JPWO2009050981A1 - Seismic latch structure - Google Patents

Abstract

It has a simple configuration and can be easily implemented, and it can securely lock moving members such as drawers, sliding doors or hinged doors during the action of vibration, and can easily release the locked state and It is an earthquake-resistant latch structure that can be reliably performed, and includes a standby passage portion (55) and an action passage portion (56) extending in a direction intersecting with the standby passage portion (55), and is provided on the fixing member (1). A restriction slot (53) formed therein, a detection pin (51) that is movably provided in the restriction slot (53) and protrudes from the restriction slot toward the movement member (2), and the movement member (2) And the detection pin (51) set in the working passage portion (56) without being engaged with the detection pin (51) set in the standby passage portion (55) of the restriction slot (53). And a stopper that only engages.

Description

  The present invention is used, for example, in drawers, sliding doors or hinged doors in furniture and home appliances, where the moving member moves due to translational movement, rotational movement, etc. The present invention relates to an earthquake-resistant latch structure that locks movement of a moving member when vibration is generated.

  In recent years, in furniture and system kitchens, there are a large number of drawers that are attached to the furniture body through a guide member using balls, rollers, etc. for the purpose of improving operability and texture. . Such drawers can be easily and smoothly pulled out of the furniture body even when heavy objects are stored, but during an earthquake or transport, if the shaking is large, the drawer will pop out of the furniture body. There is a concern that the stored items will scatter and eventually injure the people around.

  For this reason, an earthquake-resistant latch structure that locks the movement of the drawer with respect to the furniture main body due to the acting vibration has been proposed (Japanese Patent Laid-Open No. 2003-24156, Japanese Patent Laid-Open No. 2007-105405).

  An earthquake-resistant latch structure disclosed in Japanese Patent Application Laid-Open No. 2003-24156 includes an engaged portion provided on a drawer side, and a lock provided on a furniture body side and biased toward a lock position engaging with the engaged portion. A member, a holding member that locks the locking member against the urging force at the unlocked position, and a ball that releases the locking state of the holding member and the locking member. Then, when a shake due to an earthquake or the like acts on the furniture, the ball collides with the holding member to release the locking state of the holding member and the lock member, and the lock member moves from the unlock position to the lock position. Is configured to do. As a result, the engaged portion meshes with the lock member, and the movement of the drawer with respect to the furniture body is locked.

  Further, in this earthquake-resistant latch structure, a lock release member is provided on the drawer side, and when the drawer is completely stored in the furniture body, the lock release member pushes the lock member back from the lock position to the unlock position. The holding member is configured to lock the lock member again.

  On the other hand, the earthquake-resistant latch structure disclosed in Japanese Patent Application Laid-Open No. 2007-105405 is in a state of being retracted into the casing by a casing provided on the furniture body side and supported swingably with respect to the casing and by the biasing force of the spring. A hook member that is held by the hook member, a stopper body that is provided on the drawer side and engages with the hook member that protrudes from the casing, and is accommodated in the casing and pushes the hook member out of the casing in accordance with its rolling position. It consists of a ball. When a shake due to an earthquake or the like acts on the furniture, the ball moves in the casing, and accordingly, the hook member protrudes from the casing and meshes with the stopper body on the drawer side.

In addition, in this latter seismic latch structure, the ball housing space in the casing is inclined so that the ball returns to its original position by its own weight, and when the shaking stops, the ball naturally returns to its original position. In connection with this, the hook member is pulled into the casing, and the meshing state between the hook member and the stopper body is released.
JP2003-24156 JP2007-105405A

  However, in these conventional earthquake-resistant latch structures, the ball moves by detecting the swing, and further, the lock member or the hook member advances to the engagement position with the drawer due to the movement, and as a result, the furniture body Since the movement of the drawer with respect to the movement of the ball is restricted and the movement of the lock member or the hook member needs to be created due to the movement of the ball, the structure has to be complicated. In addition, since the movement of the lock member or the hook member is created due to the movement of the ball that has detected the swing, the movement is likely to be unstable, and the drawer is not locked even though the vibration is acting. A malfunction may occur.

  Furthermore, with this type of seismic latch structure, it is necessary to release the locked state of the drawer after the shaking has settled and restore it to its original state. However, with the above-mentioned seismic latch structure, the ball spontaneously returns to its original position. If the ball is stopped in an unstable state, the locked state cannot be released. Further, in this case, since the drawer cannot be pulled out, it becomes very difficult for the user of the drawer to release the locked state.

  The present invention has been made in view of such problems, and the object of the present invention is to have a simple configuration and can be easily implemented, and to move members such as drawers and hinged doors when a vibration is applied. It is an object of the present invention to provide an earthquake-resistant latch structure that can be securely locked and that can be easily and reliably released from the locked state.

  That is, the present invention is an earthquake-resistant latch structure that is provided between a fixed member and a movable member that is movable with respect to the fixed member, and that restricts the movement of the movable member relative to the fixed member when a vibration is applied. A restricting slot provided in the fixing member, which is configured by a passage portion and an action passage portion extending in a direction intersecting with the standby passage portion, and is movably provided in the restricting slot and is directed from the restricting slot toward the moving member. And a stopper that is provided on the moving member and that engages only with the detection pin set in the working passage portion without being engaged with the detection pin set in the standby passage portion of the restriction slot. , Is composed of.

  In such an earthquake-resistant latch structure of the present invention, when the detection pin provided movably in the restriction slot acts on the fixing member provided with the restriction slot, the standby passage that was initially set It moves to the action channel part by the energy of the vibration from the part. On the other hand, when a vibration is applied to the moving member, the moving member causes a movement such as a translational movement and a swinging movement with respect to the fixed member by the energy of the vibration. The stopper provided on the moving member acts on the stopper. When set in the passage portion, it engages with the detection pin. For this reason, if the vibration that the detection pin moves from the standby passage portion of the restriction slot to the working passage portion acts on the fixed member, the movement of the moving member relative to the fixed member is limited. On the other hand, if the detection pin remains set in the standby passage portion, the stopper does not engage with the detection pin at all, so that the moving member can move freely with respect to the fixed member.

