JP2006002375A - Earthquake-proof latch - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an earthquake-proof latch provided with a proper damper in any case against closing force of a hinge for closing a door forcedly. <P>SOLUTION: This earthquake-proof latch is constituted in such a way that it is composed of a holder part B forming two damper mounting parts 7, 7 for mounting dampers 13, 13 detachably and two earthquake-proof latch parts A, A for locking a door of furniture by earthquake shock, two earthquake-proof latch parts A, A are arranged in parallel, the damper mounting parts 7, 7 are arranged on both sides in the direction of width of the earthquake-proof latch parts A, A arranged in parallel, the holder part B is mounted in the earthquake-proof latch parts A, A arranged in parallel, and two of the plurality of dampers 13, 13, ... having resistance force for damping in accordance with closing force of the door 21 of the furniture at installation site are mounted in mounting holes 7b, 7b of both damper mounting parts 7, 7 in the holder part B. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention prevents furniture doors such as chests, cupboards, and book shelves from opening suddenly due to the impact against an earthquake, and buffers the impact that occurs when the door is closed during the closing operation of the door. The present invention relates to an earthquake-resistant latch that can mount a damper very easily.

  Conventionally, in furniture that has doors that swing and open horizontally, such as chests, cupboards, book shelves, etc., the doors suddenly open due to the shock of the vibration at the time of an earthquake, and the stored items pop out to the outside, This becomes a secondary disaster and puts people at risk. Various earthquake-resistant devices have been developed to prevent furniture doors from opening suddenly due to an impact caused by an earthquake. Among such earthquake-resistant devices, there are various types that utilize the rolling of a sphere due to an impact during an earthquake. This is because the sphere in a stationary state rolls by detecting the vibration at the time of the earthquake, and the actuated member incorporated in the earthquake resistant device moves following the movement of the sphere by the movement due to the rolling. It is set and the actuated member is locked with a locking member mounted on the door of the furniture. As a result, the furniture door can be locked in the closed state, and the situation where the door suddenly opens during an earthquake can be prevented.

  A seismic device that uses the rolling of a sphere works by sensitively detecting the shaking of the earthquake, so there is an advantage that the door of the furniture can be surely locked in the event of an earthquake. Even an earthquake of a large scale can be sensitively sensed and can roll and lock. As a result, even if the earthquake is less than an impact that does not open the furniture door, the lock will be applied, and the lock must be released one by one, which may be inconvenient. This is not limited to shaking caused by an earthquake, and even if it moves only slightly to change the location of furniture, the seismic device may be locked. It becomes even more troublesome.

  In addition, in furniture, there is a hinge equipped with an elastic body such as a spring or a leaf spring for forcibly urging the door in the closing direction to close the door. When such a hinge is used, the door can be securely closed to the furniture body, but if the elastic force of the elastic body built in the hinge is too strong or the door is light, the door When it closes, it may collide with the furniture body vigorously.

In particular, the swing speed is maximized at the moment when the door closing operation is completed, and the door swings again in the opening direction due to the reaction when the door is closed. In such a case, there is a possibility that an impact will occur at the moment when the door is closed, and the lock of the earthquake-resistant device will malfunction. In order to prevent this, as shown in Patent Document 1, there is one provided with a damper.
JP2003-172060

  In contrast to the hinges that apply a closing force to the door as described above, there are dampers with various resistances that are attached to furniture, and the appropriate ones must be used according to the closing force of the door. I must. That is, when the resistance force of the damper is too small or too large with respect to the closing force due to the elasticity of the hinges, none of them is useful for shock buffering. In particular, if the resistance force of the damper is too great, the door will not be completely closed, and the door will be poorly closed. For this reason, it is necessary to select a damper that has an appropriate resistance force and that can provide a good shock buffer according to the closing force of the door by the hinge.

  In Patent Document 1, a damper is attached to the seismic lock in advance, but there is an inconvenience that it can be used only for furniture provided with a hinge adapted to the resistance of the damper. In other words, a damper is attached to the seismic lock in an assembly factory or the like. For example, even if the seismic lock is taken to the furniture installation site and attached to the furniture, the elastic closing force by the hinge and the damper The balance with the resistance is not always the same. An object of the present invention is to provide a seismic latch equipped with a proper damper in any case against a closing force by a hinge for forcibly closing a door.

