JP2007123179A - Battery pack - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a battery pack for which engagement of the battery pack having large mass with an electric apparatus is hardly released, in an environment with vibration applied thereto. <P>SOLUTION: This battery pack is provided with: a claw part 120 mounted and fixed to an electric apparatus and carrying out engagement with a part to be engaged which is arranged in the electric apparatus, and an operation part 110 operated in releasing the engagement. The operation part 110 is swingably supported; the claw part 120 is slidably supported; and the action part of the operation part 110 and the power point part of the claw part 120 are linked to each other through a link mechanism. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a latch mechanism attached to a battery pack in order to engage the battery pack with an electric device. In particular, even when the electric device is used in an environment where the electric device vibrates, the engagement of the battery pack is released. It is related to technology to make it difficult to be done.

In recent years, a battery pack in which a secondary battery or the like is packaged is widely used, and is used in an electric device such as a mobile phone, a digital camera, and an electric bicycle.
Usually, such a battery pack is engaged by using a latch mechanism or the like when housed on the electric device side.
As such a battery pack, for example, as shown in FIGS. 12a to 12d, in order to attach and fix a battery pack 1000 comprising a main body 1001 and a casing part 1002 to an electric device 1003, the end face of the casing part 1002 is moved upward. There is one that uses the extension of the extended claw portion 1000A to press and engage the claw portion 1000A with the recess 1003A on the electric device 1003 side. (For example, Patent Document 1)
Further, the casing portion 1002 has a flat operation portion 1002B extending from the claw portion 1000A. To release the engagement, as shown in FIG. 12c, the operation portion 1002B in the engagement portion 1001 is provided. The battery pack 1000 can be removed from the electric device 1003 by pressing the battery pack in the direction of arrow A and lifting the battery pack 1000 upward.

Thus, by providing a latch mechanism using a part of the casing of the battery pack 1000, the battery pack can be easily engaged with an electric device.
Japanese Utility Model Publication No. 07-029740

However, in the battery pack latch mechanism as described above, the urging force is obtained by utilizing the bending of the claw portion extending from the end surface of the battery pack casing, so there is a limit in obtaining a large urging force. It is impossible to engage a battery pack having a large mass.
Moreover, when using for engagement with electric equipments, such as an electric bicycle, since a vibration is added to a battery pack, there exists a problem that a nail | claw part will move by vibrating and engagement with a recessed part will be cancelled | released.

Therefore, the present invention has been made in view of the above problems, and is a pack in which engagement with an electric device is difficult to be released even when used in an environment where vibration is applied or when the mass of the battery pack is large. The object is to provide a battery.

In order to achieve the above-described object, a battery pack according to the present invention includes an engaging portion that is attached and fixed to an electrical device and that engages with an engaged portion disposed in the electrical device, and the engagement battery. A battery pack including an operation unit that is operated when releasing the engagement, wherein the operation unit is swingably supported, and the engagement unit is slidably supported. The action part of the part and the force point part of the engaging part are connected via a link mechanism.

In the configuration of the battery pack described above, when vibration is applied to the battery pack, the inertial force works in one direction, but the operating portion is supported to be swingable, whereas the engaging portion is slidably supported. Therefore, the directions in which the two can move are different, and the operating portion and the engaging portion are connected via the link mechanism. Therefore, a deterrent to the movement acts and the engaging portion is difficult to be released.
Since the operating part and the engaging part are composed of separate members, the degree of freedom in designing the engaging part is improved compared to the conventional latch mechanism, so the engaging part has a large stroke and high strength. Therefore, even a battery pack having a large mass and a large inertial force and gravity can be engaged firmly.

The link mechanism includes a convex portion disposed in the operation portion, a long groove portion disposed in the engagement portion, and a support portion that pivotally supports the operation portion, and the convex portion. May be fitted in the groove portion and slidable along the groove, the convex portion may be the action portion, and the contact portion of the groove portion with the convex portion may be the force point portion.

With this configuration, the swinging motion of the action portion can be converted into the linear motion of the power point portion.
Further, when the position of the convex portion in the groove at the time of engagement is the first position and the position of the convex portion in the groove at the time of disengagement is the second position, the first position in the groove is The groove is bent between the first position and the second position, and in the vicinity of the second position, and a region from the first position to the bent position in the groove is defined as a first region. When the second region extends from the bent position to the second position in the groove, a force that causes the convex portion to enter the second region from the first region is urged by the engaging portion. The position of the operation unit may be fixed by the entry.