  Therefore, in the earthquake-resistant latch structure of the present invention, the detection pin set in the action passage portion directly engages with the stopper in accordance with the action of vibration on the fixed member, and the movement of the moving member with respect to the fixed member is locked. The structure is extremely simple, and the moving member can be reliably locked with respect to the fixed member as long as the detection pin moves due to the shaking. In addition, the restriction slot may be in the shape of a long hole through which the detection pin can move, and the stopper may be a simple plate-like member. The restriction slot and the stopper are located on the fixed member and the moving member. It can be easily provided, and the present invention can be implemented at a very low cost.

  The seismic latch structure of the present invention thus configured can be applied to drawers for furniture, home appliances, system kitchens, etc., and can also be applied to sliding doors. Moreover, it is possible to apply also to what is called a hinged door in which the door as a moving member performs rotational motion with respect to the furniture main body as a fixed member. And since the seismic latch structure of the present invention can be implemented by forming a restriction slot on the fixed member and a stopper on the moving member, it can be installed in a narrow space. It can be attached to these applications without causing a reduction in the storage capacity of the drawer.

It is a perspective view which shows 1st embodiment of the slide rail unit to which the earthquake-resistant latch structure of this invention is applied. It is a front view of the slide rail unit shown in FIG. It is a side view which shows the state which pulled out the inner rail from the outer rail. It is an enlarged view which shows the detail of the control slot of a pin setting member. In the earthquake-resistant latch structure in 1st embodiment, it is a figure which shows the positional relationship of the detection pin and guide member in a normal use state. In the earthquake-resistant latch structure in 1st embodiment, it is a figure which shows the positional relationship of the detection pin and guide member at the time of the effect | action of a vibration. It is a figure which shows return operation | movement of a detection pin in the earthquake-resistant latch structure in 1st embodiment. It is a perspective view which shows 2nd embodiment of the slide rail unit to which the earthquake-resistant latch structure of this invention is applied. It is the front view and top view which show the pin control member in 2nd embodiment. It is a front view which shows the guide member in 2nd embodiment. In the earthquake-resistant latch structure in 2nd embodiment, it is a figure which shows the positional relationship of the detection pin and guide member in a normal use state. In the earthquake-resistant latch structure in 2nd embodiment, it is a figure which shows the positional relationship of the detection pin and guide member at the time of the effect | action of a vibration. It is a figure which shows return operation | movement of a detection pin in the earthquake-resistant latch structure in 2nd embodiment. It is a perspective view which shows 3rd embodiment of the slide rail unit to which the earthquake-resistant latch structure of this invention is applied. It is a front view of the slide rail unit shown in FIG. It is a perspective view which shows 4th embodiment of the slide rail unit to which the earthquake-resistant latch structure of this invention is applied. It is a side view which shows the state which pulled out the inner rail which concerns on 4th embodiment from the outer rail. In the earthquake-resistant latch structure in 4th embodiment, it is a figure which shows the positional relationship of the detection pin and guide member in a normal use condition. In the earthquake-resistant latch structure in 4th embodiment, it is a figure which shows the positional relationship of the detection pin and guide member at the time of the effect | action of a vibration. It is a figure which shows return operation | movement of a detection pin in the earthquake-resistant latch structure in 4th embodiment. It is a perspective view which shows 5th embodiment which applied the earthquake-resistant latch structure of this invention to the hinged door of furniture. It is a principal part enlarged plan view which shows the positional relationship of the pin setting member and guide member which concern on 5th embodiment.

  Hereinafter, the earthquake-resistant latch structure of the present invention will be described in detail with reference to the accompanying drawings.

  1 and 2 show a first embodiment in which the earthquake-resistant latch structure of the present invention is applied to a slide rail unit used for drawers such as furniture. The slide rail unit includes an outer rail 1, an inner rail 2 that translates relative to the outer rail 1, and that rolls between the outer rail 1 and the inner rail 2. And a retainer 4 for arranging a large number of balls 3 at a predetermined interval between the outer rail 1 and the inner rail 2. FIG. 1 shows a state in which the inner rail 2 is housed in the outer rail 1, and the ball 3 and the retainer 4 are present in the vicinity of the central portion in the longitudinal direction of the outer rail 1. Therefore, FIG. And the retainer 4 is not drawn.

  For example, when this slide rail is used as a guide member for drawers such as furniture, the outer rail 1 is fixed to the furniture body and the inner rail 2 is fixed to the drawer. Thereby, it is possible to smoothly put in and out the drawer with respect to the furniture body using the rolling of the balls 3 arranged between the outer rail 1 and the inner rail 2. That is, the outer rail corresponds to the fixed member in the present invention, and the inner rail corresponds to the moving member in the present invention.

  The outer rail 1 is formed by precision forming a steel plate by roll forming, and is formed in a channel shape by bending a pair of ball rolling portions 12 and 12 along the longitudinal direction of the attachment portion 11. A ball rolling surface having a curvature approximate to the spherical surface of the ball 3 is formed on the inner side surface of the ball rolling portion 12.

  On the other hand, the inner rail 2 is similarly formed from a steel plate and formed into a channel shape by bending the pair of ball rolling portions 22 and 22 along the longitudinal direction of the mounting portion 21. However, since the inner rail 2 is housed between the ball rolling portions 12 and 12 of the outer rail 1 and the balls 3 are arranged between the inner rail 2 and the outer rail 1, the inner rail 2 is formed to be slightly smaller than the outer rail 2 and A ball rolling surface is formed on the outer surface of the rolling part 22.

  The retainer 4 is formed by pressing a steel plate or by injecting a synthetic resin into a mold. The retainer 4 is inserted between the outer rail 1 and the inner rail 2 and is interposed between the rails 1 and 2. Are arranged at equal intervals to prevent contact between adjacent balls.

  In the slide rail unit configured as described above, since the outer rail 1 and the inner rail 2 are combined via the ball 3 as described above, the rolling of the ball 3 causes the outer rail 1 to move into the outer rail 1. The stored inner rail 2 can be smoothly pulled out from the outer rail 1.

