KR19990013840A - Storage mechanism of switchgear - Google Patents

Abstract

The simple configuration in which the number of parts is reduced prevents the reversal of the main shaft during the closing operation due to the release of the closing spring.

It is fixed to the storage shaft 2, and each of the opposing portions of the drive gear 20 and the drive gear 21 sandwiched by the storage shaft 2, which transmits the rotation of the storage motor 3 to the main shaft (1). Engagement teeth 20c and 21c engaged with the drive gear 21 by rotation of the storage motor 3 are provided.

Moreover, the one-way clutch 7 is attached to the support part to the support frame 4 of the storage shaft 2, and the rotation of the storage shaft 2 by the transmission from the storage motor 3 is constrained to reverse rotation.

Description

Storage mechanism of switchgear

The present invention relates to a mechanism for storing an input spring for causing an input operation to a power switch device such as a circuit breaker, a switch.

The closing force of the circuit breaker is one that uses the storage force of the spring in order to perform the closing operation, more specifically, the moving operation of the movable contact with respect to the fixed contact which constitutes the main contact point as quickly as possible.

In this type of opening and closing apparatus, before closing operation, the closing spring is stored by compression or tension and restrained in this state. In closing, the main contact point is controlled by the storage force of the closing spring released by release of the restraint. By operating the contact input lever connected to move the movable contactor at high speed.

A storage mechanism for storing the closing spring has been proposed in various configurations together with a storage release mechanism.

Fig. 8 is a side sectional view showing the main part of a storage mechanism disclosed in Japanese Patent Laid-Open No. 9-106741 by the present applicant.

This storage mechanism is provided with the main shaft 1, the storage shaft 2, and the storage motor 3 which are substantially parallel to each other in the common support frame 4, and were supported in parallel.

The main shaft 1 holds a large cogwheel 10 at one protruding end of the support frame 4 and a feeding cam 11 at its midway portion, and these are held around the shaft in accordance with the rotation of the main shaft 1. To rotate.

The crank pin 12 protrudes from the outer surface of the large cogwheel 10 at the position which was moderately eccentric from the axial center of the main shaft 1.

One of the push rods 13 is connected to the crank pin 12, and the other end of the push rods 13 is inserted into and supported by the spring plate 40.

The spring plate 40 is, for example, a fixed plate integrally protruding from the outside of the support frame 4, and between the spring plate 40 and the pressing plate 14 fixed to the intermediate portion of the push rod 13. The injection spring 5 is installed in the.

The injection spring 5 is the spring plate 40 and the pressing plate when the protruding installation position of the crank pin 12 approaches the spring plate 40 by the rotation of the large cogwheel 10 as shown. Compressed and stored between (14).

This storage state is maintained by restraining the rotational position of the large cogwheel 10 by a restraining means (not shown). When this restraint is released, the spring force of the closing spring 5 is the pressing plate 14 and the pressing rod. Through 13 and the crank pin 12, it acts on the big cogwheel 10, and the main shaft 1 is made to rotate with a high speed with this big cogwheel 10. As shown in FIG.

The inner side of the support frame 4 is supported by the contact injection lever 6 through the support shaft 60 provided on one surface thereof.

The other side of the contact input lever 6 is supported by a roller 61 in contact with the cam surface on the outer circumference of the input cam 11, and the contact input lever 6 is adapted to the operation of the roller 61 along the cam surface. As a result, the rotation of the feed cam 11 is caused to swing around the support shaft 60, and is connected to a main contact (not shown) to perform the feed operation by the swing.

Moreover, the said storage shaft 2 is equipped with the electric cogwheel integrally fixed to the protruding end to one side of the support frame 4, and is between the electric cogwheel 20 and the outer surface of the support frame 4; Drive gear 21 fitted to move therein.

The electric cogwheel 20 is engaged with the large cogwheel 10 fixed to the shaft end of the main side 1, and the drive cogwheel 21 is an output cogwheel 30 fitted to the output end of the storage motor 3. Is interlocked.

The storage motor 3 is a geared motor in which the rotation of the motor main body 3a is decelerated and drawn out by the reduction gear 3b provided on these output sides.

The output gear 30 is fitted to the output shaft 31 of the reduction gear 3b. Between the output shaft 31 and the housing of the reduction gear 3b, there is a one-way clutch 7a that allows rotation in one direction only. It is equipped.