As a result, since the operation unit is fixed when the engagement is released, it is not necessary to continuously apply external force to the operation unit once the engagement is released. can do.
Further, the urging force may be a restoring force of an elastic member that is in contact with the engaging portion and is disposed at a position toward which the engaging portion faces when the engagement is released.

Thereby, the urging force can be obtained with a simple configuration.
In addition, a fitting part is provided in the support part, a fitted part is provided in the operation part, and when the engagement is released, the fitting part and the fitted part overlap, When the overlap occurs, it is desirable that the fitting portion and the fitted portion are fitted to fix the position of the operation portion.

As a result, since the operation unit is fixed when the engagement is released, it is not necessary to continuously apply external force to the operation unit once the engagement is released. can do.
The link mechanism includes a cam attached to the operation portion and swinging integrally with the operation portion, and a flat portion disposed on the engagement portion and contacting the cam. It is good also as a structure which the said engaging part moves by the said cam pressing the said plane part with a movement, and the said engagement cancellation | release occurs.

With the above configuration, the swing motion can be converted into a linear motion.
Further, it is desirable that a torsion spring for applying a biasing force to the operation unit is wound around the swing shaft of the operation unit so as to swing in a direction in which the engagement occurs.
Thereby, the restoring force of the spring can be used as a driving force for the engagement, and the engagement is more reliably performed.

(Embodiment 1)
1. Configuration FIG. 11 is an external view of battery pack 90 according to Embodiment 1 of the present invention.
The pack battery 90 is a pack battery used in an electric device to which vibration or impact is applied, such as a portable printer, a portable liquid crystal television, a portable DVD player, and an electric bicycle. The claw portion 120 and the projection 90a that extend from the latch mechanism 100 that can be moved in and out are engaged with two concave portions (not shown) provided in a storage portion (not shown) on the electric device side. , Is to be fixed.

FIG. 1 is an external view of the latch mechanism 100 described above.
The latch mechanism 100 is disposed in the battery pack 90, and when the battery pack is stored in the storage space of the electric device, the claw portion moves linearly by swinging the operation portion, so that the casing end surface of the battery pack is provided. This is a mechanism for engaging the battery pack and the electric device firmly by engaging the claw portion protruding from and protruding into a recess (not shown) arranged on the electric device side.

  More specifically, the latch mechanism 100 includes an operation unit 110 that is pivotally attached to a fixing pin 102 that is bridged with a pair of side surfaces facing each other on the inner side surface of the casing unit 101 (hereinafter referred to as “casing side surface pair”). And a guide part 101a formed integrally with the casing part 101 and a claw part 120 guided by the guide part 101b so as to be slidable in the X-axis direction are connected via a link mechanism. A spring 117 that applies a biasing force to the operation unit 110 is wound around the fixing pin 102 so that 121 protrudes from the end surface of the casing unit 101.

The spring 117 is a so-called torsion spring made of a coil spring.
The end portion 117 a of the spring 117 is in contact with the wall surface of the casing portion 101 so that the urging force is generated, and the other end portion 117 b is fixed to the operation portion 110.
Each of the pair of inner side surfaces facing each other in the casing portion 101 has a recess that fits into one of a protruding portion 116a and a protruding portion 116b, which will be described later, when the main body 121 completes protruding from the end surface of the casing portion 101. Here, the concave portion 103a is a portion which is on the Y-axis arrow direction side and fits with the protruding portion 116a, and the concave portion is a portion which is opposite to the Y-axis arrow direction and is fitted with the protruding portion 116b. 103b.

Normally, the battery pack has a rectangular parallelepiped shape, and the casing of the battery pack can be extended by extending the casing of the battery pack so that the casing of the battery pack can also be used as the battery pack casing. In the casing portion 101 of the latch mechanism for the battery pack, an example in which the battery pack 90 is disposed in the casing of the battery pack 90 is shown.
In addition to this, there is also a method in which the casings are integrated by joining the end face in the X-axis arrow direction of the casing portion 101 in FIG. 1 and the end face of the casing of the rectangular battery pack.

FIG. 2 is an external view of the latch mechanism 100 with the casing 101 removed, and FIG. 3 is an external view of only the operation unit 110.
FIG. 4 is a cross-sectional view obtained by crossing the center position in the Y-axis direction of the latch mechanism 100 in FIG. 1 with the XZ plane, and shows an initial state, that is, a state in which no external force is applied to the operation unit 110. Show.