  This slide rail unit is configured to have the shortest overall length when the inner rail 2 is completely overlapped with the outer rail 1, that is, when the inner rail 2 is completely retracted into the outer rail 1 as shown in FIG. For example, a state in which the above-described drawer is completely stored in the furniture body corresponds to this state.

  The inner rail 2 can be easily pulled out from the outer rail 1 by utilizing the rolling of the ball 3. This is because the inner rail 2 is unintentionally moved due to an earthquake or a vibration during transportation. This means that there is a high possibility of moving with respect to 1. Accordingly, the slide rail unit is provided with an earthquake-resistant latch structure 5 to prevent the inner rail 2 from unintentionally popping out when a shake such as an earthquake or transportation is applied.

  The seismic latch structure 5 includes a pin setting member 50 fixed to the outer rail 1, a detection pin 51 that is held by the pin setting member 50 and whose setting position is changed according to the action of shaking on the outer rail 1, The guide member 52 is fixed to the inner rail 2 and engages with the detection pin 51 according to the set position of the detection pin 51.

  The pin setting member 50 fixed to the outer rail 1 and the guide member 52 fixed to the inner rail 2 are set so as to overlap each other in a state where the inner rail 2 is completely drawn into the outer rail 1, that is, the state shown in FIG. Yes. FIG. 3 shows a state where the inner rail 2 is moved with respect to the outer rail 1 and the guide member 52 is displaced from the pin setting member 50.

  The pin setting member 50 is formed by opening a slot-like restriction slot 53 with respect to a metal plate. In the example shown in FIG. 1, the pin setting member 50 is fixed to the outer rail 1 via an L-shaped flange portion 54. The restriction slot 53 faces the inner rail 2. The detection pin 51 is inserted into the restriction slot 53 and is held substantially perpendicular to the pin setting member 50. The detection pin 51 has a pair of locking rings so that it does not fall out of the restriction slot 53. 51 a is positioned and fixed on the front and back of the pin setting member 50. FIG. 4 shows details of the restriction slot 53. The restriction slot 53 includes a standby passage portion 55 that extends in the moving direction of the inner rail 2, and an action passage portion 56 that extends obliquely downward from one end of the standby passage portion 55. A pin restricting portion 57 is provided between the standby passage portion 55 and the working passage portion 56 so that the detection pin 51 is not easily moved from the standby passage portion 55 to the working passage portion 56. It has been. In the restriction slot 53 shown in FIG. 4, the standby passage portion 55 is inclined by an angle α with respect to the horizontal direction, that is, the moving direction of the inner rail 2, whereby the pin restriction portion 57 is connected to the standby passage portion 55 and the working passage. It is formed between the portion 56. In other words, the standby passage portion 55 is formed as a downwardly inclined path in a direction away from the action passage portion 56, and the detection pin 51 located in the standby passage portion 55 moves to the tip of the standby passage portion 55 by its own weight. Therefore, unless some external force acts on the detection pin 51, the detection pin 51 does not move over the pin restricting portion 57 and move from the standby passage portion 55 to the action passage portion 56. In addition, the detection pin that has entered the working path portion 56 over the pin restricting portion 57 is configured to fall to the lower end of the working path portion 56 by its own weight.

  On the other hand, the guide member 52 is formed by cutting out a locking groove 58 into which the tip of the detection pin 51 enters the metal plate, and is fixed to the inner rail 2, and the inner rail 2 is connected to the outer rail 1. The pin setting member 50 is arranged so as to overlap with the pin setting member 50 when stored.

  The locking groove 58 includes a stopper 59 that engages with the detection pin 51 that has fallen into the action passage portion 56 of the restriction slot 53, and a recovery slope 60 that is formed obliquely upward facing the stopper 59. ing. The stopper 59 is formed in a substantially V shape so as to be surely engaged with the detection pin 51, and is expanded in a direction in which the inner rail 2 is pulled out from the outer rail 1. When the inner rail 2 tries to jump out of the outer rail 1 in a state where it has fallen into the action passage portion 56, the tip of the detection pin 51 enters the deepest portion of the stopper 59.

  The restoration slope 60 is formed as an inclined surface obliquely upward with respect to the horizontal direction, and the upper end of the restoration slope 60 is located above the standby passage portion 55 of the restriction slot 53. For this reason, when the inner rail 2 is pushed into the outer rail 1 from a state in which the detection pin 51 is locked to the stopper 59, that is, a state in which the detection pin 51 is dropped into the action passage portion 56 of the restriction slot 53, the detection is performed. When the pin 51 is brought into contact with the recovery slope 60 and the action passage portion 56 is pushed upward and the inner rail 2 is completely stored in the outer rail 1, the detection pin 51 gets over the pin restricting portion 57 and enters the standby passage portion 55. It is set up.

  Further, in the guide member 52, the height of the portion on the back side of the inner rail 2 (the left side in FIG. 3) with respect to the locking groove 58 is formed lower than the height of the recovery slope 60. When the 2 is pulled out from the outer rail 1, the detection pin 1 set in the standby passage portion 55 of the restriction slot 53 is configured not to interfere with the guide member 52. In addition, a guide slope 61 is formed as an upward inclined surface at the tip of the guide 52 member in the pushing direction of the inner rail 2, and the detection pin 51 is unintentionally in a state where the inner rail 2 is pulled out from the outer rail 1. The detection pin 51 can be guided into the locking groove 59 of the guide member 52 when it falls into the action passage portion 56 of the restriction slot 53.