The drive cogwheel 21 meshing with the output cogwheel 30 slides in the relative rotational and axial length directions through the one-way clutch 7b and the projection clutch 8 which are inserted and preserved in the ball passing through the shaft center part. It is fitted to the easy storage shaft 2, and is operated toward the said electric gear 20 by the push spring 22 provided between the outer surfaces of the support frame 4. As shown in FIG.

The one-way clutch 7b provided in the drive gear 21 allows rotation in the same direction as the one-way clutch 7a provided in the reduction gear 3b, and drives the gearwheel by electric transmission from the output gear 30. The rotation of 21 is transmitted to the inner protrusion clutch 8, while the slip is generated in the reverse rotation from the protrusion clutch 8 side.

The drive gear 21 is normally pressed by the power gear 20 by the spring force of the push spring 22 which is in contact with one side, and the said drive gear 20 by the engaging action of the projection clutch 8 is carried out. It is made to rotate integrally with.

This engagement state is in the rotational position where the main shaft 1 and the large cogwheel 10 are shown, and when the closing spring 5 is in a storage state, it is largely opposed to the crank pin 12 in a radial direction. The driving cogwheel 21 is pressed by the pressing protrusion 15 provided on the other side of the cogwheel 10, and the driving cogwheel 21 is released by being separated from the transmission cogwheel 20 against the push spring force. It is supposed to be.

In the conventional storage device configured as described above, if the large gear 10 is restrained in the state shown in the drawing, the large gear rotates at a high speed in a predetermined direction by releasing the storage force of the injection spring 5, This rotation is transmitted to the contact input lever 6 via the input cam 11, and this contact input lever 6 swings on the highway and a main contact (not shown) is introduced.

In this closing operation, the rotation of the large cogwheel 10 is transmitted to the gear cogwheel 20 engaged therewith, so that the storage shaft 2 rotates, but the direction of rotation is contained in the drive cogwheel 21. The driving gear wheel 21 does not rotate, and the rotational force is not transmitted to the output shaft 31 of the storage motor 3.

In addition, the rotation of the large cogwheel 10 by the release of the closing spring continues beyond the predetermined rotational position (top dead center) by its inertia, and the closing spring 5 is stored therebetween, The gear 10 and the main shaft 1 try to reverse after exceeding the top dead center.

However, this reverse power is transmitted to the one-way clutch 7b contained in the drive cogwheel 21 through the transmission cogwheel 20, and this one-way clutch 7b engages and is transmitted to the drive cogwheel 21, It is transmitted to the output shaft 31 of the input motor 2 again through the output gear 30, and as a result of the engagement of the one-way clutch 7a mounted on the output shaft 31, the reversal is prevented and the large gear wheel 10 is constrained to the rotational position beyond the top dead center.

After the input state is obtained, when the storage motor 3 is driven to rotate, this rotation is transmitted to the drive gear 21 through the output gear 30 fitted to the output shaft 31, and again the projection clutch 8 is moved. The large cogwheel 10 which is transmitted to the transmission gear 20 through this, and meshes with the transmission gear 20 rotates.

By this rotation, the pressing rod 13 connected to the crank pin 12 is pressed down, and the closing spring 5 is compressed between the pressing plate 14 and the spring plate 40 to obtain a storage state of the city. The next closing operation becomes possible.

The rotation of the large cogwheel 10 by the rotation of the storage motor 3 is performed by the pressing projection 15 pressing the driving gear 21 at a predetermined rotational position, and the engagement of the projection clutch 8 is released. It stops and this rotation position is preserve | saved by restraint of the big gear 10 by the above-mentioned restraining means.

In the conventional storage device configured as described above, the one-way clutch 7b and the projection clutch 8 are assembled to the drive gear 21, and there is a problem that the structure of the drive gear 21 becomes complicated. In order to prevent the reversal of the large cogwheel 10 and the main shaft 1 from the top dead center, the one-way clutch 7a mounted to the storage motor 3 is used, and the whole structure including the structure of the storage motor 3 is used. There is a problem that leads to the complexity of the structure.

In addition, for the reverse stop of the large cogwheel 10, it is necessary to engage the projection clutch 8 some time until the rotation direction is switched after reaching the top dead center, and the large cogwheel 10 It is necessary to increase the precision of parts of each part that affects the engagement operation of the projection clutch 8, such as a change in the rotational speed of the c), the lubrication state between the projection clutch 8 and the storage shaft 2, and the like.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and a simple configuration in which the number of parts is reduced can reliably prevent the reversal of large gears and spindles during the feeding operation, and provides a highly reliable opening and closing device for a storage device. It aims to do it.