  Therefore, the inventor has conducted extensive research to solve the above-mentioned problems, and as a result, the present invention has been developed in accordance with the present invention. The holder portion is formed with two damper mounting portions for detachably mounting the damper, and the door of the furniture by earthquake shock. The two seismic latch portions are arranged in parallel, and the holder portions are arranged in parallel so that the damper mounting portions are arranged on both sides of the parallel seismic latch portions in the width direction. Two of the plurality of dampers having a resistance force to be buffered according to the closing force of the furniture door at the installation site are installed in the mounting holes of the both damper mounting portions of the holder portion. The seismic latch that can be mounted solves the above-described problems.

  Next, in the above-described configuration, the two seismic latch portions arranged in parallel are seismic latches that are bonded and fixed, or the two seismic latch portions arranged in parallel are seismic latch bodies formed as a single body by integral molding. Thus, the above problem is solved. Further, in the above-described configuration, the two seismic latch portions in parallel or the seismic latch body and the holder portion are configured as separate separable members and are integrally mounted at the installation site, and As a result, the above-mentioned problems have been solved.

  Further, in the above-described configuration, the holder portion is composed of a plate-shaped fixed plate portion and a damper mounting portion in which a mounting hole into which the damper cylinder portion is inserted, and the fixed plate portion is The above-described problem is solved by providing an earthquake-resistant latch that is disposed on the upper portion of the latch portion and that allows the fixed plate portion to be fixed to the furniture side together with the earthquake-resistant latch portion. The damper mounting portion of the holder portion has a tubular shape, and the longitudinal direction thereof is a seismic latch that is formed longer than the cylinder portion of the damper, thereby solving the above problems.

  Next, the holder part is composed of two damper mounting parts and two attachment locking parts, and one attachment locking part supports the two seismic latch parts in parallel or the outer surface of the earthquake resistant latch body. And an engaging claw-like portion that engages with reinforcing ribs formed on both sides in the width direction of the earthquake-resistant latch portion, and one attachment locking portion is integrally formed on the side surface of the damper mounting portion. The other mounting locking portion is formed as an earthquake-resistant latch formed at a position separated from the damper mounting portion via an arm-shaped portion, thereby solving the above-mentioned problem.

  The holder portion is composed of a damper mounting portion and a locking block, and the locking block includes two outer locking grooves into which the two parallel earthquake-resistant latch portions or the reinforcing ribs of the earthquake-resistant latch body are inserted. The above-mentioned problems are solved by using an earthquake-resistant latch in which an intermediate locking groove into which an intermediate reinforcing rib formed between the reinforcing ribs is inserted is formed.

  Next, the holder portion for mounting the two dampers, and the two seismic latch portions arranged in parallel to lock the door by seismic impact, or the seismic latch body comprising the two seismic latch portions as a single unit by integral molding, The holder part is integrally formed with the two earthquake-resistant latch parts or the earthquake-resistant latch body arranged in parallel, and the holder part has a plurality of dampers having a resistance force to be buffered according to the closing force of the door of the furniture on the installation site. The above-described problems have been solved by adopting an earthquake-resistant latch that can be attached to one of them.

  According to invention of Claim 1, according to the elastic closing force of the door of the furniture installed in the field, appropriate resistance force from the several damper which has resistance force which can fully buffer this closing force Can be selected and attached to the holder part. In this way, by combining the earthquake-resistant latch and multiple dampers at the furniture installation site, it is possible to easily cope with dampers with various resistances according to the closing force of the hinge with a forced closing force. Can be made.

  Further, when manufacturing the earthquake-resistant latch at the factory, it is possible to appropriately select and assemble the earthquake-resistant latches having various kinds of resistance at the site while preventing unnecessary production. As a result, it is possible to make the anti-seismic latch part very unlikely to malfunction, and it is possible to make the furniture with extremely high impact buffering in the door closing operation. In addition, since two seismic latches are provided in parallel, especially when mounting on a furniture body having a double door type door, there is no hassle of mounting it on both doors. It is extremely simple and quick, and can be performed extremely efficiently. In addition, since the two earthquake-resistant latch portions are provided in parallel, the mounting can be stabilized.

Next, according to the invention of claim 2, since the two earthquake-resistant latch portions A and A are joined and fixed, the handling of the two earthquake-resistant latch portions A and A is extremely simple, and therefore, the assembly to the furniture is performed. Is very simple and efficient. Then, according to the invention of claim 3, the two seismic latch section A, by integrally molding the A, since the single seismic latch body A _0, it is possible to reduce the number of components constituting the seismic latch . It can also be easily assembled into furniture. Furthermore, since the two earthquake-resistant latch portions A and A have a portion that is shared by a part of the structural member such as the frame portion, the cost can be reduced.