  FIG. 5 shows the relationship between the setting state of the detection pin 51 and the guide member 52 in the normal use state of the slide rail unit. 5 to 7 described below, only the restriction slot 53, the detection pin 51, and the guide member 52 are shown for simplification. As shown in FIG. 5, the detection pin 51 is set in the standby passage portion 55 of the restriction slot 53 in the normal use state of the slide rail unit. As described above, since the standby passage portion 55 is inclined at the angle α, the detection pin 51 is maintained at the tip of the standby passage portion 55 unless some external force acts on the detection pin 51. 5 shows a positional relationship between the detection pin 51 and the guide member 52 at a state where the inner rail 2 is completely stored in the outer rail 1, that is, at a stroke end of the inner rail 2. FIG. Even if the inner rail 2 and the guide member 52 fixed to the inner rail 2 are moved to the right in the drawing from this state and the inner rail 2 is pulled out from the outer rail 1, the detection pin 51 is guided by the guide b as shown in FIG. There is no interference with the member 52. For this reason, in a state where the detection pin 51 is set in the standby passage portion 55, the inner rail 2 can be freely moved with respect to the outer rail 1, and for example, the drawer is freely taken in and out of the furniture body. be able to.

  FIG. 6 shows a state in which the vibration is applied to the slide rail unit due to an earthquake or transportation, and the earthquake-resistant latch structure 5 is operated. 6 shows the relationship between the detection pin 51 and the guide member 52 at the stroke end of the inner rail 2, and the detection pin 51 is restrained by the recovery slope 60 of the guide member 52 in this state. In this way, it is held in the standby passage portion 55 of the restriction slot 53. When vibration is applied to the slide rail unit from this state, the inner rail 2 is slightly pulled out of the outer rail 1 to release the restraint state of the detection pin 51 by the recovery slope 60 of the guide member 52, and the detection pin 51 is in a standby state. The passage portion 55 can be freely moved. When the magnitude of the vibration acting on the slide rail unit reaches a certain level, the detection pin 51 gets over the pin restricting portion 57 and moves from the standby passage portion 55 to the action passage portion 56, as shown in FIG. And moves to the lower end of the action passage portion 56 by its own weight. Then, when the inner rail 2 further tries to jump out of the outer rail 1 from the state in which the detection pin 51 has fallen into the action passage portion 56, the detection pin 51 hits the stopper 59 of the guide member 52 as shown in FIG. The movement of the inner rail 2 relative to the outer rail 1 is locked by the engagement between the tip of the detection pin 51 and the guide member 52. Accordingly, the inner rail 2 is prevented from jumping out of the outer rail 1, and for example, it is possible to prevent an accident in which the drawer is unintentionally jumped out of the furniture body during an earthquake or the like.

  As to how much swing is applied to the slide rail unit when the detection pin 51 is dropped into the action passage portion 56 of the restriction slot 53, the length or inclination angle α of the standby passage portion 55, or It is possible to arbitrarily adjust the friction coefficient between the detection pin 51 and the standby passage portion 55 by adjusting the friction coefficient. Accordingly, the seismic latch structure 5 can be acted upon quickly when slight vibrations are applied, and the limit point of the drop condition of the detection pin 51 is set so that the detection pin 51 does not drop in daily use. It can also be raised.

  On the other hand, FIG. 7 shows an operation of returning the detection pin 51 from the action passage portion 56 of the restriction slot 53 to the standby passage portion 55. In the partial diagram a, the detection pin 51 has fallen into the action passage portion 56 of the restriction slot 53 and the stopper 59 of the guide member 52 is engaged with the detection pin 51, so that the inner rail 2 is in relation to the outer rail 1. It is in a locked state. When the inner rail 2 is pushed into the outer rail 1 from this state, the detection pin 51 rides on the recovery slope 60 provided opposite to the stopper 59 as shown in the partial diagram b, and acts as the inner rail 2 moves. The passage portion 56 is lifted up. When the pushing operation of the inner rail 2 with respect to the outer rail 1 is further continued, the detection pin 51 gets over the pin restricting portion 57 and is reset to the standby passage portion 55 as shown in FIG. As shown to d, it will be in the state pressed by the said restoration slope 60 and restrained in the front-end | tip of the waiting | standby passage part 55. FIG. Thereby, the return operation of the detection pin 51 to the standby passage portion 55 is completed.

  However, since the earthquake shakes repeatedly, for example, when an earthquake occurs, not only the locking operation of FIG. 6 occurs alone, but the locking operation of FIG. 6 and FIG. Thus, the unintentional pop-out of the inner rail 2 with respect to the outer rail 1 is prevented.

  Next, FIG. 8 shows a second embodiment of the earthquake-resistant latch structure of the present invention. Also in the second embodiment, the earthquake-resistant latch structure is applied to the slide rail unit having the same structure as that of the first embodiment. Therefore, the slide rail unit is denoted by the same reference numerals as those in the first embodiment in FIG.

  The seismic latch structure 7 of the second embodiment also has a pin setting member 70 fixed to the outer rail 1, and is held by the pin setting member 70, and the setting position is changed according to the action of shaking on the outer rail 1. And a guide member 72 that is fixed to the inner rail 2 and engages with the detection pin 71 in accordance with a set position of the detection pin 71. This is the same as the embodiment.

  However, in the first embodiment described above, the guide member 52 and the pin setting member 50 overlap each other at the stroke end of the inner rail 2, and the detection pin 51 is set in the standby passage portion 55 of the restriction slot 53. In the second embodiment, the guide member 72 is configured to completely pass through the pin setting member 70 until the inner rail 2 reaches the stroke end.

  FIG. 9 shows the pin setting member 70, where a part a is a front view and a part b is a plan view. The pin setting member 70 has a retraction plate portion 70b obliquely intersecting with a main body plate portion 70a facing the inner rail, and a slot-shaped restriction slot straddling the main body plate portion 70a and the retraction plate portion 70b. 73 is established. The pin setting member 70 is fixed to the outer rail 1 via an L-shaped flange portion 74, and a part of the restriction slot 73 faces the inner rail 2. The detection pin 71 is inserted into the restriction slot 73 and is held substantially perpendicular to the pin setting member 70, so that the detection pin 71 does not fall out of the restriction slot 73. 71 b is positioned and fixed on the front and back of the pin setting member 70. The restriction slot 73 includes a standby passage portion 75 formed in the retracting plate portion 70b, a working passage portion 76 provided in the main body plate portion and extending obliquely downward from one end of the standby passage portion 75, and the working passage. The retraction passage portion 76a extends obliquely upward from the lower end of the portion 76. The retracting passage portion 76a is positioned at an end opposite to the working passage portion 76 above a recovery slope 80 of a guide member described later.