The storage mechanism of the opening and closing apparatus according to the present invention comprises engaging means for engaging at the time of rotation of the drive gear by the storage motor in opposing portions of the drive gear fitted to the storage shaft and the electric gear for driving to the main shaft. The one-way clutch which constrains the said rotation and the reverse rotation to the support part of a storage shaft is comprised.

In the present invention, when a large cogwheel rotates in the main contact input direction and attempts to reverse beyond the top dead center, the one-way clutch provided between the support frame engages to restrain the rotation of the storage shaft itself, thereby restoring the reversal. Stop it.

On the other hand, when the driving cogwheel by the storage motor is driven to rotate, the driving cogwheel engages with the engagement means configured at the opposite side to the cogwheel, and the electric cogwheel and the reservoir shaft rotate in the direction allowed by the one-way clutch. Through the crank part provided in the large cogwheel, the closing spring is stored.

In addition, the engaging means is constituted by providing an engagement surface that rises substantially perpendicularly to the opposite surface of the driving gear and the transmission gear, and a triangular engagement tooth having a continuous smoke.

In the present invention, the rotation of one direction is constrained by the engagement of the engagement surfaces installed on the engagement teeth provided on the opposite surface of the two cog wheels, and the rotation of the other direction is allowed by the slipping between the slopes provided on the respective engagement teeth. do.

In addition, a triangular engagement tooth having an engagement surface that rises substantially vertically and a continuous slope thereof is provided on an opposing surface of the drive gear with the electric gearwheel, and an engagement pin is installed on the storage shaft facing the engagement tooth. It constitutes the engagement means.

In the present invention, the engagement pin provided on the storage shaft restrains the rotation in one direction against the engagement surface installed on the engagement tooth of the driving tooth, and at the same time restricts the rotation in the direction in which the engagement pin is against the story of the engagement tooth. Sliding of the engagement pins on the slopes provided at the side allows rotation in the other direction.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a side sectional view showing a main portion of a storage mechanism of an opening and closing device according to the present invention;

2 is an operation explanatory diagram of a circuit breaker to which the storage mechanism according to the present invention is applied.

3 is an external perspective view of a drive gear;

4A is a front view of a drive cog wheel,

4b is a side cross-sectional view of the drive gear,

5 is an external perspective view of the gear wheel.

6A is an enlarged side view of the vicinity of a gear wheel.

6B is an enlarged cross sectional view showing the vicinity of a transmission gear.

Fig. 7 is an external perspective view of a gear wheel showing another embodiment of the engaging means.

Fig. 8 is a side sectional view showing a main portion of a storage mechanism of a conventional switching device.

Explanation of symbols for main parts of the drawings

1 spindle, 2 storage shafts,

3 storage motor, 4 support frame,

5 closing springs, 7 one-way clutch

20 gear, 20d engagement gear,

21 drive gear, 21c engagement gear.

EMBODIMENT OF THE INVENTION Hereinafter, this invention is explained in full detail according to the figure which shows the embodiment.

1 is a side cross-sectional view showing the main portion of a storage mechanism of the opening and closing device according to the present invention, Figure 2 is an operation explanatory diagram of a circuit breaker to which the storage mechanism is applied.

The storage mechanism according to the present invention, like the conventional storage mechanism shown in Fig. 8, has a main shaft (1), a storage shaft (2) and a storage motor (3) supported in parallel to each other in parallel to a common support frame (4). Equipped with.

The main shaft 1 holds the large gear 10 at the protruding end of one side of the support frame 4 by inserting the feed cam 11 in the middle part thereof, and these are rotated around the shaft according to the rotation of the main shaft 1. To rotate.

The outer surface of the large gear 10 is attached to the crank pin 12 at a position eccentrically appropriate to the shaft center of the main shaft 1.

One end of the push rod 13 is connected to the crank pin 12, and the other end of the push rod 13 is inserted into the spring plate 40.

The spring plate 40 is, for example, a fixed plate which is integrally installed on the outer side of the support frame 4, and is provided between the spring plate 40 and the pressing plate 14 fixed to the intermediate portion of the pressing rod 13. An injection spring 5 is provided.

As shown in FIG. 5, when the mounting position of the crank pin 12 approaches the spring plate 40 by the rotation of the large cogwheel 10 as shown in the drawing, the spring plate 40 and the pressing plate It is compressed and stored between (14).

