JPH0690896B2 - Operating device for shiya breaker - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an operating device for performing a closing operation and a tripping operation of a circuit breaker by an operation spring.

[Conventional technology]

1 to 6 each show a conventional operating device for this type of circuit breaker. FIG. 1 is a front view and FIG. 2 is a sectional view taken along line (II)-(II) of FIG. FIG. 3 is a cross-sectional view taken along line (III)-(III) of FIG. 1, and FIGS. 4 to 6 are operation explanatory views. First, in FIGS. 1 and 2, (1)
Is a frame, (2) is a support pin that rotatably supports the operation lever (3), and (4) is a connection pin which is planted at one end of the operation lever (3) and connected to an opening / closing device (not shown). This connecting pin (4) is constantly urged in the direction of arrow (C) by a trip spring (not shown) provided in the opening / closing device (not shown). (6) is a roller rotatably mounted by a pin (7) in a groove (5) formed at a predetermined position of the operation lever (3),
(8) is a stopper pin which is planted at a predetermined position of the operation lever (3), and the stopper pin (8) is provided at a predetermined position of the frame (1) as shown in FIG. ) A first latch (10) rotatably supported by
It is provided in order to engage with the hook portion (10a) of the and to prevent the operation lever (3) from rotating in the counterclockwise direction. (12) is a first trigger lever rotatably supported by a support pin (11) at a predetermined position of the frame (1) in the vicinity of the first latch (10). Reference numeral 12) is provided for locking the clockwise rotation of the first latch (10) when the first tripping electromagnet (16) described later is deenergized. (13) and (1
4) is the first latch (10) and the first trigger lever (1
2) Return springs for returning and counterclockwise, and (16) tripping electromagnet having a plunger (15) that moves forward and backward in a predetermined stroke when the power is turned "ON" or "OFF",
Reference numeral (17) is a main shaft of an operating device rotatably supported at a predetermined position of the frame (1) near the operation lever (3), and the main shaft (17) has a roller ( A cam (18) slidably and slidably attached to 6) is integrally mounted.

Next, in FIG. 3, reference numeral (19) is a ratchet wheel integrally attached to the main shaft (17), and the groove (20) formed on the outer circumference of the ratchet wheel (19) has an angle of about 180 ° on both sides. A pair of serrated teeth (21) (21) are provided in the range. When the ratchet wheel (19) receives a force to rotate counterclockwise by the closing spring (37) described later, the support pin (23)
The hook portion (24a) of the second latch (24) rotatably supported by means of engaging with the stopper pin (22) planted at a predetermined position in the groove (20) of the ratchet wheel (19). Thus, the rotation of the ratchet wheel (19) is prevented. further,
Even if the hook portion (24a) of the second latch (24) is engaged with the stopper pin (22) of the ratchet wheel (19), the second latch (24) may be rotated counterclockwise. , The second trigger lever (26) rotatably supported by the support pin (25) at a predetermined position of the frame (1) is engaged with the second latch (24), so that the rotation is prevented. It's locked.
(27) is a return spring for returning the second latch (24) in the clockwise direction, and (28) is the second trigger lever (2).
6) A return spring for returning the counterclockwise direction, (30) is a closing electromagnet having a plunger (29) that advances and retracts in a predetermined stroke when the power is turned “ON” and “OFF”, and (31) is the above-mentioned ratchet wheel (19). An eccentric shaft rotatably supported in the vicinity of the frame (1) and rotated at a predetermined speed by, for example, a reduction motor (not shown). The eccentric shaft (31) has a different eccentric direction (180 °). Is formed, and a pair of drive claws (32) (33) having different claw lengths are swingably fitted to the eccentric ring part as shown in FIG. . The tip ends of the drive claws (32) (33) are in sliding contact with the pair of saw blade teeth (21) (21) formed on the outer circumference of the ratchet wheel (19). When the drive claws (32) (33) alternately make a swinging motion with the rotation of the eccentric shaft (31), the drive claws (32) (33) are alternately moved by the claw wheel (19). It engages with the teeth (21) (21) and rotates the ratchet wheel (19) counterclockwise. The spring receiving plate (34) has one end connected to a crank pin (35) planted at a predetermined position on the side surface of the ratchet wheel (19) and the other end supporting the free end of the closing spring (37). Fig. 3 shows a crank rod connected to the 36) via a retaining bush (36a). Fig. 3 shows the restoring elastic force of a compressed closing spring (37) via the crank rod (34) and the ratchet (19). The state is shown in which it is transmitted to the main shaft (17) and a counterclockwise rotational force is applied to this main shaft.

The conventional breaker operating device is constructed as described above. First, the tripping operation will be described.