  Next, according to the invention of claim 4, since the two seismic latch parts or seismic latch bodies in parallel and the holder part are separable separate members, by integrating them at the installation site of furniture, The holder portion can be mounted on furniture using the type of seismic latch as it is, and the present invention can be configured without wasting the existing seismic latch. Further, if a spare holder part is always provided, even if either the latch part or the holder part is damaged, it can be easily repaired, repaired and replaced.

  Next, according to invention of Claim 5, the said holder part is comprised from the plate-shaped fixed board part and the damper mounting part in which the mounting hole in which the cylinder part of a damper is inserted was formed, Since the fixed plate portion is disposed on the two parallel earthquake-resistant latch portions or the earthquake-resistant latch body, and the fixed plate portion is fixed to the furniture side together with the two parallel earthquake-resistant latch portions or the earthquake-resistant latch body. The portion is sandwiched between two seismic latch portions or seismic latch bodies in parallel with the furniture, so that the most shocked location where the damper is mounted can be strengthened.

  Next, according to the invention of claim 6, the damper mounting portion of the holder portion has a cylindrical shape and the longitudinal direction thereof is longer than the cylinder portion of the damper, so that the damper can be supported in an extremely stable state. Is. Next, according to the invention of claim 7, the two seismic resistances arranged in parallel by the mounting locking portion formed in the holder portion and the mounting locking portion provided in the holder portion via the arm-shaped portion. Since it can be attached to the outer periphery of the latch part or the earthquake-resistant latch body, only the holder part can be attached later to the earthquake-resistant latch part previously attached to the furniture.

  According to an eighth aspect of the present invention, the locking block of the holder portion includes two outer locking grooves into which the reinforcing ribs are inserted, and an intermediate coupling into which the intermediate reinforcing ribs 6 formed between the reinforcing ribs are inserted. It has a very simple shape in which a stop groove is formed, and can be very easily attached to the earthquake-resistant latch portion. Next, according to the ninth aspect of the present invention, the holder part and the earthquake-resistant latch part or the earthquake-resistant latch body are integrally formed, so that the entire earthquake-resistant latch can be made very compact and space saving can be realized.

  Hereinafter, the present invention will be described with reference to the drawings. First, the present invention mainly includes an earthquake-resistant latch portion A and a holder portion B. In actual use, the locked member 22 is added. In the present invention, two earthquake-resistant latch portions A are provided and used in parallel. The earthquake-resistant latch portion A is composed of a housing portion 1, a swing hook portion 2, and a sphere 3. The housing portion 1 is composed of a bottom surface portion 1a, a front side portion 1b, a rear side portion 1c, and left and right compatible upside portions 1d and 1d. As shown in FIGS. 1 (B), 8, 10 (A), etc., these are formed into a substantially rectangular parallelepiped shape, a cubic shape, and the like, and the internal shape also constitutes a substantially rectangular parallelepiped or cubic space. Is formed.

The upper portion of the housing portion 1 is an opening, which accommodates a sphere 3 and a swinging hook portion 2 to be described later, and to which a cap material 4 is attached. Here, as shown in FIG. 3A or 2, the front side portion 1 b of the housing portion 1 has a seismic latch portion A (including a seismic latch body A ₀ described later) together with a holder portion B as a furniture body. The rear side portion 1c is located toward the back side of the furniture body 20 while being attached outward.

Next, as shown in FIGS. 8B and 8C, the swinging hook portion 2 includes a sensing portion 2b and a hook lever portion 2a. Its sensing unit 2b includes a receiving surface 2b ₁ recessed into a flat shape toward a substantially central portion from the outer side to the lower side. Further, a hook lever portion 2a protruding outward from the sensing portion 2b is formed. The hook lever portion 2a includes a hook piece 2a ₁ and a lever portion 2a _2, and the hook piece 2a ₁ is formed at the tip, that is, the end portion of the lever portion 2a ₂ . The hook piece 2a ₁ has a hook shape and is easily hooked to a loop-shaped portion 22a of the locked member 22 described later (see FIGS. 3 and 11). The lever portion 2a ₂ is formed so as to incline slightly upward from the base portion with the sensing portion 2b to the outside and extend outward from the upper end portion in a substantially horizontal shape. As described above, the sensing portion 2b and the hook lever portion 2a are integrally formed rigid bodies.

As shown in FIGS. 11A to 11C, the receiving surface 2 b ₁ of the sensing unit 2 b is disposed so as to contact the sphere 3 disposed on the bottom surface portion 1 a of the housing unit 1. Then, the ball 3 is located in the rest position of the bottom portion 1a, in the state in which receiving surface 2b ₁ and ball 3 are in contact with the sensing portion 2b, the sensing unit 2b and the hook lever portion 2a is in the horizontal state . This horizontal state is a state in which the swinging hook portion 2 is not locked with a locked member 22 described later (see FIG. 11A).