In this stored state, as shown in Fig. 2, the closing mechanism 17 is engaged with the pin 16 provided at the enemy position on the outer surface of the large cogwheel 10, thereby restraining the rotation of the large cogwheel 10. Is maintained.

This restraint is released by driving the locking device 17 by a suitable driving means and releasing the engagement to the pin 16, wherein the spring force of the closing spring 5 is pressed plate 14, pressing rod 13 And the large cogwheel 10 through the crank pin 12 so that the main shaft 1 together with the large cogwheel 10 rotates about 1/2 of the highway in the clockwise rotation in FIG.

Inside the support frame 4, the contact input lever 6 is supported freely through the support shaft 60 provided on one surface thereof.

The other side of the contact input lever 6 is supported by a roller 61 in contact with the cam surface of the input cam 11 outer circumference, and the contact input lever 6 is operated by the operation of the roller 61 following the cam surface. And swing around the support shaft 60 as the feed cam 11 rotates.

The feed cam 11 has a cam surface that increases the separation distance from the shaft center of the main shaft 1 in accordance with the rotation of the clockwise rotation by opening the feed spring 5, as shown in FIG. The swing of the contact input lever 6 due to the opening of (5) is caused to occur counterclockwise in FIG.

On the other side of the contact input lever 6, pins 62 and 63 are provided on both sides of the support shaft 60, as shown in Fig. 2, and one pin 62 has an input spring ( It is connected to the main contact point 9 through the link 90 so as to perform the closing action by swinging the contact input lever 6 by the opening of 5).

When the contact input lever 6 swings until the main contact 9 of the other pin 63 is in the closed state, it engages with the opening latch 64 and restrains the swing of the contact input lever 6. The opening of the main contact point 9 drives the opening catching device 64 by a suitable driving means, and releases the engagement to the pin 63 so as to open the main spring 9. It is realized by separating the movable contactor by the spring force of 91).

In addition, 92 in FIG. 2 is a contact spring for holding | maintaining the contact pressure of the stationary contactor and the movable contactor of the main contact point 9 in an input state.

In addition, the storage shaft (2) is provided with a gear wheel (20) integrally fixed to the protruding end to one side of the support frame (4) and at the same time the outside of the gear wheel (20) and the support frame (4) A driving gear 21 is provided between the side faces, and a one-way clutch 7 is provided at a support portion on one side of the support frame 4.

The electric cogwheel 20 is engaged with the large cogwheel 10 fixed to the shaft end of the main shaft 1 and the driving cogwheel 21 is connected to the output cogwheel 30 fitted to the output end of the storage motor 3. Are interlocking.

The storage motor 3 is a geared motor in which the rotation of the motor main body 3a is decelerated and drawn out by the reduction gear 3b provided on the output side thereof, and the output gear 30 is the reduction gear 3b. Is fitted to the output shaft 31).

3 is an external perspective view of the drive cog 21 engaged with the output cogwheel 30, FIG. 4 (a) is a front view of the drive cog 21, and FIG. 4 (b) is a cogwheel 21 Is a cross-sectional side view.

As shown in these figures, the drive gear 21 has a larger engagement hole 21b on one side of the support hole 21a passing through the shaft center portion, and the engagement surface 21b has a bottom surface 24. A triangular engagement tooth 21c is formed in the circumferential direction at the place in the circumferential direction, with the engagement surface rising substantially vertically from the surface and the slope in the circumferential direction continuous with the engagement surface and having a slope continuous to the bottom surface 24. It is.

The drive gear 21 comprised in this way opposes the opening side of the engagement hole 21b in which the said engagement tooth 21c was formed, and the fixing side of the transmission gear 20, and through the said support hole 21a, Relative rotation and axial quality are fitted to the sliding shaft 2 in the direction, and the transmission gear 20 is driven by a push spring 22 provided between the outer surface of the support frame 4. It's working.

FIG. 5 is an external perspective view of the transmission gear 20 integrally formed at the shaft end of the storage shaft 2, and FIG. 6A is an enlarged side view showing the vicinity of the transmission gear 20; FIG. b) is a cross-sectional view taken along line BB of (a).

As shown in these figures, the end face 25 of the proximal end of the electric gearwheel 20 has an engagement surface that rises substantially perpendicularly from this end surface 25, and has an appropriate inclination in the circumferential direction continuously to the engagement surface. The triangular engaging teeth 20c having the slopes continuous to the end face 25 are formed in two places in the circumferential direction.