In FIG. 2, when the tripping electromagnet (16) is excited and the plunger (15) extends, the tip of this engages with one end of the first trigger lever (12) and resists the return spring (14). Is rotated clockwise, the other end of the first trigger lever (12) is disengaged from the first latch (10),
The stake (10) becomes free. Therefore, the connecting pin (4) of the operating lever (3), which is always urged in the direction of arrow (C), rapidly rotates in the direction of arrow (C), and the opening / closing device (Fig. (Not shown) is tripped. The state during this tripping operation is shown in FIG. During the tripping operation described above, the constituent members shown in FIG. 3 do not operate at all.

Next, the closing operation will be described.

In FIG. 3, when the closing electromagnet (30) is excited and the plunger (29) extends, its tip engages with one end of the second trigger lever (26) and resists the return spring (28). Since this is rotated clockwise, the other end of the second trigger lever (26) is disengaged from the second latch (24), and the second latch (24) becomes free. Therefore, the stopper pin (2) is attached to the hook portion (24a) of the second latch (24).
The ratchet wheel (19), which has been prevented from rotating by the engagement of 2), rapidly rotates counterclockwise together with the main shaft (17) by the restoring elastic force of the compressed closing spring (37). Therefore, as shown in FIG. 4, the cam (18) integral with the main shaft (17) also rotates in the counterclockwise direction, so that the cam (18) passes through the roller (6) of the operation lever (3). Rotate the operating lever (3) clockwise. Therefore, the connecting pin (4) of the operating lever (3) is rotated in the direction opposite to the arrow (C) to turn on the switchgear (not shown) connected thereto, and at the same time, the trip spring (Fig. (Not shown) is compressed to store energy. In this way, when the operating lever (3) returns to the state shown in FIG. 2, the first latch (10) and the first trigger lever (12).
Is returned to the original state by the return springs (13) (14).
Then, when the cam (18) further rotates together with the main shaft (17) and is separated from the roller (6) of the operation lever (3),
As shown in FIG. 5 of the operation lever (3), the stopper pin (8) is engaged with the hook portion (10a) of the first latch (10) to lock the rotation, so that the opening / closing device is in the closed state. Is maintained.

The main shaft (17) rotates counterclockwise to the bottom dead center by the restoring elastic force of the closing spring (37), and then the main shaft (17) and the cam (1) given by the closing spring (37).
8), the closing spring (37) is rotated again while being compressed by the rotation energy of the ratchet wheel (19) and stopped when the rotation energy disappears. Then, after this, the main shaft (17) starts to rotate clockwise again by the restoring elastic force of the closing spring (37), but the drive claw (32) is attached to the teeth (21) (21) of the ratchet wheel (19).
The rotation is locked by the engagement of (33).

Next, the energizing operation of the closing spring (37) will be described. When the closing operation described above is completed, the closing spring (37) is fully extended as shown in FIG. 6, and in this state, the eccentric shaft (31) is rotated by the reduction motor (not shown), and the drive claw ( When 32) and (33) alternate rocking motion,
These both drive claws (32) (33) are the teeth (21) (2) of the ratchet wheel (19).
Since the ratchet wheel (19) is rotated in the counterclockwise direction by engaging with 1), the crank rod (34) is gradually closed by the closing spring (37).
Is compressed and stored. Then, as shown in FIG. 3, when the closing spring (37) is fully compressed, the second latch (24) and the second trigger lever (26) cause the return springs (27) (28). ), The stopper pin (22) of the ratchet wheel (19) is rotated even if the ratchet wheel (19) tries to rotate counterclockwise due to the restoring elastic force of the closing spring (37). Hook part (24a) of the second latch (24)
The rotation of the closing spring (37) is locked by engaging with, and the energization state of the closing spring (37) is maintained.

[Problems to be solved by the invention]

Since the conventional breaker operating device is configured as described above, when the closing electromagnet (30) is excited by an erroneous signal while the closing spring (37) is being charged, the second trigger lever is activated. (26) is disengaged from the second latch (24), and the second latch is freed to unlock the ratchet wheel (19). When the circuit breaker is already closed, the closing spring ( 37) has the drawback that it is released without load.

The present invention has been made paying attention to such a point, and even if the closing electromagnet (30) is excited by an erroneous signal when the circuit breaker is in the closing state and the closing spring (37) is energized, It is intended to provide an operation device for a circuit breaker in which the second trigger lever (26) is not separated from the second latch (24) and the closing spring (37) is released without load. .

[Means for solving problems]

The breaker operating device according to the present invention is such that the operation piece swingably attached to the tip of the plunger of the closing electromagnet is changed in direction by the kick lever which is rotated in conjunction with the trip electromagnet. is there.

