam support base (59), (6
3) is an iter spring mounted on the cam support base (59) with screws (64), and has a projection (63a) for snap-action. (65) is the hole provided in the leaf spring (63), (6
6) is a cam shaft whose both ends are rotatably supported in the dharma hole (62) and the hole (65) respectively, and (67) is a notch step portion provided in the cam shaft (66). Engage. (68)
Is a cam provided on the cam shaft (66) and has a groove (68a) for snap-action. (69) is an arm having a contact portion (69a) with which the rotary fulcrum pin (70) is fitted at one end and abutting against the movable iron core (55a) at the other end, and (71) is attached to the cam support base (59). The arm support member is provided with a vertically elongated hole (71a) for movably inserting the rotation fulcrum pin (70). Reference numeral (72) is an arm adjusting screw which is vertically inserted into a hole (59a) of the cam support base (59) and which holds a rotation fulcrum pin (70) at a lower end and a nut (72) at an upper end.
It is received by the cam support base (59) by a). (7
3) is a lifting rod rotatably attached to the middle of the arm (69) by a pin (74), and the upper end (73a) is a cam (68).
Is engaged with the cam surface (68b) of the. (75) is a trip bar, and the movable iron core (55a) and the adjusting screw (58) are engaged with each other. (76) is a latch that engages with the trip bar (75), (77) is a latch that engages with the latch (76), and the cradle (44) is engaged with the latch. The reference numerals (59) to (74) form an electromagnetic trip adjustable device.

Next, the operation will be described. Although not shown, in the ON state, the current is the stator (40) → the fixed contact (40a) → the movable contact (51a) → the movable element (51) → the flexible conductor (54) → the fixed conductor (5
It flows to 3). Then, in the off state shown in FIG.
The link mechanism (46) is bent by the tension spring (48), the mover (51) is pulled up together with the crossbar (49), and the movable contact (51a) is opened. Next, although not shown, when an overcurrent flows in the ON state, the bimetal (56) bends and the trip bar (75) rotates, and when a large current flows, the movable iron core (55a) of the electromagnetic trip device (55) moves. It operates and the trip bar (75) rotates. The latch (76) and the latch (77) rotate, the cradle (44) disengages from the latch (77) and rises up, the link mechanism (46) bends and the mover (51) moves together with the crossbar (49). Pulled up and tripped.

In the assembled state as shown in FIGS. 1 and 2, the arm (69) is positioned by the arm adjusting screw (72) with the pivot fulcrum pin (70) being suspended and the lifting rod (73). The contact portion (69a) is in contact with the movable iron core (55a) while being locked so as not to rotate upward.
Therefore, in this state, the gear gap between the movable iron core (55a) and the fixed iron core of the electromagnetic trip device (55) is set to the initial setting value.

After assembling the arm (69) in this way, raising and lowering the arm adjusting screw (72) by turning the nut (72a) causes the tip (73a) of the lifting rod (73) to come to the cam surface (68b) of the cam (68). Since it abuts and stops, the rotation fulcrum pin (7
0) moves up and down together with the arm adjusting screw (72) along the long hole (71a), the arm (96) rotates with the pin (74) of the lifting rod (73) as a fulcrum, and the contact portion (69a) moves. Move the movable iron core (55a) up and down. When the arm (69) is further contacted with the movable iron core (55a) by the arm adjusting screw (72) in this way, play of the arm (69) due to backlash and distortion of the arm (69) can be absorbed.

The electromagnetic trip device (55) is adjusted by turning the adjustment button (24). In other words, when the adjustment button (24) is turned, the cam (68) rotates, the lifting rod (73) descends, and the arm (69) rotates in the direction of the arrow (78) with the pivot pin (70) as the fulcrum. As a result, the movable iron core (55a) descends and the movable iron core (55a) of the electromagnetic trip device (55)
The gap width between the core and the fixed core is adjusted. At this time, the looseness between the pivot fulcrum pin (70) and the hole, the looseness between the cam (68) and the lifting rod (73), and the bending of the arm (69), etc., may be small in the arm adjustment screw (72) already assembled. Since it is absorbed by the adjustment, the gear button between the movable iron core (55a) and the fixed iron core of the electromagnetic trip device (55) is correctly set to the initial setting value by operating the adjustment button (24).

