JP2006194078A - Seismic locking method and shelf with anti-earthquake measures - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a seismic locking method for a door or the like and a shelf with anti-earthquake measures using the method, wherein a locking body moves independently from a returning motion of the door or the like during an earthquake, so that the lock is not released by the returning motion of the door or the like while it reaches a lock position and oscillates during the earthquake, so that the releasing mechanism can be simplified. <P>SOLUTION: The seismic locking method according to the invention is composed in such a way that the locking body moves independently from the returning motion of the door or the like during the earthquake, so that the lock is not released by the returning motion of the door or the like, but it reaches the lock position and oscillates during the earthquake, so that the releasing mechanism can be simplified. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

Detailed Description of the Invention

The present invention relates to an earthquake locking method such as a door that automatically locks hinged doors, drawers and the like (hereinafter referred to as doors and the like) during an earthquake, and a shelf with an earthquake countermeasure using the method.

2. Description of the Related Art Conventionally, an earthquake locking device that automatically locks a door or the like in the event of an earthquake uses an earthquake locking method that detects an earthquake by moving a ball due to shaking. In this case, since the locking body is released by the return movement of the door or the like, the release mechanism is complicated.

Problems to be solved by the invention

The present invention solves the above-mentioned conventional problems, and the structure in which the locking body moves independently of the return movement of the door or the like at the time of an earthquake so that it is not released by the return movement of the door or the like and reaches the lock position at the time of the earthquake and vibrates. It is an object of the present invention to provide an earthquake lock method for a door or the like that can simplify the release mechanism by using the above, and a shelf with an earthquake countermeasure using the method.

Means for solving the problem

The present invention is a position in which the locking body of the apparatus main body attached to the shelf body side stops the opening movement of the door or the like in the event of an earthquake in the locking method in which the door or the like flutters in the event of an earthquake to achieve the above object. Moves to the locked position, and the locking body moves independently of the return movement of the door etc. Thus, after the door is moved away from the door or the like, the locking body proposes a locking method in the event of an earthquake such as the door returning to the standby position regardless of the movement of the door or the like.

The invention's effect

The embodiment of the earthquake locking method for a door or the like and the shelf with an earthquake countermeasure using the method according to the present invention are as described above, and the effects thereof are listed below.
The locking method at the time of an earthquake of the present invention is configured such that the locking body moves independently of the return movement of the door or the like in the event of an earthquake, and is thus not released by the return movement of the door or the like and reaches the lock position at the time of the earthquake and vibrates. This can simplify the release mechanism.

Hereinafter, an earthquake locking method for a door and the like according to the present invention and a shelf with an earthquake countermeasure using the method will be described with reference to the embodiments shown in the drawings.
1 and 2 show an earthquake locking device such as a door using the earthquake locking method of the present invention (except for components different from the scope of the present invention), and the earthquake locking device is an apparatus main body. A recess as the vibration area A is provided in (1).
In the illustrated embodiment, the floor surface of the vibration area A is inclined to the left and right and is also inclined forward.
Further, a sphere (9) is housed in the vibration area A so as to vibrate, and the sphere (9) has the center rear end of the vibration area A at its stable position.
Next, the locking body (2) is attached to the apparatus body (1) so as to be rotatable about the shaft (2c).
An opening as the vibration area A is provided in the front portion of the locking body (2) that is in front of the shaft (2c), and the sphere (9) is stored in the opening.
The opening as the vibration area A allows a lateral movement to be added when the sphere (9) moves forward at the inclined front edge A1 as shown in FIG.
Next, the front end of the opening as the vibration area A is provided with a ridge (2b) whose lower surface is inclined.
Further, at the tip of the locking body (2), the locking portion (2e) and the locking portion (5a) of the locking device (5) (described later) locked to the locking portion (2e) are locked. An elastic portion (2f) that secures a holding force (also an unlocking force) is provided.
On the other hand, a weight (2d) for adjusting the balance by bringing the center of gravity of the locking body (2) closer to the shaft (2c) is provided at the rear part of the locking body (2).
Next, the upper surface of the apparatus main body (1) is closed with a lid (3) in order to prevent the locking body (2) from coming off from the apparatus main body (1).
The apparatus main body (1) is attached to a main body (90) of a shelf such as furniture and a hanging cupboard with screws or the like.
On the other hand, a latch (5) is attached with a screw or the like to a hinged door (91) of a shelf such as furniture and a hanging cabinet (the illustrated one shows a hinged door as an example of a door including a drawer).
The locking tool (5) has a locking portion (5a) locked to the locking portion (2e) of the locking body (2).