The operation unit 110 is provided with a through hole 115a and a through hole 115b for inserting the fixing pin 102 in the main body 114 serving as a skeleton, and at a distance A from the fixing pin 102 as shown in FIG. The link pin 112a and the link pin 112b face each other, and the facing direction is arranged to be the same as the axial direction of the fixed pin 102.
Furthermore, the main body 114 has a grip region 111 that is shaped so that the user can easily grip it at a distance B from the fixed pin 102, and is opposed to each surface of the casing side pair described above. The two side surfaces are respectively provided with a protruding portion 116a and a protruding portion 116b.

Further, a hole 113 for inserting the end 117b of the spring 117 is provided in the main body 114.
In the casing portion 101, a planar guide portion 101a and a guide portion 101b that are parallel to each other for guiding the claw portion 120 only in the X-axis direction, and a spring receiving portion 101s that receives the end portion 117a of the spring 117 are integrally molded. ing.

The claw portion 120 is made of a thermoplastic resin material having a good moldability and slidability such as POM, and has a main body portion 121 having a trapezoidal shape at the tip portion as shown in FIG. An oval groove 122 extending in the Z-axis direction is disposed at the end.
For convenience, it is assumed that the groove portion 122 penetrates in the Y-axis direction in the main body portion 121, but may actually be a groove that is engraved.

The trapezoidal shape at the distal end of the main body 121 is that when the battery pack is attached to an electric device, the member on the electric device side comes into contact with the inclined portion of the trapezoidal shape, so that the claw 120 is naturally pushed down in the immersion direction. Therefore, the inclined portion is disposed at a position where the inclined portion first comes into contact with a member on the electric device side during the mounting.
2. About Operation In the initial state, the link pin 112 a is located at the lowest position of the groove 122.

At this time, the unillustrated link pin 112b is also positioned at the lowest position of the groove 122, and at this time, the main body 121 is in a positional relationship protruding from the end surface of the casing 101, and such a state is called a locked state.
FIG. 5 shows the movement of the main body 121 when the operation unit 110 is swung by applying an external force to the grip area 111 of the operation unit 110 in the direction of the Z-axis arrow and in the direction opposite to the X-axis arrow direction. It is a figure explaining and shows the state at the time of completion of immersion of the body part 121.

When the immersion of the main body 121 is completed, the operation unit 110 moves upward, and the link pin 112a is positioned at the top of the groove 122.
At this time, the link pin 112b (not shown) is also positioned at the top of the groove 122.
Furthermore, the claw portion 120 moves linearly in the X-axis arrow direction side as compared with the position in the initial state, and the main body portion 121 is immersed in the opening portion 101 c provided on the end surface of the casing portion 101.

For convenience, the state as described above is referred to as an unlocked state.
This is because the movement in the X-axis arrow direction and the Z-axis arrow direction that occurs when the link pin 112a swings integrally with the operation unit 110 is caused by the action of the groove portion 122 extending in the Z-axis direction of the claw portion 120. This is because the movement in the Z-axis arrow direction is canceled and only the movement in the X-axis direction is taken out.

At this time, the recesses 103 a and the recesses 103 b provided on both outer side surfaces of the main body 114 are fitted into the protrusions 116 a provided on both inner side surfaces of the casing unit 101.
Even if the external force applied to the grip area 111 is lost by this fitting, the unlocked state can be maintained.
3. Summary In this way, the fixed pin 102 that is the swing shaft serves as a fulcrum, the grip area 111 of the operation unit 110 serves as a power point, and the link pin 112a and the link pin 112b serve as action points, and the force that is pulled up by the user's hand. A horizontal component (X-axis component) of the resultant force obtained by subtracting the reaction force of the spring from B / A is added to the link pin 112a and the link pin 112b, and the claw portion 120 is drawn.

The operation unit 110 is supported to be swingable, and the claw unit 120 is supported to be slidable.
Since both are connected via a link mechanism, it is difficult to move even if vibration is applied.
Further, as the value of B / A is increased, the force to move the claw 120 in and out can be reduced, and accordingly, the set value of the spring constant of the spring 117 is increased to increase the reaction force, and the main body 121 is fitted. The pressing force to the concave portion can be increased to perform stronger engagement.

