JP2004156439A - Housing box having locking function upon occurrence of earthquake, and earthquake-responsive locking device for use in the housing box - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a housing box which dispenses with unlocking operation thereof by automatically unlocking a locking member 16 without pressing back a wing 5 by a user. <P>SOLUTION: The housing box having a locking function upon occurrence of an earthquake, is constructed in the following manner. The wing 5 is pivoted to an opening 4 of a frame 3 in a manner being openable and energized toward the frame 3. A locking device main body 1 having the locking member 16 is arranged on an opening inner surface 8A of the frame 3, and the locking member 16 assumes an unlocking position A in normal times and moves to a locking position B under vibration conditions. The wing 5 has an engaged member 40 arranged on an inner surface 5A thereof, with which the locking member 16 assuming the locking position B engages, and the locking member 16 is returned to the unlocking position A when the wing 5 is moved in a closing direction. According to the housing box thus constructed, an energizing force F in the wing 5 closing direction is set to a value that can return the locking member 16 to the unlocking position A. <P>COPYRIGHT: (C)2004,JPO

Description

  The present invention relates to a storage box having an earthquake lock function and an earthquake lock device used for the storage box.

For example, in a storage box with a wing represented by furniture such as a cupboard, a bookcase, a closet, a makeup case, and a top bag, a door (wing) is pivotally mounted in a double-opened manner at an opening of a box body having an open front. ing.
In a storage box with a wing represented by the above furniture, a storage device is frequently taken in and out, so that a lock device is generally rarely provided, and even if a lock device is provided, a user does not use the lock device much. Many.

For this reason, as can be seen from the experience of the Great Hanshin Earthquake, when the storage box was greatly shaken by the earthquake of great seismic intensity, the closed door opened due to the shaking, and the stored items such as tableware jumped out. This may result in damage to the stored articles or injury to the occupants.
Therefore, a wing is pivotally attached to the opening of the frame so as to be openable and closable, and a lock device main body having a lock member which is always in the unlock position and moves to the lock position by vibration is provided on the inner surface of the opening of the frame. A lock member is provided on the inner surface of the lock member to be locked by the lock member at the lock position, and the lock member returns to the unlock position as the wing moves in the closing direction. A storage box having a function has already been proposed (for example, see JP-A-8-199886 and JP-A-9-287338).

  According to this, the lock member returns to the unlock position with the movement of the wing in the closing direction, so that the user can strongly release the wing in the closing direction to release the lock by the lock member.

  In the above conventional technology, for example, even when the wing is locked by an unexpected vibration other than an earthquake, in order to release the lock by the lock member, it is necessary to push the wing back in the closing direction once, and suddenly, Pulling the wing will not open the wing.

Therefore, if the user misunderstands that the wing is not locked and tries to open it by pulling the wing forward, excessive force is applied to the locking member and the locking member, and the locking device at the time of the earthquake will fail early. May cause
In addition, the fact that the lock can be released simply by pushing the wing back in the closing direction can be said to be an easy unlocking operation.However, even if the wing is locked unexpectedly, it is necessary for the user to push the wing back every time. It takes quite a lot of work.

  In view of such circumstances, the present invention makes it possible to automatically release the lock by the lock member even if the user does not push back the wing, thereby eliminating the trouble of releasing the lock, and enabling the locking device in the event of an earthquake. It is an object of the present invention to effectively prevent a failure from occurring.

In order to achieve the above object, the present invention has taken the following technical measures.
That is, the storage box according to the present invention is a storage box having an earthquake locking function in which the lock member returns to the unlock position with the movement of the wing in the closing direction. The urging force is set to a size that can return the lock member to the unlock position.

  In this case, the wing is always urged in the closing direction (frame side) and the urging force is set to a size that can return the lock member to the unlocked position. Even if the wing is locked by the vibration of the wing, the wing returns in the closing direction by the urging force, and the locking member is returned to the unlock position with this return.

Therefore, according to the present invention, the lock by the lock member can be automatically released without the user pushing back the wing.
More specifically, the lock member is movable back and forth in a direction intersecting the moving direction of the wing and is urged toward the lock position, and the lock member is moved in the closing direction with the movement of the latched member. In the case of a storage box of a type provided with a cam mechanism for moving to the unlock position, the urging force F in the closing direction of the wing is f, the urging force of the lock member is f, and the inclination angle of the cam mechanism is θ. May be set to F> 2fsin−12θ.

  Further, the locking device main body includes a casing having a concave curved surface formed therein and having a riding portion following the concave curved surface, and the lock member includes a rolling member rotatably provided on the concave curved surface. In the case of a storage box of a type in which the rolling member is in a locked position when the rolling member rides on the riding portion, and the latched member is formed in a shape to be hooked on the rolling member riding on the riding portion. May be set such that the biasing force of the wing is set to a value larger than the inertial force of the rolling member.

  In addition, the locking device for an earthquake according to the present invention includes a lock device main body attached to an inner surface of an opening of a frame or an inner surface of a wing pivotally attached to the opening in a state of being biased toward the frame, and a lock device that is normally unlocked. A lock member provided at the lock device main body at the lock position so as to be in the lock position by vibration, and a hook provided at the other of the two inner surfaces to be hooked to the lock member at the lock position. A locking member provided on the locking device main body so as to return to an unlocked position by a biasing force in a closing direction of the wing.

  In this case, the wing is always urged in the closing direction (frame side), and the urging force of the wing returns the lock member to the unlocked position. Even when the wing is locked, the wing returns to the closing direction due to the urging force, and the locking member is returned to the unlock position with this return.

Therefore, according to the present invention, the lock by the lock member can be automatically released without the user pushing back the wing.
More specifically, the lock member is movable back and forth in a direction intersecting with the moving direction of the wing and is urged toward the lock position, and the lock member is moved along with the movement of the latched member in the closing direction. In the case of a seismic locking device provided with a cam mechanism for moving to an unlock position, the urging force f of the locking member is F, the urging force in the closing direction of the wing is F, and the inclination of the cam mechanism is F. Assuming that the angle is θ, f <Fsin θcos θ may be set.