  The standby passage portion 75 constituting a part of the restriction slot 73 is formed in the retracting plate portion 70b of the pin setting member 70, and the retracting plate portion 70b is bent with respect to the main body plate portion 70a. As shown in FIG. 9b, the tip of the detection pin 71 set in the standby passage 75 is retracted from the movement path of the guide member 72 indicated by a two-dot chain line in the diagram b. Yes. That is, when the detection pin 71 is set in the standby passage portion 75, the guide member 72 can pass through the pin setting member 70 without interfering with the detection pin 71.

  Further, a pin restricting portion 77 is provided between the standby passage portion 75 and the action passage portion 76 so that the detection pin 71 is not easily moved from the standby passage portion 75 to the action passage portion 76. It has been. This pin restricting portion 77 is formed by inclining the standby passage portion 75 by a minute angle with respect to the horizontal direction, that is, the moving direction of the inner rail 2, as in the first embodiment. That is, the standby passage portion 75 is formed as a downwardly inclined path in a direction away from the working passage portion 76, and the detection pin 71 located in the standby passage portion 75 moves to the tip of the standby passage portion 75 by its own weight. Therefore, unless some external force acts on the detection pin 71, the detection pin 71 does not move over the pin restricting portion 77 and move from the standby passage portion 75 to the action passage portion 76. In addition, the detection pin that has entered the working path portion 76 over the pin restricting portion 77 is configured to fall to the lower end of the working path portion 76 by its own weight.

  On the other hand, FIG. 10 shows details of the guide member 72. The guide member 72 is formed by notching a locking groove 78 into which the tip of the detection pin 71 enters the metal plate, and is fixed to the inner rail 2, and the inner rail 2 is stored in the outer rail 1. When it does, it arrange | positions so that the said pin setting member 70 may be passed.

  The locking groove 78 includes a stopper 79 that engages with the detection pin 71 that has fallen into the action passage portion 76 of the restriction slot 73, and a recovery slope 80 that is formed obliquely upward facing the stopper 79. ing. The stopper 79 has a protruding portion 79a at its upper end so as to be surely engaged with the detection pin 71, and the inner rail 2 is moved to the outer rail 1 in a state where the detection pin 71 is dropped into the action passage portion 76 of the restriction slot 73. When it tries to jump out from the tip, the tip of the detection pin 71 comes into contact with the stopper 79, and the movement of the detection pin 71 is restricted by the stopper 79 and the protrusion 79a.

  Further, the restoration slope 80 is formed as an obliquely upward inclined surface, and the upper end of the restoration slope 80 is located above the standby passage portion 75 of the restriction slot 73. For this reason, when the inner rail 2 is pushed into the outer rail 1 from a state in which the detection pin 71 is locked to the stopper 79, that is, a state in which the detection pin 71 is dropped into the action passage portion 76 of the restriction slot 73, the detection is performed. When the pin 71 is pushed up the action passage portion 76 while contacting the recovery slope 80 and the inner rail 2 is completely stored in the outer rail 1, the detection pin 71 gets over the pin restricting portion 77 and becomes the standby passage portion 75. It is set up.

  Further, in the guide member 72, the guide slope 81 is formed as an upward inclined surface at the tip of the guide member 72 in the pulling direction of the inner rail 2. The guide slope 81 is formed back-to-back with the restoration slope 80. When the inner rail 2 is pulled out from the outer rail 1 in a state where the detection pin 71 has fallen on the action passage portion 76 of the restriction slot 73, the detection pin 71 is The function of guiding to the locking groove 78 of the guide member 72 is exhibited.

  FIG. 11 shows the relationship between the setting state of the detection pin 71 and the guide member 72 in the normal use state of the slide rail unit. 11 to 13 to be described below, only the restriction slot 73, the detection pin 71, and the guide member 72 are shown for the sake of simplicity. As shown in FIG. 11, the detection pin 71 is set in the standby passage portion 75 of the restriction slot 73 in the normal use state of the slide rail unit. Since the standby passage portion 75 is slightly inclined so as to become a lower position as it approaches the tip, the detection pin 71 is maintained at the tip of the standby passage portion 75 unless some external force acts on the detection pin 71. It becomes a state. Further, since the standby passage portion 75 is formed in the retracting plate portion 70b of the pin setting member 70, the tip of the detection pin 71 set in the standby passage portion 75 does not overlap the movement path of the guide member 72, In a state where the detection pin 71 is set in the standby passage portion 75, even if the inner rail 2 is moved with respect to the outer rail 1, the detection pin 71 does not interfere with the guide member 72. For this reason, in the state shown in FIG. 11, the inner rail 2 can be freely moved with respect to the outer rail 1, and for example, the drawer can be freely put in and out of the furniture body.

  FIG. 12 shows a state in which vibration is applied to the slide rail unit due to an earthquake or transportation, and the earthquake-resistant latch structure 7 is applied. First, FIG. 12A shows the positional relationship between the pin setting member 70 and the guide member 72 at the stroke end of the inner rail 2. In this state, the detection pin 71 is placed in the standby passage portion 75 of the restriction slot 73. Is retained. When the vibration acts on the slide rail unit from this state and the vibration reaches a certain level, the detection pin 71 moves over the pin restricting portion 77 and acts from the standby passage portion 75 as shown in the partial diagram b. It moves to the passage part 76 and falls to the lower end of the action passage part 76 by its own weight. When the inner rail 2 jumps out of the outer rail 1 in the right direction of the drawing due to the continuous action of vibration, the guide slope 81 of the guide member 72 abuts against the detection pin 71 falling to the lower end of the action passage portion 76. However, since the retracting passage portion 76a is continuous with the working passage portion 76 and the guide slope 81 is formed as an upward inclined surface, the detection pin 71 is guided when the inner rail 2 continues to move. Along the slope 81, the inside of the retracting passage portion 76a of the restriction slot 73 is lifted upward. And since the upper end of this retreat passage part 76a is located above the restoration slope 80 of guide member 72, if movement of inner rail 2 continues further, as shown in figure c, detection pin 71 will be The upper end edge of the guide member 72 is overcome. Thereafter, the detection pin 71 falls along the recovery slope 80 of the guide member 72 and drops in the retracting passage portion 76 a of the restriction slot 73 and is introduced into the locking groove 78 of the guide member 72.