For this reason, even if strong vibration is applied to the electric device, the battery pack engaged with the electric device is not easily detached.
(Embodiment 2)
1. Configuration FIG. 6 is an external view of a latch mechanism 200 included in a battery pack (not shown) according to Embodiment 2 of the present invention.

Here, the battery pack according to the second embodiment is the same as that of the battery pack 90 except that the battery pack is longer than the casing of the battery pack 90 and that the latch mechanism 200 is included instead of the latch mechanism 100. Since it is the same as the battery pack 90 of the form 1, detailed description is omitted.
This latch mechanism 200 is disposed in the battery pack, similarly to the latch mechanism 100 in the first embodiment. When the battery pack is stored in the storage space of the electric device, the claw portion that protrudes and protrudes from the casing end surface of the battery pack is provided. It is a mechanism that meshes with a recess (not shown) arranged on the electric device side and firmly engages the battery pack and the electric device.

More specifically, the latch mechanism 200 has a configuration substantially similar to the configuration of the latch mechanism 100 in the first embodiment.
That is, the latch mechanism 200 includes a casing part 201, an operation part 210, a spring 217, and a claw part 220 corresponding to the casing part 101, the operation part 110, the spring 117, and the claw part 120, which are constituent members of the latch mechanism 100. However, except for the spring 217, a part of the shape is different from the latch mechanism 100.

The spring 117 according to the first embodiment is a torsion spring, whereas the spring 217 according to the second embodiment is a so-called compression spring.
Note that the same fixing pin 102 as that of the latch mechanism 100 is used in the latch mechanism 200.
Hereinafter, a difference between the latch mechanism 200 in the second embodiment and the latch mechanism 100 in the first embodiment will be described in detail.
1) About the casing portion As shown in FIG. 7, the casing portion 201 is longer in the X-axis direction than the casing portion 101, and further, a boss for fixing the spring 217 to the center of the inner wall surface in the X-axis arrow direction. Unlike the casing part 101 in that the part 201d is provided and there is no member corresponding to the concave part 103a, the concave part 103b and the spring receiving part 101s, other configurations such as the guide part 201a, the guide part 201b and the opening are provided. About the part 201c etc., it is the structure similar to the guide part 101a of the latch mechanism 100, the guide part 101b, and the opening part 101c.
2) About the operation unit The operation unit 210 has the same structure as the operation unit 110 except that there are no parts corresponding to the hole 113, the concave portion 103a, and the concave portion 103b in the operation unit 110.

Here, the configuration of the operation unit 210 will be described in comparison with each configuration of the operation unit 110 in the first embodiment. The main body 114, the through hole 115a, the through hole 115b, the link pin 112a, and the link pin 112b of the operation unit 110 will be described. And the gripping region 111 respectively include a main body 214, a through-hole 215a, a through-hole 215b, a link pin 212a, a link pin 212b, and a gripping region 211, and the corresponding ones change in shape and structure. Absent.
3) About the claw portion The claw portion 220 is made of a thermoplastic resin material having a good moldability and slidability such as POM, like the claw portion 120 of the latch mechanism 100, and has a trapezoidal shape at the tip as shown in FIG. A main body 221 having a shape is provided, and an inverted L-shaped groove 222 is disposed at the rear end of the main body 221.

Further, it differs from the claw portion 120 in that a protruding boss portion 220a is disposed at the center portion of the direction end surface opposite to the X-axis arrow direction of the main body portion 221.
The boss portion 220a is fitted to the spring 230 in a circumscribed state to fix the spring 230.
Here, the shape of the groove 222 will be described.

As shown in FIG. 7, the groove portion 222 is not composed of only a straight section extending in the Z-axis direction like the claw portion 120 of the first embodiment, but extends in the Z-axis arrow direction. The shape is bent in the direction of the X-axis arrow.
For convenience, a straight section in the Z-axis direction of the groove 222 is referred to as a main section 222b, and a bent section is referred to as a bent section 222c.

The link pin 212a and the link pin 212b enter and slide into the groove portion 222 having the above shape.
2. About Operation FIG. 7 is a diagram showing an initial state of the latch mechanism 200 according to the second embodiment of the present invention, that is, a locked state.