  Further, the locking device main body includes a casing having a concave curved surface formed therein and having a riding portion following the concave curved surface, and the lock member includes a rolling member rotatably provided on the concave curved surface. The rolling member is in a locked position when the rolling member rides on the riding portion, and the latched member is formed in a shape to be hooked on the rolling member riding on the riding portion. In this case, the inertial force of the rolling member may be set to a value smaller than the urging force of the wing.

  As described above, according to the present invention, the lock by the lock member can be automatically released without the user having to push back the wing, so that the wing is not required to be unlocked, so that the wing is much easier to use than before. The storage box can be obtained, and the failure of the locking device in the event of an earthquake due to the user pulling the wing by mistake when the wing is locked can be prevented.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 to 9 show a first embodiment of the present invention.
FIG. 2 shows a storage box 2 having a locking function during an earthquake according to the present invention. The storage box 2 includes a cupboard, a bookshelf, a closet, a makeup case, a kitchen top bag, and other pivotable doors. A box body (frame) 3 assembled from left and right side plates 3A, a top plate 8 and a bottom plate 9 in a rectangular frame shape, and an opening 4 in the front opening 4 of the box body 3. And a pair of left and right doors (wings) 5 for opening and closing the door.

In the illustrated example, a rubber sealing member 3B is provided at the upper and lower opening edges of the box body 3 to abut against the inner surface of the door 5 to seal the door 5, but this sealing member 3B is omitted. You can also.
The pair of left and right doors 5 has a width-direction outer edge pivotally attached to a side plate 3A of the box body 3 via a hinge 6 with a spring, and is of a so-called double-opening type which is rotatable inward and outward of the storage box 2. . The hinge 6 incorporates a winding spring that urges the door 5 toward the opening 4 side of the box body 3, and the door 5 is constantly urged in the closing direction by this winding spring.

  As the hinge 6 for urging the door 5 in the closing direction, not only the spring type but also a cam type that moves the door 5 in the closing direction by the weight of the door 5 can be used. A well-known magnet catch is attached to the inner surface of the opening of the box body 3, and the magnetic force of the magnet catch attracts the metal plate provided on the inner surface of the door 5 to urge the door 5 toward the box body 3. You can also.

  A pair of locking device bodies 1 of a locking device during an earthquake that automatically prevents the pair of left and right doors 5 from opening due to shaking such as an earthquake are attached to the top plate 8 of the box body 3 in correspondence with the pair of left and right doors 5. Has been. The locking device at the time of earthquake mainly comprises a locking device body 1 attached to the box body 3 side and a bracket (latched member) 40 described later attached to the door 5 side.

  As shown in FIG. 1, the lock device main body 1 includes a synthetic resin casing 15 attached to the lower surface of the front edge of the top plate 8 (the inner surface of the opening of the box main body 3) 8 </ b> A. A lock member 16 including a releasably inserted latch bolt, a first coil spring 17 that constantly urges the lock member 16 upward, a holding member 18 that holds the lock member 16 in the casing 15 in advance, An inertia member 19 for detecting the shaking of the box body 3 due to an earthquake or the like and releasing the holding member 18 from the lock member 16.

  As shown in FIGS. 1 and 3, the casing 15 includes a case body 20 that is screwed to the lower surface 8 </ b> A of the top plate 8, an upper surface side of which is opened, and a lid member 22 that closes the upper surface opening of the case body 20. At the front end of the case main body 20, a guide cylinder 21 having a bottomed tubular shape and opened upward for guiding the lock member 16 so as to be able to move back and forth is formed.

In the present embodiment, the casing 15 is arranged so that the moving direction of the holding member 18 and the inertia member 19 coincides with the opening / closing direction of the door 5 (the left-right direction in FIG. 1). The direction in which the door 5 is closed (the right side in FIG. 1) is defined as the front, and the direction in which the door 5 is closed (the left side in FIG. 1) is defined as the rear.
As shown in FIG. 1, the casing 15 is provided via a spacer portion 23 protruding from the lid member 22 such that the lock member 16 in the guide tube portion 21 is separated from the lower surface 8A of the top plate 8 at an appropriate interval. The lower surface 8A of the top plate 8 is screwed to form an insertion space 24 for the bracket 40 formed between the top plate 8 and the casing 15. The lock member 16 is inserted through the guide tube portion 21 so as to be vertically movable.

  As shown in FIGS. 3 and 5, the lid member 22 is a rectangular plate-shaped lid body 25 that closes an upper surface opening of the case body 20, and the lid body 25 is integrally formed on a rear end upper surface side of the lid body 25. It has a spacer portion 23 and a guide piece 26 integrally formed on the lower surface side of the front end portion of the lid main body 25. The lid member 22 is fixed to the case main body 20 by mounting screws (not shown) inserted into first screw holes 27 provided in the front left and right sides of the lid main body 25 and the center of the spacer portion 23.

An insertion hole 25A for the lock member 16 is formed in the center of the front end of the lid main body 25. On the left and right sides of the lower surface of the lid main body 25, the positioning holes 28 provided in the case main body 20 are fitted. A positioning pin 29 for positioning with respect to the projection is protruded (see FIG. 5).
As shown in FIG. 5, the guide piece 26 projects downward from the center of the lower surface of the lid member 22, and fits into the front part of the storage part 45 formed at the center of the case body 20 in the width direction. At this time, the front portion of the holding member 18 is guided in the front-rear direction (the left-right direction in FIG. 1).

That is, a guide groove 31 that opens downward and extends in the front-rear direction is formed in the center of the guide piece 26. By inserting the front portion of the plate-shaped holding member 18 into the guide groove 31, 18 is guided in the front-back direction.
Further, second screw holes 32 are formed at both left and right ends of the spacer portion 23 and the case body 20, and mounting screws inserted upward into the second screw holes 32 are directed toward the lower surface 8 </ b> A of the top plate 8. By screwing, the casing 15 is fixed to the top plate 8 via the spacer portion 23 of the lid member 22 that closes the casing.

As shown in FIGS. 1 and 3, the lock member 16 is formed in a prismatic shape having a length substantially equal to the inner space length of the guide tube portion 21, and has a bottomed spring storage hole 34 extending from the lower end to the center. The first coil spring 17 housed in the spring housing hole 34 is inserted into the guide cylinder 21.
At this time, the lower end of the first coil spring 17 is fitted over the connecting pin 36 erected on the bottom wall 35 of the guide cylinder 21, and is housed in the spring housing hole 34 in a compressed state. For this reason, the lock member 16 is constantly urged by the first coil spring 17 to the upper lock position B side.