As shown in Fig. 1, the engaging cogs 20c are inclined in opposite directions to the engaging cogs 21c in the driving cogs 21 fitted to the storage shaft 2, and face each other. The engaging means, which is a feature of the present invention, is constituted.

The engagement means is engaged with the driving gears 20 when the engagement surfaces of the engagement teeth 20c and 21c abut when the transmission gear 20 rotates relative to the driving gear 21 in one direction. When the wheels 21 are engaged, and both of them are integrally rotated while the relative rotation occurs in the opposite direction, the rotation is allowed by the sliding of the slopes of the engaging teeth 20c and 21c to drive the gears ( 21) to keep the non-rotating state.

The engagement of the engagement means is such that it occurs in the rotational direction of the drive gear 21 by the rotation of the storage motor 3.

Moreover, the one-way clutch 7 provided in the support part of the storage shaft 2 in one side wall of the support frame 4 is comprised by the rotation of the direction which produces the said engagement, and restrains rotation in the opposite direction.

The driving gear 21 is normally pressed by the transmission gear 20 by the spring force of the push spring 22 which is in close contact with one side, and this pressing is performed by the main shaft 1 and the large gear 10 as shown in FIG. In the rotational position shown in Figs. 1 and 2, when the closing spring 5 is in the storage state, the pressure is provided on the other side of the large cogwheel 10 substantially opposite the crank pin 12 in the radial direction. It is pressed by the protrusion 15, and the drive gear 21 is released by carrying out from the transmission gear 20 against the spring force of the push spring 22. As shown in FIG.

In the storage device according to the present invention configured as described above, when the closing device 17 is driven in the state shown in FIGS. 1 and 2 and the restraint of the large cogwheel 10 is released, the storage force of the closing spring 5 is achieved. This is released, the large gear 10 rotates as described above, and the rotation is transmitted to the contact input lever 6 via the input cam 11, the contact input lever 6 is the highway swing, the pin The main contact 9 is introduced by the operation of the link 90 connected to 62.

In this closing operation, the rotation of the large cogwheel 10 is transmitted to the oscillating cogwheel 20 engaged therewith and the storage shaft 2 rotates, but the direction of rotation at this time is the support portion of the storage shaft 2. The driving gear 21 which is a direction allowed for the installed one-way clutch 7 and slipping in the engagement means and fitted to the storage shaft 2 is kept in a non-rotating state, and the rotational force is stored in the storage motor 3. It is not transmitted to the output shaft 31 of ().

The rotation of the large cogwheel 10 due to the opening of the feed spring 5 is because the feed spring 5 is stored over the predetermined rotational position (top dead center) by its inertia, and thus the large feed dog The wheel 10 and the main shaft 1 try to focus after exceeding the top dead center, and this rotation is transmitted from the gearwheel 20 to the storage shaft 2.

However, this reversal direction is a direction in which restraint occurs in the one-way clutch 7 provided in the support part of the storage shaft 2, and the reversal is prevented by the engagement of the one-way clutch 7, and the large cogwheel 10 is It is constrained to rotational position exceeding top dead center.

After the input state is obtained, when the storage motor 3 is driven to rotate, this rotation is transmitted to the drive gear 21 through the output gear 30.

The direction of rotation is the direction in which engagement occurs in the engagement means, and the rotation of the drive gear 21 is performed by the one-way clutch 7 provided on the support of the storage shaft 2. It is transmitted to 20, this gearwheel 20 and the storage shaft 2 rotates, and the large gearwheel 10 which meshes with the gearwheel 20 rotates.

By this rotation, the pressing rod 13 connected to the crank pin 12 is pushed downward to compress the closing spring 5 between the pressing plate 14 and the spring plate 40, thereby obtaining a storage state as shown. The following closing operation becomes possible.

Rotation of the large cogwheel 10 by the rotation of the storage motor 3, the driving cogwheel 21 is pressed by the pressing projection 15, the engagement of the engaging means constituted between the electric cogwheel 20 It is automatically stopped by being released, and this rotational position is preserved by the closing mechanism 17 engaging the pin 16 and restraining the rotation of the large cogwheel 10.

Thus, in the storage mechanism which concerns on this invention, the simple mechanism provided with the engagement means comprised between the opposing surface of the electric gearwheel 20 and the drive gearwheel 21, and the one-way clutch 7 arrange | positioned at the support part of the storage shaft 2 With one configuration, the same operation as in the prior art can be achieved, and the operation of the one-way clutch 7 for the reverse gearing of the large cogwheel 10 and the main shaft 1 is independent regardless of the engagement state of the engagement means. In this way, the above reversal can be reliably prevented without increasing the parts precision of each part.