The operation of the earthquake locking method of the present invention of FIGS. 1 to 3 shown in the above embodiment and the earthquake locking device such as a door using the same is as follows.
That is, in a normal use state, as shown in FIG. 1, the locking body (2) is stable with the locking portion (2e) at the front end lowered around the shaft (2c).
In this state, the sphere (9) is located at the center rear end or near the rear end which is a stable position formed by the inclined surface of the vibration area A of the apparatus main body (1).
That is, it is said that it is near the rear end because the sphere (9) may be stabilized while being pushed by the opening as the vibration area A of the locking body (2).
In the stable state at the stable position, the hinged door (91) is opened and closed, but the locking part (2e) at the front end of the locking body (2) is lowered, so that the locking tool (5) is the locking body ( It is not locked to the locking part (2e) of 2).
Therefore, the hinged door (91) can be freely opened and closed, and the user can store and take out articles from the inside of the shelf.
Next, since the main body (90) of the shelf is shaken during an earthquake, the ball (9) moves forward from a stable position near the center rear end or the rear end of the vibration area A as shown in FIG. To do.
As a result, the ball (9) pushes up the hook (2b) of the locking body (2), and the locking portion (2e) at the front end of the locking body (2) rises as shown in FIG.
Even if there is no hook (2b), the ball (9) hits the front end of the vibration area A of the locking body (2), so that the locking portion (2e) at the front end of the locking body (2) rises.
However, if there is a hook (2b), the locking portion (2e) at the front end of the locking body (2) can be easily lifted.
Here, when the sphere (9) simply vibrates linearly, the sphere (9) vibrates substantially in synchronization with the vibration waveform of the earthquake.
However, the hinged door (91) has a large inertia, so its opening / closing waveform deviates (delays) from the vibration waveform of the earthquake.

That is, even if the direction of the shaking of the earthquake is reversed from the forward direction to the backward direction, the hinged door (91) continues to move in the direction of opening as it is due to inertia.
Therefore, in the conventional method in which the sphere (9) is simply vibrated linearly, the sphere (9) moves backward almost in synchronization with the vibration waveform of the earthquake, so that the locking portion (2e) of the locking body (2) begins to descend. The locking part (5a) of the locking tool (5) cannot be locked to the locking part (2e) of the locking body (2), and the hinged door (91) opens.
However, in the present invention, the engaging body (2) is provided with the vibration area A having the inclined front edge A1, and the ball (9) accommodated in the vibration area A moves laterally at the front edge A1 when moving forward. Is added.
As a result, the forward path of the ball (9) (the path along the broad front edge A1 of the vibration area A of the locking body (2)) and the backward path (the wide rear edge of the vibration area A of the locking body (2)). The path along the path) can be clearly different, and it is easy to increase the load applied to the ball (9) in the retreat path, and the retreat time can be made longer than the advance.
As a result, even if the direction of the shaking of the earthquake is reversed from the forward direction to the backward direction, the locking portion (2e) of the locking body (2) continues to remain in the raised state for a while and then descends.
It is very important to continue the state in which the locking portion (2e) is raised for a while, and this corresponds to the continuation of the movement of the hinged door (91) in the opening direction.
Therefore, the locking part (5a) of the locking tool (5) can be locked to the locking part (2e) of the locking body (2) by the movement in the opening direction of the hinged door (91).
As apparent from the above, by increasing the load applied to the ball (9) in the backward path and making the backward time longer than the forward direction, it is possible to cope with the deviation (delay) of the open / close waveform of the hinged door (91).
As a method of increasing the load applied to the ball (9) in the backward path, in the illustrated embodiment, the ball (9) is brought into contact with a portion near the axis (2c) of the locking body (2) in the backward path. In the forward path, the ball (9) is brought into contact with a portion far from the axis (2c) of the locking body (2) to apply a small load due to the weight of the locking body (2). -ing
As a result, the load applied to the ball (9) when retreating increases, and the retreat time becomes longer than the advance.

Further, in the illustrated embodiment, the following method is also added to cope with the opening / closing waveform of the hinged door (91) being deviated (delayed) from the vibration waveform of the earthquake.
That is, the ball (9) is housed in the vibration area A of the apparatus main body (1) attached to the shelf main body so as to be able to vibrate, and the forward path and the backward path of the ball (9) are different from each other, and the swing door (91) The ball (9) is retracted while being brought into contact with the locking body (2) locked to the locking tool (5), thereby allowing the locking body (2) to be lifted by the ball (9). Furthermore, the ball (9) is housed in the vibration area A of the apparatus main body (1) attached to the shelf main body so as to vibrate, and the forward path and the backward path of the ball (9) are the same or different. Even in the case (the case shown in the figure is different), the ball (9) is brought into contact with the portion close to the shaft (2c) of the locking body (2) locked to the locking tool (5) of the hinged door (91) when retreating. I am letting.
In this way, the locking body (2) is lifted up by the ball (9), and the locking body (2) is lifted until the ball (9) reaches the rear end, and finally the locking body (2). Can be lowered easily.
Although not shown in the drawing, the ball (9) is housed in the vibration area A of the apparatus body (1) attached to the shelf body side so as to be able to vibrate, and the forward path and the backward path of the ball (9) are the same. In any case where the balls (9) are different (if they are different), the locking body (2) to be locked to the locking tool (5) of the hinged door (91) when the ball (9) moves forward and backward The contact portion may be made different to increase the friction of the contact portion during retraction.
For example, there is a method in which the material of the contact portion at the time of retraction is made of a material with high friction or the surface is rough.
Further, in the illustrated embodiment, the ball (9) is housed in the vibration area A of the apparatus body (1) attached to the shelf body side so as to be able to vibrate, and the forward path and the backward path of the ball (9) are the same. In any case (if the figures are different), the swinging return force is applied to the locking body (2) locked to the locking tool (5) of the hinged door (91). The ball (9) is retracted while being lifted by a return force.
That is, the locking body (2) is positively lifted not by a passive method of extending the retreat time of the ball (9) but by a swinging return force.