A pair of left and right stoppers 37 protrude from a lower portion of the side surface of the lock member 16, and a vertical guide groove 38 is formed between the stoppers 37. The stopper 37 restricts the lock member 16 from coming out upward by contacting a step 26A (see FIG. 5) formed at the front end of the guide piece 26.
On the other hand, on the inner surface 5 </ b> A of the door 5, a bracket (latched member) 40 that is locked by the lock member 16 protruding to the lock position B and restricts the opening of the door 5 is fixed by a mounting screw 41.

  The bracket 40 is formed in a substantially L-shape in a side view from a mounting plate 42 and a hooked plate 43 orthogonal to the mounting plate 42. The hooked plate 43 is provided with a relief portion 44 formed by bending a portion from the middle part to the front end upward, and has a lock position B at the front end (end on the storage box 3 side). The locking claw 16 is provided with a hook 44 </ b> A that hooks on the protruding end of the moved lock member 16.

  The bracket 40 is attached such that the hooked plate 43 projects rearward from the inner surface 5A by screwing the mounting plate 42 to the inner surface 5A of the door 5 with the mounting screw 41. In the closed state of the door 5, the latched plate 43 is located at the same plane position as the retracted position of the lock member 16, and at a height position where it enters the insertion space 24.

  For this reason, when the lock member 16 is housed in the guide tube portion 21 (the phantom line in FIG. 1), the lock member 16 does not lock the bracket 40 and the unlock position A where the door 5 can be opened. Become. On the other hand, when the lock member 16 protrudes upward (solid line in FIG. 1), the upper part of the lock member 16 enters the escape portion 44 of the bracket 40 fixed to the door 5, and the opening of the door 5 is prevented. The lock position B is reached.

The case body 20 of the casing 15 is formed with a storage portion 45 extending in the front-rear direction (the opening / closing direction of the door 5, the same as the left-right direction in FIG. 1) so as to intersect with the retracting direction of the lock member 16. The holding member 18 is inserted into the center of the storage section 45 in the left-right direction while being guided so as to be movable in the front-rear direction.
That is, the holding member 18 of the present embodiment is formed of a metal slide plate formed in a substantially rectangular plate shape, and a pair of left and right guide plates 46, which are erected in the center of the bottom surface of the storage unit 45 and are long in the front-rear direction, By being fitted vertically between 46, it is guided movably in the front-rear direction in the storage section 45.

As shown in FIG. 1, a rolling member 19A described later is placed on a guide ridge 47 formed by the upper edges of the guide plates 46, 46, so that the rolling friction resistance of the member 19A can be maximized. It is designed to be smaller in size.
As shown in FIG. 3, the plate-like holding member 18 has a hook piece (hook portion) 49 at a front end portion that fits into a hook recess 48 formed on a side surface of the lock member 16. Is provided at the rear end portion for connecting a second coil spring 50 that biases the second coil spring 50 toward the lock member 16 side.

In the center of the holding member 18, a notch 52 is formed, which is largely open upward, and a notch 52 is formed on the upper edge of the retaining piece 49 of the holding member 18 along with the downward movement of the lock member 16. In order to push back the holding member 18 rearward, a tapered portion 49A having a downwardly inclined shape is formed.
The second coil spring 50 to which the connecting piece 51 of the holding member 18 is fitted and fitted is housed between opposed walls 50A (see FIGS. 3 and 4) erected at the rear part of the housing part 45. The holding member 18 is constantly biased forward by contacting the rear wall surface. The latching piece 49 of the holding member 18 is forcibly fitted into the latching recess 48 of the lock member 16 by the urging force of the coil spring 50, whereby the lock member 16 can be held in the unlock position A in advance. it can.

The lock device main body 1 of the present embodiment further moves in any of a rearward direction (left side in FIG. 1) where the inertia member 19 is separated from the lock member 16 and a forward direction (right side in FIG. 1) approaching the lock member 16. In any case, a release means 71 for releasing the holding member 18 from the lock member 15 is provided.
The release means 71 includes a first release portion 72 disposed at the rear end of the holding member 18 so that the inertia member 19 moving rearward collides with the holding member 18 so that the inertia member 19 moving forwardly collides. And a second release portion 73 arranged at the front end.

Among these, the first release part 72 in the present embodiment is composed of a release piece 72A integrally formed at the rear end of the holding member 18, and the second release part 73 is provided separately from the holding member 18. It consists of a plate (release member) 73A.
That is, the first release portion 72 is formed directly on the holding member 18 by the release piece 72 </ b> A which is the rear end portion of the holding member 18 and the edge on the side of the relief recess 52, and the inertia moved rearward in the relief recess 52. When the member 19 collides with the release piece 72A, the holding member 18 moves rearward.

On the other hand, the release plate 73A constituting the second release portion 73 is for moving the holding member 18 rearward by the inertial force thereof even when the inertia member 19 in the escape recess 52 moves forward. It is made of a steel plate that is provided in the casing 15 so as to be able to swing back and forth so as to be separated from 18.
As shown in FIG. 3, the release plate 73 </ b> A is formed by slightly bending a steel plate material into a V-shape at the center in the vertical direction, so that the upper half collision plate portion 74 and the lower half swing plate portion 75 are formed. It has. The inner wall portion 76 of the storage portion 45 of the case body 20 is formed with a tapered groove 77 that gradually becomes wider as it goes upward, and the left and right side edges of the swinging plate portion 75 are formed on the tapered groove 77. Are fitted from

The guide plates 46, 46 in the storage portion 45 are provided with escape openings 78 for preventing interference between the guide plates 46, 46 and the release plate 73A (see FIGS. 1 and 4).
At the lower end of the swinging plate portion 75 of the release plate 73A, a reaction piece 79 protrudes downward. The reaction piece 79 is formed in an engagement groove formed on the front side of the escape recess 52 of the holding member 18. 80.