The said front side 1b, FIG. 8 (A), the as shown in FIG. 11, the cutting portion 1b ₁ is formed, on the outer hook lever portion 2a of the pivot hook portion 2 to be described later from the housing portion within 1 It is a part for protruding. The cut portion 1b ₁ is formed in a substantially rectangular shape, and the swing operation of the hook lever portion 2a of the swing hook portion 2 is smoothly performed. In addition, bearing grooves 1h and 1h serving as a swinging center portion of the swinging hook portion 2 are formed on the compatible upward side portions 1d and 1d and closer to the front side portion. The bearing grooves 1h, 1h are formed in a substantially U shape, and the lower ends of the bearing grooves 1h, 1h are arcuate end portions, and swing hook portions to be described later are formed on the arcuate end portions. Two pivot projections 2c are rotatably mounted. The position of the arcuate end portion is a substantially intermediate position in the height direction of the rising side portion.

  At the upper end portion of the front side portion 1b of the housing portion 1 and at both side end portions in the width direction, as shown in FIGS. 1B and 8, two fixing support portions 1e are projected so as to protrude forward. , 1e are formed. The fixing support portions 1e and 1e are portions for mounting the housing 1 on the furniture main body 20 side (storage side) such as a chiffon and a shelf. The fixing support portions 1e and 1e include screws or the like. Through holes 1f and 1f for the fixing tool are formed. Further, as shown in FIGS. 8A and 8D, reinforcing ribs 5 and 5 are formed between the fixing support portions 1e and 1e and the front side portion 1b and the compatible ascending side portions 1d and 1d. In some cases, the housing 1 can be attached to the furniture body 20 more firmly.

  Further, intermediate reinforcing ribs 6 are formed between the reinforcing ribs 5 and 5 as shown in FIGS. 8A and 8D. These ribs are formed in a plate shape, and also serve to prevent inadvertent contact with anything other than the locked portion of the door on the front side of the earthquake-resistant latch portion A. Further, a stepped portion is formed at the opening portion located at the upper portion of the housing portion 1, and a cap material 4 to be described later is attached to the opening portion in an appropriate state (see FIG. 8A). .

  As shown in FIGS. 1 (B) and 2 (B), two seismic latch portions A are arranged in parallel, and the housing portions 1, 1 of the two seismic latch portions A, A are joined to each other. . Specifically, the opposing rising side portions 1d and 1d of the two casing portions 1 and 1 are bonded and fixed together with an adhesive or the like. Alternatively, the compatible ascending side portions 1d and 1d may be bonded and fixed using a fixing tool such as a screw. In addition, as shown in FIG. 12, the two earthquake-resistant latch portions A and A can be used in combination with the holder portion B described later by simply adjoining the two housing portions 1 and 1 without joining them together. is there.

Further, there are two seismic latch portions A and A that are integrated into a single unit (see FIGS. 9 and 10). A material obtained by this alone hereafter seismic latch body A _0. In this earthquake-resistant latch body A ₀ , the housing member A ₁ is integrally formed so that the two housing parts 1, 1 become a single body. More specifically, housing member A ₁ that this alone is composed of a bottom portion 1a, the front side 1b, the rear side 1c and the left and right both upstream side 1d, and 1d, FIG. 10 (A), the As shown to (B), the substantially rectangular parallelepiped bowl shape is formed, and the space shape inside the casing part 1 is also formed in the substantially rectangular parallelepiped shape.

The top of the housing member A ₁ is an opening portion, the two oscillating hook 2,2 and two spheres 3, 3 are housed, in which cap member 4 is mounted. Its housing member A _1, the partition wall portion 1g is formed. The partition wall portion 1g is for partitioning the interior of the housing member A ₁ into two equally sized rooms [FIG 10 (C) refer to Fig. That is, it can be said that the earthquake-resistant latch body A ₀ is obtained by joining two earthquake-resistant latch portions A and A in parallel through the partition wall portion 1g. Moreover, the fixing supporting portion 1e, among 1e, are those formed between the two pivot hook portions 2, than those formed on both sides in the width direction of the seismic latch body A _0, width Will be formed widely. In addition, one or two or more through holes 1f are formed in the fixing support portion 1e located at the central portion, and four are preferable from the viewpoint of mounting strength.