In addition, the engagement teeth 20c and 21c constituting the engagement means have a simplified form as shown in Figs. 3 to 6, and since high shape precision is not required, the transmission gear 20 and the drive tooth are Together with the wheel 21, it can be integrally formed by cold forming, and it can be configured with high strength with a small number of processings, and the reliability is improved.

The engagement means is not limited to the engagement teeth 20c and 21c formed on the transmission gear 20 and the drive gear 21, but can be implemented in other forms.

Fig. 7 is an external perspective view of the gear wheel 20 implementing another embodiment of the engaging means.

In this drawing, the engagement pins 23 are provided in a shape penetrating the storage shaft 2 in the radial direction at a position close to the transmission gear 20 fixed to the shaft end, and the protrusions of these engagement pins 23 are provided. The engagement state is obtained against the engagement surface of the engagement tooth 21c of the drive gear 21 side as shown to FIG. 3 and FIG. 4, and the engagement is released by sliding along the slope of the engagement tooth 21c. The state is being obtained.

As described above, in the storage mechanism of the switchgear according to the present invention, the engaging means engaged at the time of rotation by the storage motor is provided at an opposing portion between the drive gear fitted to the storage shaft and the electric gearwheel for transmission on the main shaft. Since the one-way clutch which constrains the said rotation and the reverse rotation to the support part of the storage shaft is comprised, the simple structure which reduced the number of parts can reliably prevent the large gearwheel and the spindle reversal in a feeding operation. have.

Further, the engaging means is constituted by a triangular engaging tooth provided with an engaging surface which rises substantially perpendicular to the opposing surfaces of the driving gear and the electric gear, and a slope that is continuous to the engaging gear. Since the same engagement teeth provided on the opposing surface on the driving gear side and the engagement pins provided on the storage shaft facing the engagement teeth are secured, a secure engagement and disengagement state is obtained.

In addition, the present invention exhibits excellent effects, such that the engaging teeth can be integrally formed by driving gears or electric gears by cold forging, and can form a high-strength engaging tooth without requiring machining.

Claims (3)

It has an input cam linked to the contact input lever of the switchgear and a crank section linked to the input spring, rotates by electric power from a storage motor, stores the input spring by the action of the crank part, and opens the input spring. By the action of the input cam, the main shaft for moving the contact input lever and the closing operation by the input cam, and the storage shaft parallel supported on the support frame common to the main shaft and the storage Drive gear wheels are mounted so as to slide in the direction of oil field and shaft length and rotate by transmission from the storage motor, and are fixed to the storage shaft in close proximity to the drive gear wheels. It is comprised in the transmission gear which transmits to the said main shaft, and this opposing part of this driving gear and the said transmission gear, Engaging means engaged with the rotation of the drive gear wheel by the storage motor, and a one-way clutch provided at the support position of the storage shaft in the support frame and restraining the rotation of the storage shaft in the opposite direction to the storage direction. Storage mechanism of the switchgear characterized in that. The method of claim 1, The engaging means are provided on opposite surfaces of the drive gear wheel and the transmission gear, respectively, and are engaged with each other in the circumferential direction in the circumferential direction continuously with the engaging surface rising substantially perpendicularly from the opposite surface. A triangular engagement tooth having an inclination and a slope continuous to the opposing surface, and an operation spring for operating the drive gear toward the electric gear, and the rotation of the storage direction is butted between the engagement surfaces; And a mechanism for allowing the rotation in the reverse direction to be allowed by sliding of the slopes in opposition to the spring force of the operating spring. The method of claim 1, The engagement means is provided on an opposing surface of the drive cogwheel with the electric cogwheel, and has an engagement surface that rises substantially perpendicularly from the opposing surface, and has a predetermined inclination in the circumferential direction continuously to the engagement surface. Triangular engaging teeth having slopes continuous to opposite surfaces, engaging pins radially installed on the storage shaft between the driving gears and the transmission gears, and the driving gears directed toward the transmission gears. An actuating spring and constraining the rotation in the storage direction due to the abutment of the engaging pin to the mating surface, and rotating in the opposite direction to the sliding of the mating pin, which occurs against the spring force of the actuating spring along the slope; Storage mechanism of switchgear with the configuration allowed by