Therefore, when the inertia member 19 moves forward along with the swing of the box body 3, the plate 73A collides with the collision plate portion 74 of the release plate 73A and swings, and at the same time, the reaction piece 79 of the release plate 73A moves. The holding member 18 is moved rearward to move the holding member 18 rearward, whereby the holding member 18 is released from the lock member 16.
In addition, since the center portion of the release plate 73A is bent so that the collision plate portion 74 is slightly inclined to the side opposite to the lock member 16, the collision plate portion 74 is closer to the inertia member 19 as compared with the case where there is no bending. Will be. Accordingly, the release plate 73A operates only by slightly moving the inertia member 19 forward, and therefore, the detection sensitivity of vibration is improved as compared with the case where the bending is not performed.

  Further, as the release member 73A that performs the above operation, not only a plate-shaped member (release plate) wide in the width direction of the casing 15 but also an arm-shaped member having an intermediate portion pivotally attached to the case body 20 side is used. You can also. That is, the release member 73A only needs to be a member having a link function capable of converting the forward movement of the inertia member 19 into the backward movement of the holding member 18, and the shape thereof is not particularly limited.

  In the present embodiment, the inertia member 19 is formed of a rolling member 19A made of a metal ball, is housed in the housing part 45 together with the plate-shaped holding member 18, and the first release part in the escape recess 52 of the holding member 18. It is provided between the second release portion 73 and the second release portion 73 (release plate 73A) so as to freely roll in the front-rear direction. In addition, as the rolling member 19A, a short-axis-shaped roller may be employed in addition to the ball.

The rolling member 19 </ b> A causes the holding member 18 guided between the guide plates 46, 46 in the storage portion 45 to move the holding member 18 due to shaking during an earthquake (for example, shaking with a seismic intensity of about 2 to 3). The weight is designed to generate an inertial force (collision force) sufficient to push the ball backward against the elastic force of 50.
As a material of the rolling member 19A, it is preferable to employ, for example, brass as a metal which does not easily generate rust and which can surely roll with good sensitivity by shaking due to an earthquake or the like and can maintain the sensitivity for a long time. Alternatively, the outer periphery of a steel material may be covered with a resin. Also, a resin in which a metal having a high specific gravity such as lead is buried in a resin can be adopted.

  The bottom edge 52A of the escape concave portion 52 of the holding member 18 is formed to have a height such that the middle part of the holding member 18 fits between the guide plates 46, 46 so as to be lower than the upper end surface of the guide ridge 47. As a result, the rolling member 19A rolls in the escape recess 52 without contacting the holding member 18, so that the rolling resistance is reduced and the operation sensitivity during an earthquake is improved.

The rolling member 19A reciprocates back and forth in the storage part 45 by the shaking of the box body 3, but when the shaking is large due to an earthquake or the like, the inertial force due to the rolling is large. And collides with the first release portion 72 or the second release portion 73 of the holding member 18.
Due to this collision, the holding member 18 urged toward the locking member 16 by the second coil spring 50 is displaced rearward (to the left in FIG. 1), and the locking piece 49 of the holding member 18 is shifted to the locking recess of the locking member 16. After that, the lock member 16 is projected upward by the first coil spring 17 to be in the lock position B.

  On the other hand, in the present embodiment, a recessed portion 81 is provided at the protruding end of the lock member 16 to ensure that the bracket 40 is hooked on the hooking claw 44A. As shown in FIG. 1 and FIG. 3, the recessed portion 81 is formed by carving the rear surface of the protruding end of the bracket 16 shallowly over a certain range in the vertical direction. For this reason, the hooking claw 44A of the bracket 40 is hooked on the protruding end of the lock member 16 in a state of having entered the recess 81 (see FIG. 1).

As shown in FIG. 3, a metal reinforcing plate 82 is embedded inside the lock member 16, and an edge of the reinforcing plate 82 constitutes a lower edge of the latching recess 48, so that The lower edge of the retaining recess 48 is prevented from being worn out early due to contact with the retaining portion 49 of the holding member 18.
On the other hand, as shown in FIG. 1, the hooked plate 43 of the bracket 40 is provided with a relief portion 44 formed by bending a portion from a tip end portion to an intermediate portion upward. The escape portion 44 is formed so as to be located slightly behind the lock member 16 (inside the box body 3) when the door 5 is completely closed. At this time, the proximal end of the escape portion 44 is bent. The part is located just on the rear side surface of the lock member 16.

Therefore, the lock member 16 can project to the lock position B when the escape portion 44 comes directly above the lock member 16 as shown in FIG. Then, the lock member 16 protruding from the escape portion 44 catches the hook 44A of the bracket 40 at the protruding end thereof, and regulates the movement of the wing 5 in the opening direction.
As shown in FIG. 1, the lock device main body 1 of the present embodiment is configured such that the door 5 further moves in the closing direction from the state in which the lock member 16 is engaged with the bracket 40 (the state in FIG. 1). And a lock release mechanism 63 for pushing the lock member 16 back to the unlock position A.

In the present embodiment, as the lock release mechanism 63, the halfway portion of the bracket 40 moving in the closing direction of the door 5 in the same direction directly contacts the protruding end of the lock member 16 so that the lock member 16 is retracted. A cam mechanism 63A including first and second cam portions 61 and 62 formed in a shape of being pushed back downward.
The first cam portion 61 is formed of a spring member 54 formed to be inclined forward and downward at an intermediate portion of the hooked plate 43 of the bracket 40. The spring member 54 is formed at an intermediate position in the opening and closing direction of the door 5 of the bracket 40 so as to be inclined toward the projecting side of the bolt 16 as approaching the lock member 16 side (the storage box 3 side).

On the other hand, the second cam portion 62 is formed at the protruding end of the lock member 16 and is formed so as to be inclined toward the immersion side of the lock member 16 toward the bracket 40 (outside the box 3).
For this reason, when the door 5 moves in the closing direction from the state where the lock member 16 protruding to the lock position B is engaged with the escape portion 44, the cam portions 61 and 62 abut against each other to move the lock member 16 to the unlock position A. To push back. In other words, when the door 5 further moves in the closing direction from the state where the lock member 16 is engaged with the bracket 40 (the state where the protruding end of the lock member 16 enters the escape portion 44), the first cam of the bracket 40 is moved. The portion 61 comes into contact with the second cam portion 62 of the lock member 16, and the lock member 16 is pushed back to the unlock position A.