Each room partitioned by the partition wall portion 1g of the housing member A _1, as mentioned above, cut to the hook lever portion 2a of the swing hook portion 2 protrudes outward from the housing portion within 1 A portion 1b ₁ is formed, and bearing grooves 1h and 1h serving as a swing center of the swing hook portion 2 are formed (see FIG. 10). Cap member 4 for covering the opening of the seismic latch body A ₀ is there as one member capable of covering the two chambers partitioned by the partition wall 1g, alone each room as in the first type The two cap materials 4 and 4 may be covered with

  Next, there are various types of holder parts B. As shown in FIGS. 1 (A) and 1 (B), the first type has two damper mounting parts 7, 7 and one sheet. And the fixed plate portion 8. The holder portion B is formed from a synthetic resin such as plastic. The fixed plate portion 8 is formed in a substantially flat plate shape and is disposed on the cap material 4 at the upper portion of the earthquake-resistant latch portion A. The fixing plate portion 8 is formed with about 2 to 4 fixing through holes 8a, 8a,.

  The distance between the fixing through holes 8a, 8a,... Is equal to the distance between the through holes 1f, 1f,. Further, both the damper mounting portions 7 are formed at the end portions in the width direction of the fixed plate portion 8 and on the lower surface side. Each damper mounting portion 7 has a substantially cylindrical shape or a tubular shape as a whole, and a mounting hole 7b is formed in the mounting cylindrical portion 7a. The mounting hole 7b is a substantially cylindrical passage hole into which the cylinder portion 13a of the damper 13 is inserted as shown in FIGS. 1 (A) and 1 (D). The length of the damper mounting portion 7 in the longitudinal direction is substantially equal to the length of the cylinder portion 13a of the damper 13 or longer than the cylinder portion 13a.

As a result, the entire cylinder portion 13a of the damper 13 is supported along the longitudinal direction. As shown in FIG. 1A, FIG. 2, etc., the holder part B is disposed at the upper part of the earthquake-resistant latch part A and is attached to the opening side of the ceiling inside the storage of the furniture body 20. Specifically, the fixed plate portion 8 is disposed so as to cover the cap material 4 on the upper portion of the earthquake-resistant latch portion A, and the plurality of fixing through holes 8a, 8a,. The positions of the plurality of through holes 1f, 1f,... Are matched to each other and fixed to the ceiling inside the housing of the furniture body 20 through a fixing tool such as a screw. In this case, the fixing plate portion 8, a structure which is interposed between the seismic latch body A ₀ that ceiling and two seismic latch portion A or alone for parallel furniture body 20.

Further, as shown in FIGS. 2 (A), (B), and FIG. 9 (B), the two damper mounting portions 7 and 7 are arranged on the outer sides of the earthquake-resistant latch portions A and A or the earthquake-resistant latch body A ₀ in parallel. More specifically, the damper mounting portion 7 is disposed near the upper portion of the earthquake-resistant latch portion A or the earthquake-resistant latch body A ₀ . Therefore, the damper mounting portion 7 is located closest to the ceiling of the furniture body 20 as shown in FIG. Thereby, the position of the mounting hole 7b of the damper mounting portion 7 is also close to the ceiling of the furniture body 20, and the damper 13 mounted in the mounting hole 7b can be installed at a position close to the ceiling of the furniture body 20. it can. Thereby, the moment which the damper 13 receives by the closing force of the door 21 exerts on the holder part B can be reduced, and the holder part B can be made durable.

  As shown in FIG. 4 (A), the second type of the holder part B is composed of two damper mounting parts 7, 7, an attachment locking part 9 and an arm-like part 10. As shown in FIG. 4A, the attachment locking portion 9 is formed at a substantially central location in the longitudinal direction of the damper mounting portion 7. The attachment locking portion 9 includes an outer support portion 9a and a locking claw-shaped portion 9b. The locking claw-shaped portion 9b is formed in a substantially folded shape with respect to the outer support portion 9a. Two attachment locking portions 9 are formed on the holder portion B, and one is integrally formed on the damper mounting portion 7 side as described above (see FIG. 4B).

The two damper mounting portions 7 and 7 are connected and formed via the arm-shaped portion 10. In the mounting locking portion 9 formed on the damper mounting portion 7 side, the outer support portion 9a is formed in a flat concave shape, and the locking claw-shaped portion 9b protrudes from the damper mounting portion 7 side. Is formed. The two damper mounting portions 7 and 7 and the arm-shaped portion 10 surround the rear outer periphery of the casing members A _{1 and 1} of the parallel earthquake-resistant latch portions A and A or the casing member A ₁ of the earthquake-resistant latch body A _0. It is fixed (see FIG. 4B).

  The mounting locking portion 9 is locked so as to sandwich the reinforcing rib formed on the housing portion 1 between the outer support portion 9a and the locking claw-shaped portion 9b, and the holder portion B is seismic latch Mounted on part A. Here, the holder portion B is extremely strong with respect to the earthquake-resistant latch portion A by further strengthening the clamping force with respect to the reinforcing rib by the outer support portion 9a and the locking claw-like portion 9b of the mounting locking portion 9. Can be fixed to.