Next, another embodiment of the present invention will be described with reference to FIGS. FIG. 3 is a side view showing the electromagnetic trip adjustable device, and FIG. 4 is a sectional view taken along line IV-IV in FIG. Is omitted. In the figure, (69A) is an arm into which the rotation fulcrum pin (70) is fitted, one end of which is engaged with the cam surface (68b) of the cam (68) and the other end of which is attached to the movable iron core (55a). It has an abutting portion (69a) for abutting. (71A) is an arm support member attached to the trip base (6) and has a vertically elongated hole (71a) for movably inserting the pivot fulcrum pin (70). (72A) is an arm support member (71
An arm adjusting screw inserted in a hole (71b) of (A) so as to be able to move up and down holds a pivot fulcrum pin (70) at a lower end and an upper end is received by an arm supporting member (71A) by a nut (72a). Since the operation of this embodiment is almost the same as that of the above embodiment, the description thereof will be omitted.

[Effect of device]

As described above, according to the present invention, since the play and distortion of the arm can be absorbed by adjusting the rotation fulcrum of the arm, the gear trip between the movable iron core and the rotating iron core of the electromagnetic trip device is initialized. The effect is that the value is set correctly.

[Brief description of drawings]

FIG. 1 is a vertical side view showing an embodiment of the present invention, FIG. 2 is an enlarged view showing the electromagnetic tripping adjustable device of FIG. 1, and FIG. 3 is an electromagnetic puller showing another embodiment of the present invention. FIG. 4 is a side view of the disengageable adjustable device, FIG.
FIG. 5 is a partially cutaway view showing a conventional structure, and FIG.
5 is a detailed configuration diagram of the trip device of FIG. 5, FIG. 7 is a cross-sectional view taken along the line VII-VII of FIG. 6, and FIG. 8 is a line VIII-VI of FIG.
II is a schematic sectional view, FIG. 9 is a partial configuration diagram of FIG. 6, and FIG. 10 is a perspective view of an arm. In the figure, (55) is an electromagnetic trip device, (55a) is a movable iron core, (24) is an adjustment button, (59) is a cam support,
(68) is a cam, (68b) is a cam surface, (69) and (69A) are arms, (70) is a rotation support pin, (71a) is a long hole, (7)
2) and (72A) are arm adjustment screws, and (59) to (74) are electromagnetic trip adjustable devices. In the drawings, the same reference numerals indicate the same or corresponding parts.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Koji Genba 1-8 Midoricho, Fukuyama-shi, Hiroshima Mitsubishi Electric Corporation Fukuyama Manufacturing Co., Ltd. (72) Hideaki Moriwaki 1-8 Midoricho, Fukuyama-shi, Hiroshima Mitsubishi Electric Corporation Company Fukuyama Factory

Claims (2)

[Scope of utility model registration request] 1. An electromagnetic trip device and a circuit or breaker having an electromagnetic trip adjustable device, wherein the electromagnetic trip adjustable device is a cam operated by an adjusting button and a cam of this cam. An arm that is rotated by engaging a surface and is brought into contact with the movable iron core of the electromagnetic tripping device to move, and the rotation fulcrum of the arm is adjustable so that the arm can be adjusted in the rotation direction. The circuit and disconnection characterized by 2. A cam support base for supporting a cam, wherein a rotation fulcrum pin of an arm is movably fitted in an elongated hole of the cam support base, and the rotation fulcrum pin is held to hold the elongated hole. The circuit breaker and the circuit breaker according to claim 1, wherein an arm adjusting screw for moving along the rail is attached to the cam support base.