In the locked state, the link pin 212a is located at the lowest position of the main section 222b.
At this time, the link pin 212b (not shown) is also positioned at the lowest position of the main section 222b, and at this time, the main body portion 221 has a positional relationship in which the main body portion 221 protrudes from the end surface of the casing portion 201.
FIG. 8 is a diagram for explaining the movement of the main body 221 when an external force is applied to the grip region 211 of the operation unit 210 in a direction opposite to the X-axis arrow direction from the Z-axis arrow direction to swing the operation unit 210. It shows a state just before the immersion of the main body 221 is completed.

Just before the main body part 221 is completely immersed, the operation part 210 moves upward, and the link pin 212a is positioned at the top of the main section 222b.
At this time, the link pin 212b (not shown) is also positioned at the top of the through hole 222.
Furthermore, the claw portion 220 moves linearly in the X-axis arrow direction side as compared with the position in the initial state, and the main body portion 221 is immersed in the opening portion 201 c provided on the end surface of the casing portion 201.

As described in the first embodiment, the movement in the X-axis arrow direction and the Z-axis arrow direction, which is generated when the link pin 212a swings integrally with the operation unit 210, is shown in FIG. This is because the movement in the Z-axis arrow direction is canceled by the action of the main section 222b extending in the axial direction, and only the movement in the X-axis direction is taken out.
Further, FIG. 9 shows a state when the immersion of the main body portion 221 that instantaneously shifts to the state of FIG. 8 is completed.

In the state where the main body 221 is completely immersed, the position of the operation unit 110 is located at the same position or slightly above the position just before the immersion is completed, and the link pin 112a enters the bending section 222c.
At this time, a link pin 112b (not shown) also enters the bent section 222c.
Further, the claw portion 220 moves slightly in a straight line to the side opposite to the X-axis arrow direction as compared with the position just before the immersion, and the main body portion 221 enters the opening portion 201c provided on the end surface of the casing portion 201. Maintain an immersive state.

This is because the claw portion 220 receives an urging force from the spring 217, and a degree of freedom in the X-axis direction of the claw portion 220 is added in the bent section 222c, so that the repulsive force of the spring 217 contradicts the X-axis arrow direction. It is because it is pushed out in the direction to do.
In this state, the link pin 212a and the link pin 212b are fitted and fixed in the bent section 222c.

That is, even if the external force applied to the grip area 111 is lost, the unlocked state can be maintained.
In order to release this state, the main body portion 221 immersed in the opening 201c is pushed with a fingertip so as to deviate from the link pin 212a and the link pin 212b bent section 222c and enter the main section 222b. The main body 2212 can be protruded from the opening 201c by the reaction force of the spring 217.

Alternatively, by setting the distance of the bending section 222c to be short, the external force is applied in the direction in which the gripping area 211 is pushed down (the direction opposite to the Z-axis arrow direction) to deviate from the bending section 222c of the link pin 212a and the link pin 212b. Thus, the main section 2212 can be protruded from the opening 201c by the reaction force of the spring 217.
3. Summary As described above, the fixed pin 102 that is the swing shaft serves as a fulcrum, the gripping region 211 of the operation unit 210 serves as a power point, and the link pin 212a and the link pin 212b serve as action points, and are pulled up by the user's hand. The force obtained by subtracting the reaction force of the spring from the horizontal component (X-axis component) of the resultant force obtained by multiplying the force by about B / A pulls the claw portion 220.

Similarly to the latch mechanism 100 of the first embodiment, the larger the B / A value, the smaller the force that causes the claw portion 220 to protrude and retract, and accordingly, the set value of the spring constant of the spring 217 is increased to increase the reaction force. Can be set larger, and the pressing force to the concave portion into which the main body portion 221 is fitted can be increased to achieve stronger engagement.
For this reason, even if strong vibration is applied to the electric device, the battery pack engaged with the electric device is not easily detached.
(Modification)
In Embodiment 1 and Embodiment 2, as a mechanism for converting the oscillating motion into the linear motion, a configuration in which a pin is fitted and slid in the groove portion is used. However, the configuration is not limited to this configuration. For example, as shown in FIG. 10, a claw portion 421 having a flat surface portion 421a perpendicular to the sliding direction is arranged, and an operation portion 501 having a cam shape at the tip is fixed so that the cam contacts the flat surface portion 421a. A configuration may be adopted in which the pins 102 are axially attached.

  In addition to this, a mechanism similar to a power transmission mechanism including a crank, a connecting rod, a piston, and a cylinder used for an automobile engine or the like may be incorporated.