  Next, as a third type of the holder part B, as shown in FIG. 5 (A), it is composed of two damper mounting parts 7 and 7 and a locking block 11. The damper mounting portion 7 has the same configuration as the first and second types. As shown in FIGS. 5 (B), 6 (A), 6 (B), etc., the locking block 11 has a vertical direction between the reinforcing ribs 5, 5 and the intermediate reinforcing ribs 6, 6,. The outer locking grooves 11a, 11a into which the reinforcing ribs 5, 5 are inserted, and the intermediate locking grooves 11b into which the intermediate reinforcing ribs 6, 6,. have. The outer locking grooves 11a and 11a and the intermediate locking groove 11b are formed to be staggered in the vertical direction, and the reinforcing ribs 5 and 5 and the intermediate reinforcing rib 6 are connected to the seismic latch portion A and the front side. It is fixed so as to be inserted.

  That is, in the middle of the locking block 11, it is supported by the intermediate reinforcing rib 6, and the holder portion B in a very stable state by inserting the reinforcing ribs 5, 5 into the outer locking grooves 11a, 11a on both sides thereof. Can be installed. As a modification of the third type holder portion B, as shown in FIGS. 7 (A) and 7 (B), outer locking projections 12 and 12 are formed near the locations where the outer locking grooves 11a and 11a are formed. Sometimes. The outer stopper protrusions 12 and 12 are engaged with the rear end edge in the front-rear direction of the reinforcing rib to make it difficult for the holder part B to come off the earthquake-resistant latch part A. The first to third types of holder portions B described above are configured as separate members separable from the earthquake-resistant latch portion A. Thus, by making the seismic latch part A and the holder part B separate members that are separable, the seismic latch part A and the holder part B can be integrated and installed at the installation site. The holder part can be attached to the furniture using the conventional type earthquake-proof latch as it is, and the holder part B can be attached using the existing earthquake-proof latch. In this way, the present invention can be configured without wasting existing seismic latches and the like.

Next, as the fourth type of the holder B, which are integrally formed on both sides in the width direction position of the housing member A ₁ of Seismic latch unit A, the housing section 1 or seismic latch body A ₀ of A the parallel It is. The damper mounting portion 7 is formed in a substantially rectangular parallelepiped cylindrical shape, and the mounting hole 7b is formed as described above. The damper mounting portion 7 is integrally formed on the side surface portion of the earthquake-resistant latch portion A (see FIGS. 13A and 13B) or integrally formed on the lower surface side of the bottom portion 1a of the casing portion 1. [See FIGS. 13C and 13D].

  On the inner periphery of the opening of the mounting hole 7b of the damper mounting part 7 of the holder part B, there is a case where a flat receiving surface 7c formed in a concave shape is formed [FIG. 1 (D), FIG. (See (B), FIG. 6 (A), etc.)]. On the flange receiving surface 7c, the flange portion 13c formed on the cylinder portion 13a of the damper 13 is appropriately arranged. That is, it serves as a stopper surface for inserting the damper 13 on the damper mounting portion 7 side into the mounting hole 7b in an appropriate state.

  Next, the damper 13 is comprised from the cylinder part 13a, the piston part 13b, and the collar part 13c, as shown to FIG. 1 (A), (D). The flange portion 13c is formed around the entrance / exit side of the piston portion 13b of the cylinder portion 13a, and fits on the flange receiving surface 7c formed around the opening of the mounting hole 7b of the damper in the holder portion B described above. It has become. A viscous fluid and a spring material are provided in the cylinder portion 13a, and the piston portion 13b is elastically operated by the flow of the fluid and the elasticity of the spring. The damper 13 usually has three types of resistances of “large”, “medium”, and “small” as shown in FIG. 1 (A), FIG. 5 (A), etc. ]. Then, the three types of dampers 13 are selected at the furniture installation site, and the optimal one is used by inserting the cylinder part 13a into the mounting hole 7b of the damper mounting part 7 of the holder part B. is there.

The present invention, as described above, parallel to seismic latch unit A, but those composed of an A (including seismic latch body A ₀₎ and the holder section B, seismic latch unit A to the parallel, A ( The earthquake-resistant latch body A ₀ ) may be other than the type using a metal sphere as described above. As long as the holder part B can be mounted on any type of seismic latch, the holder part B can have any shape other than the two seismic latch parts A and A or the seismic latch body A _{0 in} parallel in the above embodiment. This is also the seismic latch portion A or seismic latch body A ₀ in the present invention.