As shown in FIG. 6, the spring member 54 includes a fixed plate portion 55 fixed to the inner surface of the mounting plate 42 of the bracket 40, and a contact plate portion 56 extending rearward from an upper edge of the fixed plate portion 55. And a leaf spring having the following. The spring member 54 may employ not only a leaf spring but also a rod-shaped spring.
The contact plate portion 56 has a substantially U-shape in a side view by bending the middle portion downward, and the portion from the bent portion to the front end is formed to be inclined forward and downward, so that the locking member 16 A contact portion 57 (first cam portion 61) for the protruding end is provided. The contact portion 57 is inclined at substantially the same angle as the second cam portion 62 of the lock member bolt 16 in a state where the contact portion 57 enters the escape portion 44 of the bracket 40, and is longer than the second cam portion 62. It has an interface.

As shown in FIGS. 1 and 6, at the center in the width direction of the hooked plate 43 of the bracket 40, the interference between the upwardly elastically deformed contact plate portion 56 and the hooked plate 43 is avoided. Relief hole 58 is provided.
On the other hand, a third cam portion 64 bent downward and forward is provided at the distal end portion of the hooked plate 43 of the bracket 40.

  The third cam portion 64 can also be moved by moving the fully opened door 5 in the closing direction so that all the portions of the bracket 40 are located outside the storage box 3, and the third cam portion 64 can be moved to the lock position B. The lock member 16 and the bracket 40 interfere with each other when the lock member 16 projects to the lock position B in a state where the door 5 is largely opened completely. 5 can be prevented from closing.

  That is, when the lock member 16 projects to the unlock position A in a state where the door 5 is largely opened completely (the state of FIG. 7C), when the door 5 moves in the closing direction from this state, the second cam portion 62 and the third cam portion 64 are pressed against each other to press the lock member 16 toward the unlock position A, whereby the distal end of the bracket 40 can pass over the lock member 16, so that the lock member 16 is moved to the lock position. The door 5 in the fully open state can be easily closed even when the door is in the position B, and the door 5 can be smoothly closed.

  In the present embodiment, the urging force F of the hinge 6 with spring in the closing direction of the door 5 is set to a magnitude that can return the lock member 16 to the unlock position A. That is, the urging force of the spring-loaded hinge 6 in the closing direction of the door 5 is F, the urging force of the lock member 16 by the first coil spring 17 is f, and the inclination angle of the second cam portion 62 of the cam mechanism 63A with respect to the vertical direction. Is assumed to be θ, the relationship between the two urging forces F and f is set so that the following equation (1) is established, whereby the lock member 16 can be moved to the unlock position without pushing the door 5 back by hand. You can return to A.

(1) F> 2fsin ^-1 2θ
Hereinafter, the basis of the above equation (1) will be described with reference to FIG.
FIG. 9 shows the state of action of the force when the first cam portion 61 (the contact portion 57 of the spring member 54) constituting the cam mechanism 63 </ b> A contacts the second cam portion 62 of the lock member 16.

In this case, the urging force F by the hinge 6 of the door 5 acts as a horizontal force exerted by the first cam portion 61 on the second cam portion 62, as shown in FIG. A component force F1 along the direction 62 and a component force F2 perpendicular to the cam portion 62 are dispersed, and their magnitudes are F1 = Fsin θ and F2 = Fcos θ, respectively.
Assuming that the component force of F2 in the vertical direction below F2 is F3, the component force F3 is greater than the biasing force f of the first coil spring 17 if the component force F3 is greater than the biasing force f of the first coil spring 17. Overcoming this, the lock member 16 can be pushed back downward.

  Then, since this component force F3 can be calculated as F3 = F2 sin θ = F sin θ cos θ, if F sin θ cos θ = (１ ／) F sin 2θ> f, the lock member 16 can be pushed back downward. Therefore, if the urging force F of the door 5 is set so that F> 2fsin-12θ, the locking member 16 can be pushed back by the urging force F.

  According to the seismic locking device according to the above structure, when the lock member 16 is immersed in the unlock position A, the locking piece 49 of the holding member 18 passes through the tapered portion 49A and fits into the locking recess 48. Thus, the lock member 16 is held at the unlock position A. For this reason, the lock member 16 is always held at the unlock position A in a normal case where no large swing occurs in the box body 3, and in this case, the door 5 can be freely opened and closed.

On the other hand, when the shaking greater than the seismic intensity assumed in the box body 3 occurs, the holding by the locking piece 49 is released by the impact force when the rolling member 19A collides with the first release portion 72 or the second release portion 73. You.
Therefore, as shown in FIG. 1, when the engaging recess 44 of the bracket 40 comes directly above the lock member 16, the lock member 16 automatically moves to the lock position B, and the protruding end of the lock member 16. Locks the hook 40 </ b> A of the bracket 40 to prevent the door 5 from being opened. As a result, the stored items such as tableware in the storage box 2 are prevented from jumping out.

  On the other hand, since the door 5 is urged in the closing direction, the lock member 16 automatically moves in the closing direction from the state in which the lock member 16 is engaged with the bracket 40. Since the urging force F of the door 5 is set in the relationship of the above-described formula (1), the first cam portion 61 of the bracket 40 is moved to the second cam portion 62 at the upper end of the lock member 16 by the urging force F. Then, the member 16 is pushed back to the unlock position A, and then the holding member 18 holds the lock member 16 at the unlock position A, whereby the lock by the lock member 16 is automatically released.

  As described above, in the present embodiment, the locking member 16 is automatically returned to the unlock position A by the urging force F of the door 5, so that even if the door 5 is locked suddenly due to a minute vibration or the like other than the earthquake, The door 5 is always returned to the closed position by the urging force F, and the lock of the lock member 16 is released. Therefore, the lock of the lock member 16 can be automatically released without the user having to push the door 5 back.