  When the inner rail 2 further protrudes from this state, as shown in the partial diagram d, the stopper 79 of the guide member 72 hits the detection pin 71 located at the lower end of the action passage portion 76 and the retreat passage portion 76a, and the detection pin 71 returns to the retracting passage portion 76 a of the restriction slot 73. However, a protrusion 79 a is provided at the upper end of the stopper 79 of the guide member 72, and the movement of the detection pin 71 is restrained by the protrusion 79 a, the stopper 79 and the retracting passage 76 a, and is fixed to the inner rail 2. The movement of the guide member 72 is locked. Accordingly, the inner rail 2 is prevented from jumping out of the outer rail 1, and for example, it is possible to prevent an accident in which the drawer is unintentionally jumped out of the furniture body during an earthquake or the like.

  Also in this second embodiment, the standby passage is used to determine how much swing is applied to the slide rail unit when the detection pin 71 is dropped into the action passage portion 76 of the restriction slot 73. It can be arbitrarily adjusted by adjusting the length and inclination angle of the portion 75 or the friction coefficient between the detection pin 71 and the standby passage portion 75.

  On the other hand, FIG. 13 shows an operation of returning the detection pin 71 to the standby passage portion 75 of the restriction slot 73. FIG. 12A shows the same state as FIG. 12D, that is, the state where the movement of the inner rail 2 is locked by the engagement of the detection pin 71 and the guide member 72. At this time, the detection pin 71 is in the restriction slot. 73 is present in the working passage portion 76 or the retracting passage portion 76 a and is introduced into the locking groove 78 of the guide member 72. When the inner rail 2 is pushed into the outer rail 1 from this state, the recovery slope 80 constituting the locking groove 78 of the guide member 72 hits the detection pin 71, and as shown in FIG. As the inner rail 2 moves, the action passage portion 76 is lifted. When the pushing operation of the inner rail 2 with respect to the outer rail 1 is further continued, as shown in the partial diagram c, the detection pin 71 gets over the pin restricting portion 77 and is set in the standby passage portion 75, and finally in FIG. As shown, the guide member 72 passes completely through the pin setting member 70, and the detection pin 71 is held at the tip of the standby passage portion 75. Thereby, the return operation of the detection pin 71 to the standby passage portion 75 is completed.

  In the earthquake-resistant latch structure 5 of the first embodiment described above, the fixed position of the guide member 52 with respect to the inner rail 2 and the fixed position of the pin setting member 50 with respect to the outer rail 1 are strictly matched with the stroke end of the inner rail 2. There was a need to position. However, in the earthquake-resistant latch structure 70 shown in the second embodiment, if the detection pin 71 is set in the standby passage portion 75 of the restriction slot 73, the guide member 72 freely passes through the pin setting member 70. Therefore, the fixed position of the guide member 72 with respect to the inner rail 2 and the fixed position of the pin setting member 70 with respect to the outer rail 1 do not need to be strictly determined as compared with the first embodiment, and accordingly, the position relative to the slide rail unit is not required. The seismic latch structure is easy to install.

  Next, FIGS. 14 and 15 show a third embodiment of the earthquake-resistant latch structure of the present invention, FIG. 14 is a perspective view, and FIG. 15 is a front view.

  In the third embodiment, the earthquake-resistant latch structure of the present invention is incorporated in the gap between the outer rail 1 and the inner rail 2 constituting the slide rail unit, and the pin setting member and the guide are provided outside the outer rail 1 and the inner rail 2. Compared with the first embodiment or the second embodiment in which the members are provided, the installation space of the earthquake-resistant latch structure is significantly reduced.

  In the third embodiment, a restriction slot 100 is provided for the outer rail 1, and a detection pin 101 is held in the restriction slot 100. The restriction slot 100 has a standby passage portion and an action passage portion, and is formed in substantially the same shape as the restriction slot 53 in the first embodiment. Accordingly, when vibration is applied to the outer rail 1, the detection pin 101 set in the standby passage portion moves to the action passage portion by the energy of the vibration and falls to the lower end of the action passage portion by its own weight. .

  On the other hand, the inner rail 2 is provided with a stopper 102. The stopper 102 is formed by cutting a part of the inner rail 2 at a right angle toward the outer rail 1. When the inner rail 2 is pulled out in the direction of arrow A from the outer rail 1, the stopper 102 falls into the action passage portion of the restriction slot 100. The detected pin 101 hits the stopper 102 and the inner rail 2 cannot be pulled out from the outer rail 1 any more. A substantially triangular guide piece 103 is fixed to the inner rail 2 adjacent to the stopper 102 on the side opposite to the arrow A direction with respect to the stopper 102. This guide piece 103 is provided with a guide slope 104 that is obliquely upward with respect to the horizontal direction, and when the detection pin 101 has fallen into the working path portion with the inner rail 2 pulled out from the outer rail 1, The detection pin 101 helps to get over the stopper 102 without hitting the stopper 102, and prevents a trouble that the pulled out inner rail 2 cannot be stored in the outer rail 1.

  A recovery member 105 is fixed to the inner rail 2 at a position slightly spaced from the stopper 102 in the direction of arrow A. The recovery member 105 has a recovery slope 106 that is inclined in the horizontal direction, that is, upward with respect to the pulling-out direction of the inner rail 2, and when the inner rail 2 is pulled into the outer rail 1, The detection pin 101 that has fallen rides on the restoration slope 106, ascends the action passage portion, and is reset to the standby passage portion. The fixing position of the recovery member 105 with respect to the inner rail 2 corresponds to the retracting end of the inner rail 2 when the slide rail unit is in use, and the inner rail 2 is most retracted with respect to the outer rail 1, The detection pin 101 must be reset in the standby passage portion of the restriction slot 100.