  The door 21 of the furniture body 20 is opened and closed by a hinge. The hinge of the door 21 is forcibly closed with respect to the door 21, and a closing force is applied to the door 21. The closing force of the door 21 is urged in the closing direction by an elastic member such as a spring incorporated in the hinge. That is, when the door 21 is moved in a closing direction over a certain range, the door 21 is forcibly closed by the elastic member incorporated in the hinge. There is a slide hinge as such a hinge. The closing force is a force when the furniture body 20 or the damper collides with the closing force. This closing force varies depending on the elastic force of the elastic member incorporated in the hinge. In particular, when the closing force is large, a large impact is applied when the door 21 collides with the furniture body 20, and the door 21 is locked (see FIGS. 11B and 11C).

  A plurality of dampers 13, 13,... Having various resistances are provided according to the various closing forces of the door 21 described above. These dampers 13, 13,... Are selected so that they can absorb the impact at the time of collision of the door 21 in the best condition against the closing force by the hinges attached to the furniture door 21 at the installation site. Then, the selected damper 13 is attached to the holder part B. In the present invention, as described above, in the site where the furniture is installed, the earthquake-resistant latch is mounted on the furniture body 20 and the most suitable damper among the plurality of dampers is mounted according to the closing force of the door 21. Thus, the door 21 of the furniture can be opened and closed very well, and earthquake countermeasures can be taken. In general, the damper 13 is preferably provided with three types of resistance, “large”, “medium”, and “small” because selection can be easily performed.

The to-be-latched member 22 is comprised from the loop-shaped part 22a and the attachment fixing | fixed part 22b, as shown to FIG. 3 (B). The locked member 22 is made of a metal material, but may be made of synthetic resin as long as it has excellent strength. The attachment fixing portion 22b is a portion that is fixed to the door 21 via a fixing tool such as a screw. Further, the loop portion 22a, hooks 2a ₁ of the pivot hook portion 2 is a portion which can be locked [FIG 11 (B), (C) refer to Fig.

In order to attach the seismic latch of the present invention to the furniture body 20, the housing part 1 or the housing member A ₁ is attached to the upper end portion of the opening of the furniture body 20. A locked member 22 is fixed to the door 21. As shown in FIG. 11A, the positional relationship between the seismic latch and the locked member 22 is such that when the seismic latch is in a natural state (a state where no earthquake has occurred), the loop portion 22a The swing hook portion 2 is positioned slightly below the hook piece 2a ₁ . Then, the pivot hook portion 2 is swung during the earthquake, the hook lever portion 2a is lowered, by hooks 2a ₁ is engaged with the loop-shaped portion 22a of the engaged member 22, the door 21 is closed In this state, it is locked (see FIGS. 11B and 11C).

The time of the earthquake, the down hook lever portion 2a of the pivot hook portion 2 downward, hooks 2a ₁ is engaged with the engaged member 22, in which the door 21 is locked so as not to open is there. When the earthquake ends, the sphere 3 moves to a low position of the bottom surface portion 1 and the locked state is released.

(A) is a perspective view of a plurality of dampers having a seismic latch having a first type holder portion and a large, medium, and small resistance force, and (B) is a perspective view in which the latch portion and the holder portion are separated. (C) is a vertical side view of the damper mounting portion, and (D) is a vertical side view of the damper mounting portion with the damper mounted. (A) is the principal part perspective view which mounted | wore the furniture main body with the earthquake-resistant latch with a damper, (B) is a front view of (A), (C) is a vertical side view of (A). (A) is a perspective view of the present invention mounted on a furniture body, (B) is a perspective view of a locked member mounted on a door, and (C) is an abbreviated view of a furniture ceiling mounted with the present invention. FIG. (A) is a perspective view in which the second type holder part, the earthquake-resistant latch part, and a plurality of dampers having large, medium, and small resistances are separated, and (B) is the second type holder part being attached to the latch part. FIG. (A) is a perspective view in which a third type holder part and an earthquake-resistant latch part and a plurality of dampers having large, medium and small resistances are separated, and (B) is a third type holder part mounted on the latch part. FIG. (A) is a cross-sectional plan view of a state in which the third type holder part is mounted on the latch part, and (B) is a front view in which the latch part on which the third type holder part is mounted is attached to the upper part of the furniture body. (A) is a perspective view of the modification of a 3rd type holder part, (B) is a principal part cross-sectional plan view of the state which mounted | wore the latch part with the modification of the 3rd type holder part. (A) is an exploded perspective view of the latch portion, (B) is a perspective view of the swing hook portion as viewed from below, (C) is a cross-sectional view taken along line X ₁ -X _{1 in} (B), and (D) the latch portion. FIG. (A) is the perspective view which isolate | separated the 1st type holder part and the earthquake-resistant latching body which united and integrated the two earthquake-resistant latch parts, (B) is a front view of the state with which the furniture main body was mounted | worn. (A) is an exploded perspective view of a seismic latch member, (B) is a plan view of the housing portion, a X ₂ -X ₂ cross-sectional view along a line (C) is (B). (A) is a vertical side view of the latch portion in the natural state, (B) is a vertical side view of the state where the sphere has moved to the rear side, and (C) is a vertical side view of the state in which the sphere has moved to the front side. It is the separated perspective view of the type which uses it combining with a holder part only by making two housing parts adjoin only, without joining. (A) is a perspective view in which a fourth type holder part is integrally formed on the side surface part of the earthquake resistant latch part, (B) is a front view of (A), and (C) is a fourth type holder part being earthquake resistant. A perspective view formed integrally on the bottom lower surface side of the latch portion, and (D) is a front view of (C).