  In the present embodiment, the first release portion 72 and the second release portion 73 are provided regardless of whether the inertia member 19 moves in the backward direction away from the lock member 16 or in the forward direction approaching the same member 16. Since the release means 71 releases the holding member 18 from the lock member 16, the lock member 16 can be instantaneously protruded to the lock position regardless of the initial swing generated in the box body 3 in any of the front and rear directions. It is possible to prevent a difference in the detection sensitivity of the vibration depending on the direction of the vibration.

  Further, in the present embodiment, since the door 5 returns to the closing direction by the urging force F of the hinge 6, the lock member 16 is always returned to the unlocked state. Therefore, the door 5 is once locked by an unexpected vibration other than the earthquake. Also in this case, the lock by the lock member 16 is automatically released, and then the door 5 can be opened even if the door 5 is immediately pulled. Therefore, when the door 5 is opened, an excessive force is applied to the lock member 16 and the bracket 40, so that it is possible to prevent the locking device at the time of the earthquake from failing early.

Further, since the lock can be automatically released without pushing back the door 5, even if the sensitivity of the lock device main body 1 for detecting the swing is increased, the use of the storage box 2 is not inconvenient. The sensitivity of the main body 1 for detecting the shaking can be made extremely sharp.
Next, with reference to FIGS. 7 and 8, the operation of the earthquake locking device will be described in more detail.

First, as shown in FIG. 7A, when the lock member 16 is held at the unlock position A, both the latched plate 43 and the spring member 54 of the bracket 40 are inserted through the lock device body 1 side. The space 24 can be freely moved back and forth, and in this case, the door 5 can be freely opened and closed.
On the other hand, when the shaking of the box main body 3 is larger than the assumed seismic intensity, the holding by the locking piece 49 is released by the impact force when the rolling member 19A collides with the releasing portions 72 and 73 of the holding member 18. For this reason, as shown in FIG. 7B, when the escape portion 44 of the bracket 40 comes directly above the lock member 16, the lock member 16 automatically moves to the lock position B, and the lock member 16 projects. The end is hooked on the hook 44 </ b> A of the bracket 40, and the opening of the door 5 is prevented.

  At this time, in the present embodiment, since the hooks 44A of the bracket 40 are engaged in a state where the hooks 44A are inserted into the recessed portions 81 of the lock member 16, the lock member 16 is closed by the play of the casing 15 with respect to the guide tube portion 21 or the like. Even if it falls slightly in the opening direction of the door 5, it is possible to prevent the hook 43 </ b> A of the bracket 40 from coming off in the opening direction of the door 5.

Then, even if an earthquake accompanied by back-and-forth shaking strikes many times in a short time, the door 5 is completely opened only by repeating the state of FIG. 7A and the state of FIG. 7B. Never.
Thereafter, when the earthquake subsides, the door 5 moves in the closing direction by the urging force F of the hinge 6 and returns to the state shown in FIG. 7A. At this time, the first cam portion 61 (spring member 54) of the bracket 40 is The member 16 comes into contact with the second cam portion 62 at the upper end of the lock member 16 and is pushed back to the unlock position A.

Therefore, after that, the holding member 18 holds the lock member 16 at the unlock position A, and the lock by the lock member 16 is automatically released.
In the present embodiment, since the spring member 54 that is elastically deformable in the up-down direction is employed as the first cam portion 61, as shown in FIG. 7B and FIGS. Even if the mounting height of the bracket 40 slightly changes due to backlash, mounting error of the bracket 40, or the like, the first cam portion 62 surely contacts the protruding end portion (second cam portion 62) of the lock member 16. Therefore, the lock release mechanism 63 including the cam mechanism 63A can be operated more reliably.

  On the other hand, as shown in FIG. 7C, even when the lock member 16 is protruding in a state where the door 5 is completely opened, if the door 5 moves in the closing direction by the urging force F of the hinge 6, Since the third cam portion 64 formed at the tip of the bracket 40 pushes down the second cam portion 62 of the lock member 16, the door 5 can be easily closed without pushing the lock member 16 back with a finger.

  In the above embodiment, when a band-shaped mating member for closing the gap between the two doors 5 is fixed to the edge of one of the left and right doors 5, the other door 5 is connected to the other door 5. If the door 5 is not opened, one of the doors 5 cannot be opened. Therefore, it is sufficient to provide the bracket 40 only on the other door 5 and provide one lock device main body 1 on the box main body 3 for automatically locking the same.

However, when the joining member is pivotally attached to one of the doors 5, brackets 40 are provided on the left and right doors 5 as in a second embodiment described later, and these brackets 40 are provided. It is necessary to provide the lock device main body 1 at each position of the box main body 3 corresponding to.
Further, in the case of the storage box 2 having the one-sided door 5, the lock device main body 1 can be attached to the vertical side surface of the box main body 3.

In the first embodiment, as shown in FIG. 3, a rounded round portion 18R is formed at the lower part of the front and rear ends of the holding member 18, so that the holding member 18 slides back and forth. This also improves the sensitivity of vibration detection.
Further, in the first embodiment, the cam portion 61 is provided only on the bracket 40, and the lock member 16 in which the bracket 40 is in the lock position B is moved to the unlock position A by the movement of the wing 5 in the closing direction only with the cam portion 61. May be pressed.

Further, a cam portion 62 is provided only on the lock member 16, and the lock member 16 at the lock position B is pressed by the bracket 40 to the unlock position A by the movement of the wing 5 in the closing direction only by the cam portion 62. You may.
That is, the cam mechanism 63A can be configured not only with the first and second cam portions 61 and 62 but also with only one of them.

Further, the first cam portion 61 may be provided directly on the bracket 40 by bending the inclined portion 40A (see FIG. 8A) on the hooked plate 43 of the bracket 40 instead of the spring member 54. it can.
On the other hand, in the first embodiment, the inertia member 19 that detects the swing and releases the holding member 18 from the lock member 16 is configured by a roller-shaped or ball-shaped rolling member 19A. The inertia member 19 may be configured by a weight member that slides with respect to the holding member 18 (for example, see Japanese Patent Application No. 7-134376).