Furthermore, the ball (9) is housed in the vibration area A of the apparatus main body (1) attached to the shelf main body so as to vibrate, and the forward path and the backward path of the ball (9) are the same or different. Even in such a case, as the path of the sphere (9), the front path of the vibration area A is longer than the rear path, and the time during which the sphere (9) is present at the front is longer than the time at the rear. There is also.
As described above, the locking portion (2e) of the locking body (2) that continues to rise is the locking portion (5) of the locking tool (5) of the hinged door (91) that continues to move in the opening direction. 5a) and the hinged door (91) is locked with a gap (from FIG. 4 to FIG. 5).
The hinged door (91) acts on the latching portions (2e) and (5a) with a force for releasing the latching according to the weight of the hinged door (91) and the acceleration of the earthquake when the shaking of the earthquake returns.
The force for releasing the locking is also the elastic resistance (locking holding force) (locking releasing force) of the elastic portion (2f) provided near the locking portion (2e) of the locking body (2). ) The locked state is maintained if it is below.
That is, it is expected by setting the (locking holding force) (also locking release force) of the locking portions (2e) and (5a) from both the weight of the hinged door (91) and the expected earthquake acceleration. In the range of earthquakes, the locked state is maintained until the earthquake ends. When the earthquake is over, the user pushes the hinged door (91) of FIG.
As a result, the locked state is released, and the locking portion (2e) of the locking body (2) is lowered from the state of FIG. 5 to open and close the hinged door (91) as shown in FIG.
Here, when the earthquake ends, the ball (9) returns to the stable position at the center rear end due to the inclination of the floor surface of the vibration area A of the apparatus body (1) regardless of the release of the locked state.

As is apparent from the above, the locking method in the event of an earthquake such as the doors in FIGS. 1 to 5 is such that the locking body (2) of the device body (1) attached to the shelf body (90) side opens the doors and the like in the event of an earthquake. The locking body (2) moves independently of the return movement of the door, etc., and is not released by the return movement of the door, etc., and reaches the lock position in the event of an earthquake. The locking body (2) is locked in the event of an earthquake such as a door that returns to the standby position regardless of the movement of the door or the like after moving away from the door or the like by oscillating or holding the lock position and eliminating the shaking of the earthquake. Is the method.
In the illustrated case, the locking body (1) of the device main body (1) is locked to the locking tool (5) such as a door in the event of an earthquake, and the door or the like is locked in a locked state with almost no flapping. Was the way.
Next, FIG. 6 shows an embodiment of the locking method for an earthquake of a door or the like according to the present invention, and the locking method for an earthquake of a door or the like in which the door or the like flutters in the event of an earthquake as compared with the one shown in FIGS. It is characterized by being.
That is, the locking portion (2e) of the locking body (2) is simply stopped without being locked to the locking portion (5a) of the locking tool (5) such as a door, and the door or the like flutters during an earthquake. It becomes locked.

Side sectional view of an apparatus embodying the earthquake locking method of the present invention 1 is an exploded perspective view of the apparatus of FIG. Plan view of the vibration area of the device of FIG. Side sectional view showing the operating state of the device of FIG. Side sectional view showing the operating state of the device of FIG. Side sectional view of an apparatus embodying the earthquake locking method of the present invention

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Apparatus main body 2 Locking body 2b Shaft 2c Shaft 2d Weight 2e Locking part 2f Elastic part 3 Lid 5 Locking tool 5a Locking part 5b Attachment part 9 Sphere 90 Main body 91 Swing door A Vibration area A1 Front edge

Claims (4)

In the locking method in which the doors and the like flutter in a locked state at the time of an earthquake, the locking body of the device main body attached to the shelf main body moves to the lock position where the opening movement of the doors and the like stops at the time of the earthquake, and the locking body Moves independently of the return movement of the door, etc., and is not released by the return movement of the door, etc., but vibrates when reaching the lock position in the event of an earthquake. Locking method for earthquakes such as doors that return to the standby position regardless of the movement of the doors etc. Swing door with earthquake countermeasures using the earthquake locking method of claim 1 Drawer with earthquake countermeasures using the earthquake locking method of claim 1 Shelf with earthquake countermeasures using the earthquake locking method according to claim 1

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