Explanation of symbols

A ... seismic latch part, _A0 ... seismic latch body, B ... holder part, 5 ... reinforcing rib
6 ... Intermediate reinforcing rib, 7 ... Damper mounting portion, 7b ... Mounting hole, 8 ... Fixed plate portion, 9 ... Mounting locking portion, 9a ... Outer support portion, 9b ... Locking claw-shaped portion, 10 ... Arm-shaped portion , 11 ... Locking block,
11a: outer locking groove, 11b: intermediate locking groove.

Claims (9)

  It consists of a holder part in which two damper mounting parts for detachably mounting the damper are formed, and two seismic latch parts for locking the door of the furniture by seismic impact, and the two seismic latch parts are arranged in parallel. The holder parts are mounted on the parallel earthquake-resistant latch parts so that the damper mounting parts are arranged on both sides in the width direction of the parallel earthquake-resistant latch parts, and in the mounting holes of both damper mounting parts of the holder part, A seismic latch characterized in that two of a plurality of dampers having a resistance to buffer in accordance with a closing force of a furniture door at an installation site can be mounted.   2. The earthquake-resistant latch according to claim 1, wherein the two earthquake-resistant latch portions arranged in parallel are bonded and fixed.   2. The earthquake-resistant latch according to claim 1, wherein the two earthquake-resistant latch portions arranged in parallel are formed as a single earthquake-resistant latch body by integral molding.   In Claim 1, 2 or 3, the two seismic latch parts in parallel or the seismic latch body and the holder part are configured as separate separable members, and are integrally mounted at the installation site. Seismic latch characterized by.   5. The fixing plate portion according to claim 1, wherein the holder portion includes a plate-like fixing plate portion and a damper mounting portion in which a mounting hole into which a damper cylinder portion is inserted is formed. Is arranged at the upper part of the earthquake-resistant latch part, and is located so that the fixed plate part can be fixed to the furniture side together with the earthquake-resistant latch part.   6. The earthquake-resistant latch according to claim 5, wherein the damper mounting portion of the holder portion has a cylindrical shape, and the longitudinal direction thereof is longer than the cylinder portion of the damper.   In Claim 1, 2, 3, or 4, the said holder part is comprised from two damper mounting parts and two attachment latching | locking parts, and one attachment latching | locking part is two said earthquake-resistant latch parts in parallel, or The outer support portion for supporting the outer surface of the earthquake-resistant latch body and the engaging claw-like portions for engaging the reinforcing ribs formed on both sides in the width direction of the earthquake-resistant latch portion. A seismic latch characterized in that it is integrally formed on a side surface of the mounting portion, and the other mounting locking portion is formed at a position spaced apart from the damper mounting portion via an arm-shaped portion.   5. The holder portion according to claim 1, wherein the holder portion includes a damper mounting portion and a locking block, and the locking block includes a reinforcement of the two earthquake-resistant latch portions or the earthquake-resistant latch body arranged in parallel. An earthquake-resistant latch comprising two outer locking grooves into which ribs are inserted and intermediate locking grooves into which intermediate reinforcing ribs formed between the reinforcing ribs are inserted.   It consists of a holder part for mounting two dampers, and two seismic latch parts in parallel that lock the door by an earthquake shock, or an earthquake-resistant latch body that consists of two seismic latch parts as a single unit by integral molding, Of the plurality of dampers, which are integrally formed with the two seismic latch parts in parallel or the seismic latch body, and have a resistance force that cushions according to the closing force of the door of the furniture on the installation site. Seismic latch characterized in that one can be attached.

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