FIG. 10 shows a second embodiment of the present invention.
The lock device main body 1 according to this embodiment is configured by housing a metal plate-shaped lock member 16 on an inclined surface 90 that is formed inside the casing 15 and that is inclined rearward and downward.
The lock member 16 has a U-shaped hook portion 41 at the distal end, and an opening 92 for projecting the hook portion 41 downward is formed in a lower front portion of the casing 15. At the rear upper part of the casing 15, a pressing pin 93 is provided, with which the rear end of the lock member 16 contacts, and the pressing pin 93 is urged downward by a coil spring 94. The bracket 40 fixed to the inner surface 5A of the door 5 has a recess 95 into which the hook 91 is fitted.

  In this embodiment, when the box body 3 shakes due to an earthquake or the like, the hook 91 of the lock member 16 jumps out of the opening hole 92 and is fitted into the recess 95 of the bracket 40 in a state in which the hook 91 contacts the front wall 96 of the casing 15. Accordingly, the opening of the door 5 is prevented. At this time, the rear end of the lock member 16 is in contact with the pressing pin 93, and the pressing pin 93 urges the lock member 16 to a protruding state (lock position B).

  A magnet catch 97 is buried in the upper part of the front surface of the casing 15, and an iron suction plate 98 to be sucked to the catch 97 is fixed to a corresponding portion of the catch 97 on the inner surface 5 </ b> A of the door 5. However, in the present embodiment, the door 5 is always urged in the closing direction (the right side in FIG. 10) by the magnetic force of the magnet catch 97, and the hinge 6 itself does not have the urging force of the door 5.

However, in all the embodiments described in this specification, the urging of the door 5 in the closing direction may be performed by using the hinge 6 itself or by using the attraction force of the magnet catch 97, Also, both of these may be adopted.
Also in this embodiment, since the rear end of the lock member 16 is in contact with the cam surface (cam mechanism 63A) of the pressing pin 93, the urging force F in the closing direction of the door 5 and the coil spring of the pressing pin 93 The urging force f of the lock member 16 by 94 is set such that the relationship of the above-described formula (1) is established, as in the case of the first embodiment.

Therefore, also in the present embodiment, when the earthquake stops, the door 5 returns to the closing direction by the attraction force (biasing force F) of the magnet catch 97, and the return of the door 5 causes the lock member 16 to unlock the inside of the casing 15. It will be automatically returned to the lock position A.
FIG. 11 shows a third embodiment of the present invention.

  As shown in FIG. 11A, in the lock device main body 1 of the present embodiment, the inner bottom surface of the casing 15 is formed in the concave curved surface 100, and the riding portion 101 is formed around the concave curved surface 100. . The lock member 16 is composed of a ball-shaped rolling member 102 provided on the concave curved surface 100 so as to freely roll, and the rolling member 102 is located at the deepest central portion of the concave curved surface 100 (Normally when there is no vibration). Although it is stationary at the unlock position A), when a shaking such as an earthquake occurs, it rides on the riding section 101 to be in the lock position A.

  A slit 103 for receiving the bracket 40 into the casing 15 is formed at a front portion of the casing 15, and a retaining portion 104 of the rolling member 102 is formed below the slit 103. As shown in FIG. 11B, the bracket 40 is made of a metal plate bent substantially in an L-shape, and has a locking hole portion 105 in which the rolling member 102 enters at a central portion.

  In the present embodiment, the bracket 40 can freely move back and forth in the casing 15 through the slit 103 during normal times without vibration, and the door 5 can be freely opened and closed. On the other hand, when the box body 3 shakes due to an earthquake or the like, the lock member 16 composed of the rolling member 102 rides on the climbing portion 101 and enters the hook hole 105 of the bracket 40, thereby preventing the door 5 from being opened. .

In the present embodiment, unlike the first and second embodiments, the rolling member 102 at the lock position B only rides on the riding portion 101, and the rolling member 102 is moved to the lock position B. The holding force is only the inertial force f1 of the rolling member 102 (that is, its own weight).
For this reason, in the present embodiment, the inertia force f1 of the rolling member 102 is set to a value smaller than the urging force F of the door 5. In other words, the urging force F of the door 5 obtained by the hinge 6 with spring and the magnet catch 97 is set to a value larger than the inertia force f1 of the rolling member 102.

  Therefore, also in the case of the present embodiment, when the earthquake stops, the door 5 returns to the closing direction by the urging force F, and the return of the door 5 causes the locking member 16 including the rolling member 102 to be concavely curved inside the casing 15. It automatically returns to the deepest part of the surface 100 (unlock position A). The rolling member 102 of the present embodiment is not limited to a ball, but may be a roller.

FIG. 12 shows a fourth embodiment of the present invention.
The lock device main body 1 of the present embodiment is provided on the inner surface 5A side of the door 5, and has a mounting plate 107 fixed to the inner surface 5A, and a plate-shaped locking member 16 pivotally attached to the mounting plate 107. , Is provided.
The lock member 16 is made of an iron plate formed substantially in an L-shape when viewed from the side via a central bent portion, and has a lower vibrating leg 108 formed in a U-shape. A locking plate 109 extending upward and rearward is formed on the upper portion of the lock member 16, and a hook 110 is formed at the tip of the locking plate 109.

  The lock member 16 is pivotally attached to the mounting plate 107 via a horizontal shaft 111 inserted through the bent portion so that the lower end of the vibrating leg 108 abuts on the mounting plate 107. Accordingly, the latch plate 109 is in the unlocked position A at the lower position in the normal state when there is no vibration, but when receiving the vibration accompanying the earthquake or the like, the latch plate 109 is raised by the leaf spring action of the vibrating leg 108. At this time, it is attracted to the magnet 113 of the substrate 112 described later and reaches the lock position B.

A board 112 is screwed to the inner surface of the opening of the box body 3, and a bracket 40 to be hooked on the hook 110 of the hook plate 109 and the hook 110 are attached to the lower surface of the board 112. Is fixed.
Thus, when the locking plate 109 on the door 5 side is attracted by the magnet 113 and reaches the lock position B in the event of an earthquake or the like, the hook 110 locks the bracket 40 to prevent the door 5 from being opened. .