[Work]

According to the present invention, even if the closing electromagnet is erroneously excited when the circuit breaker is in the closed state and the closing spring is being charged, the operation piece is operated by the kick lever which is rotated in conjunction with the tripping electromagnet. Even if the plunger of the energized closing electromagnet is changed in direction and is extended, the operating piece avoids the trigger lever and does not operate it, thereby preventing the closing spring from being released.

〔Example〕

That is, although FIGS. 7 to 10 all show an embodiment of the present invention, the same reference numerals as those of the above-described conventional device (FIGS. 1 to 6) are used for the same constituent members, and the description thereof will be omitted. Omit it.

First, in FIGS. 7 and 9, (10b) is a notch step portion formed at the tip of the first latch (10), and the notch step portion (10b) is supported by the frame (1). Pin (42)
One end of a kick lever (41) rotatably supported by is engaged with the kick lever (41) in a disengageable manner, and a kick pin (43) is planted at the other end of the kick lever (41). Then, when the kick lever (41) is rotated clockwise, an operation piece (45) described later is rotated counterclockwise. Reference numeral (44) is a spring that constantly urges the kick lever (41) clockwise.

Next, in FIG. 8 and FIG. 10, (45) is an operation piece pivotally attached to the tip of the plunger (29) of the closing electromagnet (30) by a support pin (47). (Four
5) is the plunger (2) when the input electromagnet (30) is excited.
When the kick lever (41) is not engaged when the kick lever (41) is extended, the kick lever (41) is engaged with one end of the second trigger lever (26), and is rotated clockwise against the return spring (28). It is designed to perform the closing operation. When the first latch (10) engages with the stopper pin (8) of the operation lever (3) at the end of this closing operation as described above, the first latch (10) causes the counterclockwise movement. When the kick lever (41) is released from the notched step portion (10b) of the first latch (10) by rotating in the direction shown in FIG. 7 from the state shown in FIG. ), The kick pin (43) at the other end of the kick lever (41) pushes up the free end of the operating piece (45) and rotates it counterclockwise as shown in FIG. , Even if the closing electromagnet (30) is erroneously excited and the plunger (29) extends, the operating piece (45) does not engage the second trigger lever (26), and therefore the closing spring (37) is unloaded. There is no such thing as letting go.

〔The invention's effect〕

As described above, according to the present invention, even if the closing electromagnet (30) is excited by an erroneous signal when the circuit breaker is in the closed state and the closing spring (37) is energized, the second This has an excellent effect that the trigger lever (26) does not rotate and the closing spring (37) is released without load.

[Brief description of drawings]

1 to 6 each show a conventional operating device for this type of circuit breaker. FIG. 1 is a front view and FIG. 2 is a sectional view taken along line (II)-(II) of FIG. 3 is a sectional view taken along line (III)-(III) of FIG. 1, and FIGS. 4 to 6 are operation explanatory views. 7 to 10 show an embodiment of the present invention. FIG. 7 is a sectional view of a portion corresponding to FIG. 2 of the above-mentioned conventional one, and FIG. 8 is of the above-mentioned conventional one. A sectional view of a portion corresponding to FIG. 3, and FIGS. 9 and 10 are operation explanatory views. In the figure, (1) is a frame, (3) is an operating lever,
(4) is a connecting pin, (8) is a stopper pin, (17) is a spindle, (10) is a first latch, (10b) is a notch step, and (12).
Is a first trigger lever, (19) is a ratchet wheel, (22) is a stopper pin, (24) is a second latch, (26) is a second trigger lever, (29) is a plunger, and (30) is Closed solenoid valve, (3
2) (33) drive pawl, (37) closing spring, (41) kick lever, (42) support pin, (43) kick pin,
(44) is a spring and (45) is an operation piece. The same reference numerals in the drawings indicate the same or corresponding parts.

Claims (3)

[Claims] 1. A plunger of a closing electromagnet corresponding to a second trigger lever for locking the rotation of the ratchet wheel, wherein the closing operation of the opening / closing device is performed via an operating lever and a ratchet wheel storing a closing spring. While the operation piece is attached, the operation piece is urged between the first latch and the operation piece so as to be constantly rotated in the clockwise direction, and at the end of the closing operation, the operation piece is pushed up to move the operation piece to the second trigger lever. A breaker operating device comprising a kick lever for releasing engagement. 2. The kick lever is rotated by being released from a notched step portion of a latch rotated by the operation lever at the end of the closing operation, and the direction of the operation piece is changed via the kick pin. The operating device for a circuit breaker according to claim 1, wherein 3. The operating device for a circuit breaker according to claim 1, wherein the kick lever is adapted to change the direction of the operating piece by a spring.