  The earthquake-resistant latch structure of the third embodiment is substantially the same as that in which the guide member 52 in the first embodiment is divided into a stopper 102, a guide piece 103, and a recovery member 105, which are arranged inside the inner rail 2. The specific action of the earthquake-resistant latch structure is the same as that of the first embodiment. Therefore, detailed description thereof is omitted here.

  And according to this 3rd embodiment, since the earthquake-resistant latch structure of this invention can be accommodated in the clearance gap between the outer rail 1 and the inner rail 2, ie, the inside of a slide rail unit, it is utilized for furniture etc. The conventional slide rail unit can be easily replaced with the slide rail unit with the earthquake-resistant latch structure of the present invention.

  Next, FIG. 16 is a perspective view showing a fourth embodiment of the earthquake-resistant latch structure of the present invention.

  Also in the fourth embodiment, the earthquake-resistant latch structure is applied to the slide rail unit having the same structure as that of the first embodiment. Therefore, the same reference numerals as those of the first embodiment are given to the slide rail unit in FIG.

  The seismic latch structure 110 of the fourth embodiment has a pin setting member 111 fixed to the outer rail 1, and is held by the pin setting member 111 and the setting position is changed according to the action of shaking on the outer rail 1. And a guide member 113 that is fixed to the inner rail 2 and that engages with the detection pin 112 in accordance with a set position of the detection pin 112.

  FIG. 17 is a side view showing a state in which the inner rail 2 is pulled out from the outer rail 1. The pin setting member 111 is provided with a slot-like restriction slot 114, and the detection pin 112 is inserted into the restriction slot 114. The detection pin 112 is held substantially perpendicular to the pin setting member 111, and a pair of locking rings 112 a are provided on the front and back of the pin setting member 111 so that the detection pin 112 does not fall out of the restriction slot 114. Positioned and fixed.

  The restriction slot 114 includes a standby passage portion 115 and an action passage portion 116 continuous with the standby passage portion 115. The working passage portion 116 extends from the end of the standby passage portion 115 in the direction in which the inner rail 2 is pulled out (in the direction of arrow B in FIG. 17), and extends obliquely upward with respect to the horizontal direction. In other words, the action passage portion 116 is formed as an upward inclined path in a direction away from the standby passage portion 115, and the detection pin 112 is not connected to the action passage portion 116 unless some external force acts on the detection pin 112. The standby passage 115 is set by its own weight without entering.

  On the other hand, the guide member 113 is formed by notching a locking groove 117 into which the tip of the detection pin 112 enters the metal plate, and is fixed to the inner rail 2, and the inner rail 2 is connected to the outer rail 1. The pin setting member 111 is disposed so as to overlap when stored. However, when the detection pin 112 is set in the standby passage portion 115 of the restriction slot 114, the guide member 113 is fixed at a position where it does not interfere with the detection pin 112 even if the inner rail 2 moves.

  The locking groove 117 is notched upward from the lower end edge of the guide member 113, and a stopper 118 and a recovery slope 119 are provided to the guide member 113 by notching the locking groove 117. Yes. The stopper 118 engages with the detection pin 112 and stops the movement of the inner rail 2 when the detection pin 112 exists in the action passage portion 116 of the restriction slot 114. Further, the restoration slope 119 is formed as an inclined surface that is obliquely downward with respect to the horizontal direction, and when the inner rail 2 is pushed into the outer rail 1 from the state in which the detection pin 112 exists in the action passage portion 116 of the restriction slot 114. The restoration slope 119 forcibly pushes the detection pin 112 back toward the standby passage portion 115.

  FIG. 18 shows the relationship between the setting state of the detection pin 112 and the guide member 113 in the normal use state of the slide rail unit. 18 to 20 described below, only the pin setting member 111, the detection pin 112, and the guide member 113 are shown for simplification. As shown in FIG. 18, in the normal use state of the slide rail unit, the detection pin 112 is set in the standby passage portion 115 of the restriction slot 114 by its own weight. 18 shows a positional relationship between the detection pin 112 and the guide member 113 at a state where the inner rail 2 is completely stored in the outer rail 1, that is, at a stroke end of the inner rail 2. FIG. Even if the inner rail 2 and the guide member 113 fixed to the inner rail 2 are moved to the right in the drawing from this state and the inner rail 2 is pulled out from the outer rail 1, the detection pin 112 is guided by the guide b as shown in FIG. There is no interference with the member 113. For this reason, in the state where the detection pin 112 is set in the standby passage portion 115, the inner rail 2 can be freely moved with respect to the outer rail 1 as shown in the partial drawings c and d. The drawer can be freely put in and out of the main body.

  FIG. 19 shows a state in which the vibration is applied to the slide rail unit due to an earthquake or transportation and the earthquake-resistant latch structure 110 is operated. When the slide rail unit is shaken by the vibration and the acceleration in the direction in which the inner rail 2 jumps out of the outer rail 1 (the right direction in the drawing) occurs, the detection pin 112 resists its own weight from the standby passage portion 115 as shown in FIG. It moves and begins to climb up the working channel part 116. If the acceleration in the same direction continues to act as it is, the detection pin 112 further proceeds through the action passage portion 116 as shown in the partial diagram b. Further, since the inner rail 2 moves relative to the outer rail 1 due to this acceleration, the guide member 113 fixed to the inner rail 2 also moves relative to the pin setting member 111 fixed to the outer rail 1. Become. When the detection pin 112 is set in the action passage portion 116 of the restriction slot 114, the stopper 118 of the guide member 113 interferes with the detection pin 112. Therefore, if the acceleration in the same direction acts as it is, as shown in FIG. The stopper 118 abuts against the detection pin 112, and the movement of the inner rail 2 relative to the outer rail 1 is locked by the engagement between the tip of the detection pin 112 and the stopper 118.