In this embodiment, unlike the first and second embodiments, the locking plate 109 of the lock member 16 at the lock position B is merely attracted to the magnet 113 of the The force holding the member 16 at the lock position B is only the attraction force of the magnet 113.
Therefore, in the present embodiment, the urging force F of the door 5 obtained by the hinge 6 with spring and the magnet catch 97 is set to be larger than the horizontal frictional force f2 acting on the hook 110 as the magnet 113 is attracted. Is set to In other words, the attractive force of the magnet 113 is set such that the horizontal frictional force f2 acting on the hook 110 generated by the magnet 113 is smaller than the urging force F of the door 5.

Therefore, also in the case of this embodiment, when the earthquake stops, the door 5 returns to the closing direction due to the urging force F, and the return of the door 5 causes the hook 110 of the lock member 16 to be separated from the magnet 113, and the unlocked position. A will automatically return to A.
The embodiments described above are illustrative and not restrictive.
That is, the scope of the present invention is defined by the appended claims, and all modifications that fall within the meaning of the claims are included in the present invention.

It is a side sectional view showing the locking device at the time of an earthquake concerning a first embodiment of the present invention. It is a perspective view of the storage box with which the lock device was attached. It is an exploded perspective view of the same lock device. (A) is a plan view of the case main body, (b) is a side sectional view of the case main body, and (c) is a rear view of the case main body. (A) is a plan view of the lid member, (b) is a side view of the lid member, (c) is a front view of the lid member, (d) is a rear view of the lid member, and (e) is the lid member. FIG. (A) is a plan view of the bracket, (b) is a side view of the bracket, and (c) is a rear view of the bracket. It is an operation explanatory view of a locking device at the time of an earthquake of a first embodiment, (a) is a figure showing a state where a lock member is in an unlock position, (b) is opening of a door is prevented by a lock member projected to a lock position. FIG. 7C is a diagram showing a state where the lock member is at the lock position but the door is open. (A) is a figure which shows the state in which the mounting position of the bracket changed upward in the locking device at the time of an earthquake of the first embodiment, and (b) is a figure which shows the state in which the mounting position of the bracket changed downward. . It is an expanded sectional view showing the state of action of the force when the first cam part contacts the second cam part 62 of the lock member. It is a side sectional view showing the locking device at the time of an earthquake of a second embodiment. (A) is side sectional drawing which shows the locking device at the time of an earthquake of 3rd embodiment, (b) is a perspective view of the bracket and the ball which engages with it. It is a side sectional view showing the locking device at the time of an earthquake of a fourth embodiment.

Explanation of reference numerals

1 Locking device body 2 Storage box 3 Frame (box body)
4 Opening 5 Wing (door)
5A inner surface 8A inner surface (lower surface of top plate)
15 Casing 16 Lock member 40 Engagement member (bracket)
63A Cam mechanism 100 Concave curved surface 101 Riding section 102 Rolling member (ball)
A Unlock position B Lock position F Wing urging force f Locking member f1 Inertial force of rolling member

Claims (6)

A wing (5) is pivotally attached to an opening (4) of the frame (3) in a state where it can be opened and closed and urged toward the frame (3), and an inner surface (8A) of the opening of the frame (3) or A lock device main body (1) having a lock member (16) which is always at the unlock position (A) and moves to the lock position (B) by vibration on one of the inner surfaces (5A) of the wing (5). ) Is provided, and a locking member (40) is provided on the other of the inner surfaces (8A) and (5A) to be locked by the locking member (16) at the locking position (B). In a storage box having an earthquake locking function, the locking member (16) returns to the unlock position (A) with the movement of the wing (5) in the closing direction,
A locking function in the event of an earthquake, wherein the urging force (F) in the closing direction of the wing (5) is set to a size that can return the lock member (16) to the unlock position (A). Storage box with. The lock member (16) is movable back and forth in a direction intersecting the moving direction of the wing (5) and is urged toward the lock position (B) to move the latched member (40) in the closing direction. Accordingly, a cam mechanism (63A) for moving the lock member (16) to the unlock position (A) is provided,
The urging force (F) in the closing direction of the wing (5) is F> 2fsin-, where the urging force of the lock member (16) is (f) and the inclination angle of the cam mechanism (63A) is (θ). 2. The storage box having an earthquake lock function according to claim 1, wherein the storage box is set to 12θ. The locking device body (1) includes a casing (15) having a concave curved surface (100) formed therein and having a riding portion (101) following the concave curved surface (100). The rolling member (102) is provided on the curved surface (100) so as to be able to roll freely. When the rolling member (102) rides on the climbing portion (101), the rolling member (102) becomes the lock position (B), The engaging member (40) is formed in a shape to be engaged with the rolling member (102) riding on the riding portion (101),
The storage box according to claim 1, wherein the biasing force (F) of the wing (5) is set to a value larger than the inertial force (f1) of the rolling member (102). The lock device body (1) attached to the inner surface of the opening (8A) of the frame (3) or the inner surface of the wing (5) pivotally attached to the opening (4) toward the frame (3). ), A lock member (16) provided on the lock device main body (1) so as to be always in the unlock position (A) and become the lock position (B) by vibration, and A locking member (40) provided on the other of the inner surfaces (8A) and (5A) so as to be locked by the locking member (16).
The lock member (16) is provided on the lock device body (1) so as to return to the unlock position (A) by a biasing force (F) of the wing (5) in the closing direction. Earthquake locking device. The lock member (16) is movable back and forth in a direction intersecting the moving direction of the wing (5) and is urged toward the lock position (B) to move the latched member (40) in the closing direction. Accordingly, a cam mechanism (63A) for moving the lock member (16) to the unlock position (A) is provided,
The urging force (f) of the lock member (16) is f <F sin θ cos θ, where (F) is the urging force of the wing (5) in the closing direction and (θ) is the inclination angle of the cam mechanism (63A). The seismic locking device according to claim 4, wherein the locking device is set to be: The locking device body (1) includes a casing (15) having a concave curved surface (100) formed therein and having a riding portion (101) following the concave curved surface (100). The rolling member (102) is provided on the curved surface (100) so as to be able to roll freely. When the rolling member (102) rides on the climbing portion (101), the rolling member (102) becomes the lock position (B), The engaging member (40) is formed in a shape to be engaged with the rolling member (102) riding on the riding portion (101),
The earthquake locking device according to claim 4, wherein the inertia force (f1) of the rolling member is set to a value smaller than the urging force (F) of the wing (5).

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