  The battery pack according to the present invention can be used for an electric device to which vibration or impact is applied, such as a portable printer, a portable liquid crystal television, a portable DVD player, and an electric bicycle.

It is an external view of the latch mechanism for battery packs in the first embodiment of the present invention. It is an external view of the latch mechanism of the state which removed the casing in Embodiment 1 of this invention. It is an external view only of the operation part in Embodiment 1 of this invention. It is sectional drawing of the latch mechanism in the locked state of Embodiment 1 of this invention. It is sectional drawing of the latch mechanism in the immersion completion state of Embodiment 1 of this invention. It is an external view of the latch mechanism for battery packs of Embodiment 2 of the present invention. It is sectional drawing of the latch mechanism in the locked state of Embodiment 2 of this invention. It is sectional drawing of the latch mechanism just before completion of immersion of Embodiment 2 of this invention. It is sectional drawing of the latch mechanism at the time of completion of immersion of Embodiment 2 of this invention. It is a modification of the latch mechanism for battery packs of embodiment of this invention. 1 is an external view of a battery pack according to Embodiment 1 of the present invention. It is a figure explaining the conventional battery pack.

Explanation of symbols

100 Latch mechanism for battery pack 100 Latch mechanism 100
101 Casing 101
DESCRIPTION OF SYMBOLS 101 Opening part 101a Guide part 101b Guide part 101c Opening part 101s Spring receiving part 102 Fixing pin 103a Recession 103b Recession 110 Operation part 111 Grasping area 112a Link pin 112b Link pin 113 Hole part 114 Body part 115a Through-hole 115b Through-hole 116a Protrusion part 116b Protruding portion 117 Spring 117a End portion 117b End portion 120 Claw portion 121 Main body portion 122 Groove portion 200 Battery pack latch mechanism 201 Casing portion 201a Guide portion 201b Guide portion 201c Opening portion 201d Boss portion 210 Operation portion 211 Grasping area 212 Link pin 212a Link pin 212b Link pin 214 Body portion 215a Through hole 215b Through hole 217 Spring 220 Claw portion 220a Boss portion 221 Body portion 222 Through hole 222 Groove 222c bent section 222b main section 230 spring 421 pawl portion 421a planar portion 501 operating section

Claims (7)

A battery pack comprising: an engaging portion that is mounted and fixed to an electric device and that engages with an engaged portion that is disposed in the electric device; and an operation unit that is operated when releasing the engagement. And
The operation unit is supported to be swingable,
The engaging portion is slidably supported,
The battery pack, wherein the operation part of the operation part and the force point part of the engagement part are connected via a link mechanism. The link mechanism includes a convex portion disposed in the operation portion, a long groove portion disposed in the engagement portion, and a support portion that pivotally supports the operation portion,
The convex part is fitted in the groove part and is slidable along the groove.
The battery pack according to claim 1, wherein the convex portion serves as the action portion, and a contact portion of the groove portion with the convex portion serves as the power point portion. The position in the groove of the convex portion at the time of engagement is a first position,
When the position in the groove of the convex portion at the time of disengagement is the second position,
The groove is bent between the first position and the second position in the groove and in the vicinity of the second position;
From the first position in the groove to the bent position as a first region,
When the second region extends from the bent position to the second position in the groove,
The force that causes the convex portion to enter the second region from the first region is urged by the engaging portion,
The battery pack according to claim 2, wherein the position of the operation unit is fixed by the entry.   The pack according to claim 2, wherein the urging force is a restoring force of an elastic member that abuts on the engagement portion and is disposed at a position toward which the engagement portion is directed when the engagement is released. battery. A fitting portion is disposed on the support portion,
A fitted portion is disposed in the operation portion,
When the engagement is released, the fitting portion and the fitted portion overlap,
3. The battery pack according to claim 2, wherein when the overlap occurs, the fitting portion and the fitted portion are fitted, and the position of the operation portion is fixed. The link mechanism includes a cam attached to the operation portion and swinging integrally with the operation portion, and a flat portion disposed on the engagement portion and contacting the cam.
2. The battery pack according to claim 1, wherein the engagement portion is moved by the cam pressing the flat portion in association with the swinging, and the engagement occurs. 3.   2. The pack according to claim 1, wherein a torsion spring that applies an urging force to the operation unit is wound around the swing shaft of the operation unit so as to swing in a direction in which the engagement occurs. battery.

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