  On the other hand, FIG. 20 shows a state in which a swing in the opposite direction to FIG. 19 acts on the slide rail unit. From the state in which the protrusion of the inner rail 2 is locked by the engagement of the detection pin 112 and the stopper 118 (see diagram a), the swing in the direction in which the inner rail 2 is pulled into the outer rail 1 (left direction in the drawing) is a slide rail. When acting on the unit, the inner rail 2 moves with respect to the outer rail 1 due to the acceleration of the shaking, and the engagement state between the detection pin 112 and the stopper 118 is released as shown in FIG. As a result, the detection pin 112 starts to move down the action passage portion 116 to the standby passage portion 115. Further, since the inner rail 2 is drawn into the outer rail 1 by the acceleration, the recovery slope 119 of the guide member 113 presses the detection pin 112 existing in the action passage portion 116 toward the standby passage portion 115, so that the detection pin 112 is immediately reset from the working passage portion 116 to the standby passage portion 115 (see the partial diagram c).

  For example, when an earthquake occurs, in the earthquake-resistant latch structure 110 shown in the fourth embodiment, the engagement operation shown in FIG. 19 and the release operation shown in FIG. 20 repeatedly occur every time the direction of shaking changes. This makes it possible to prevent an accident in which the drawer is unintentionally jumped out of the furniture body during an earthquake or the like. On the other hand, if the shaking is stopped and the inner rail 2 is stored in the outer rail 1, the detection pin 112 is always reset to the standby passage portion 115 by its own weight, so that the inner rail 2 can be moved without performing a special releasing operation. It can be pulled out from the outer rail 1.

  In the earthquake-resistant latch structure of the fourth embodiment, the detection pin 112 is set from the standby passage portion 115 to the action passage portion 116 in accordance with the acceleration of the vibration acting on the slide rail unit. By adjusting the angle or the coefficient of friction between the detection pin 112 and the action passage portion 116, it is possible to arbitrarily adjust how much the shaking is applied to the seismic latch structure.

  The preferred first to fourth embodiments of the present invention have been described above, but the technical scope of the present invention is not limited to these embodiments. For example, in the above-described embodiments, the present invention is applied to the outer rail and the inner rail of the slide rail unit. However, an earthquake-resistant latch structure may be provided directly on the drawer or sliding door guided by the slide rail unit. Is possible. In this case, the function of the earthquake-resistant latch structure of the present invention can be obtained by directly providing the restriction slot and the detection pin on the furniture body and the stopper on the drawer.

  FIGS. 21 and 22 show a fifth embodiment in which the earthquake-resistant latch structure of the present invention is applied to a hinged door of furniture. The furniture 120 includes a box-shaped furniture main body 121 having a storage space and a door 122 that closes an opening of the furniture main body 121. The door 122 is attached to a side wall of the furniture main body 121 by a hinge. ing. Accordingly, the door 122 can rotate with respect to the furniture body 121. Reference numeral 123 in the drawing is a magnet member for maintaining the closed state of the door 122, and reference numeral 124 is a steel plate that is attracted to the magnet member 123.

  For example, by providing the furniture body with the pin setting member 50 in the first embodiment and the door with the guide member 52, the earthquake-resistant latch structure of the present invention can be applied to the hinged door of furniture. Is possible. Even when the present invention is applied to the hinged door in this way, when the vibration such as an earthquake acts on the furniture body 121 as the fixing member and the door is slightly opened, the restriction slot 53 When the detection pin 51 held on the movable member is movable from the standby passage portion to the working passage portion and the detection pin is actually set to the working passage portion by vibration, the stopper 59 of the guide member 52 is engaged with the detection pin. The swing of the door with respect to the furniture body 121 is locked. Thereby, it is possible to prevent an object from unintentionally popping out from the storage space of the furniture body 121.

  In addition, even when the detection pin 51 is mistakenly set in the action passage portion of the restriction slot 53, the door 122 is completely closed with respect to the furniture main body 121 so that the detection pin 51 is attached to the door 122. Since the guide member 52 thus set resets the detection pin 51 to the standby passage portion of the restriction slot 53, the normal use state can be easily continued if the vibration converges.

Claims (6)

Provided between the fixed member (1) and the movable member (2) that is movable relative to the fixed member (1), and restricts the movement of the movable member (2) relative to the fixed member (1) during the action of vibration. An earthquake-resistant latch structure,
A restriction slot (53) provided in the fixing member (1), which is composed of a standby passage part (55) and an action passage part (56) extending in a direction crossing the standby passage part (55), and the restriction slot ( 53) is movably provided within the restriction slot (53) and protrudes toward the moving member (2), and acts from the standby passage portion (55) in response to vibration acting on the fixed member (1). The detection pin (51) that moves to the passage portion (56) and the detection pin (51) that is provided in the moving member (2) and set in the standby passage portion (55) of the restriction slot (53) An anti-seismic latch structure comprising: a stopper (59) that engages only with a detection pin (51) set in the action passage portion (56) without being engaged. 2. The earthquake-resistant latch structure according to claim 1, wherein the action passage portion (56) of the restriction slot (53) extends obliquely upward with respect to the horizontal direction from the end portion of the standby passage portion (55). The earthquake-resistant latch structure according to claim 1, wherein the action passage portion (56) of the restriction slot (53) extends downward from an end portion of the standby passage portion (55). In the moving member (2), the standby passage portion is moved by using the movement of the moving member relative to the fixed member (1) to the detection pin (51) moved to the action passage portion (56) of the restriction slot (53). 4. The earthquake resistant latch structure according to claim 2, further comprising a restoration slope (60) to be reset to (55). The standby passage portion (55) of the restriction slot (53) is provided to be inclined with respect to the horizontal direction, and the detection pin (51) set in the standby passage portion passes through the standby passage portion (55) by its own weight. 4. The earthquake-resistant latch structure according to claim 3, wherein the earthquake-proof latch structure moves toward an end opposite to the working passage portion (56). The outer rail (1) and an inner rail (2) assembled to the outer rail (1) via a number of balls (3) and capable of translational movement freely with respect to the outer rail. The regulation slot (53) of the earthquake-resistant latch structure according to claim 1 is provided in (1), while the stopper (59) of the earthquake-resistant latch structure according to claim 1 is provided in the inner rail (2). A slide rail unit.

Images