JP5336252B2 - Door closure - Google Patents

Description

  The present invention is a sliding door in various storage furniture such as a room partition or a cupboard, a book shelf, a display shelf, a cabinet, etc., and a sliding door having a traveling door pulley mounted on the lower end surface is rapidly brought close to the end on the door closing side. Even if it is made to do, it is related with the door closing tool which can perform favorable door closing operation, the speed of the sliding door just before the door closing end being appropriately decelerated.

  Conventionally, room partition sliding doors are often mounted. If this sliding door is storage furniture with a small frontage, a guide rail is formed above and below the frontage, and a glass plate with an extremely simple structure in which the upper and lower ends are inserted into the guide rail is provided. The same applies to large sliding doors of various storage furniture such as cupboards, book shelves, display shelves and the like. As described above, the partition sliding doors for rooms and the sliding doors used for large furniture are also extremely heavy.

JP 2006-63719 A

  Since such a large sliding door is heavy, once the sliding door starts to move, there is a possibility that it will have a large impact on the frame of the cabinet due to the momentum of the sliding door. Such a state may deteriorate the quality of a high-quality room provided with a partition sliding door or furniture, and may impair the sense of quality. Furthermore, a sliding door used as a room partition is required to be quiet in operation, and as described above, there is a risk of having a large impact and coming into collision with the door stop. Is not appropriate in a high-grade room. In addition, when trying to prevent the door closing collision state at the door closing side end of the sliding door as described above, the momentum of the sliding door closing operation will be reduced as much as possible. It tends to be incomplete.

  This also causes the furniture quality to deteriorate. In addition, in the case of having a buffer function in the door closing operation of the sliding door, the device is often increased in size, and therefore the door closing device is exposed to the outside of the sliding door device, and an extra space is required. Appearance will also be impaired. In Patent Document 1, there is a disadvantage that the door closing device is exposed to the outside of the sliding door device, an extra space is required, and the appearance is also impaired. Furthermore, the closer is required for each of the left and right sides of the sliding door, and has the disadvantage of being expensive. When opening the sliding door, depending on the position of the handle, a moment is applied to the sliding door in the moving direction, and the sliding door may be inclined with respect to the guide rail, and the opening / closing operation may be difficult to stabilize.

  In addition, when attaching the door closure to a sliding door device of furniture, if you accidentally touch a movable part such as a hook, it will operate unnecessarily, making it difficult to work during assembly work. is there. In addition, there is a sliding door device of this type that is not equipped with a door closing device from the beginning. Therefore, opening and closing of the sliding door must be performed with care by the person who performs the opening and closing. Therefore, after the construction of the sliding door device, there also occurs a situation in which the door closing tool must be mounted after that. However, in Patent Document 1, it must be performed together when constructing the sliding door device, and if it is to be attached to the sliding door device later, the construction becomes extremely troublesome.

  For this reason, the problem (technical problem or purpose) to be solved by the present invention is a door closing device that appropriately reduces the speed of the sliding door at the end of the door closing to improve the operation at the time of opening and closing the sliding door. Is to be mounted anytime after the construction of the sliding door device, and the mounting thereof can be realized extremely easily and efficiently.

In view of the above, the inventor has intensively and researched to solve the above-mentioned problems, and as a result, the invention of claim 1 is made up of a rod-like casing having locking grooves on both ends in the longitudinal direction, a cylinder portion, and a piston rod. A buffer damper, a hook member pivotally supported at the base end of the cylinder part and the piston rod tip, a tension elastic body provided between the opposing hook members, the buffer damper, the hook member, and the tension The cover member covers an elastic body and has an upper surface corresponding to a range of movement of the hook member and can be fixed to a sliding door. The rod-shaped casing is attached to the cover member, and the hook member on at least one side with but becomes engaged with the engaging groove of the rod-shaped casing, the guide member is fixed to the middle of the bar casing, the guide portion of the guide member By the cylinder part the cylinder portion is loosely inserted was door閉具characterized by comprising configured slidably with respect to the guide member, the above-mentioned problems are eliminated.

  According to a second aspect of the present invention, in the first aspect, a substantially plate-shaped end mounting piece is formed at both longitudinal ends of the cover member, and the cover member can be attached to the sliding door via the end mounting piece. The above problem was solved by using a door closure. According to a third aspect of the present invention, there is provided the door closing tool according to the first or second aspect, wherein a locking projection formed on the hook member by a tensile elastic body between the hook members is locked in the locking groove. As a result, the above problems were solved.

  According to a fourth aspect of the present invention, in the first aspect of the first, second, or third aspect, the hook member includes a hook portion and a rotation base portion, and the hook portion includes a triangular locking portion and a rising edge. The above-described problem has been solved by providing a door closing tool in which an abutting portion is formed through a recess and the tensile elastic body is stretched between the rotating base portions of the both hook members. According to a fifth aspect of the present invention, in the first, second, third, or fourth aspect, the hook member is pivotally supported by a mounting member provided at a base end of the cylinder portion and a tip end of the piston rod, respectively. The above-mentioned problem was solved by using a door closing tool.

  In the first aspect of the invention, when one sliding door is closed in the left direction or in the right direction, two for closing the left side and one for the right closing are necessary. There is a biggest advantage that can be. Further, the door closing device includes a cover member that can be fixed to the sliding door, and can be attached to the sliding door very easily by the cover member. In addition, the cover member covers the vicinity of both sides in the width direction of the buffer damper, the hook member, and the tensile elastic body, and has an upper surface opened corresponding to the movement range of the hook member. This is a configuration in which a rod-like casing or the like is accommodated, and the whole can be made extremely compact. Therefore, it can be easily mounted in a small space of the sliding door device. As described above, the door closing tool of the present invention can be freely attached to the sliding door at any time after the construction of the sliding door device is completed, and can be attached very easily and efficiently.

Furthermore, the door closing tool of the present invention has a substantially rod shape as a whole, can be configured simply, and can be provided at low cost. Further, as described above, the door closing tool is constituted by the cover member that can be fixed to the sliding door and the rod-like casing, and can be easily attached to a predetermined portion of the sliding door by the cover member. In addition, the cover member protects the main components such as the hook member of the door closing tool and the buffer damper from the outside without being exposed to the outside. That is, these constituent members do not directly contact an object outside the door closing tool, and inconveniences such as failure and damage can be prevented. Furthermore, since the door closing tool is not exposed to the outside from the sliding door, the appearance of the sliding door device can be made orderly and good. In particular, since the cylinder portion is loosely inserted into the guide portion of the guide member and the cylinder portion is configured to be slidable with respect to the guide member, there is an advantage that stable operation can be achieved.

  In the invention of claim 2, end attachment pieces are formed at both ends in the longitudinal direction of the cover member of the door closing tool, and the door attachment of the present invention is extremely adapted to the sliding door by the end attachment pieces. It can be fixed to an appropriate position of the sliding door through a fixing tool such as a screw with simple and good work efficiency. The invention of claim 3 has the same effect as that of claim 1. According to the fourth aspect of the present invention, it is possible to provide a door closing tool that performs a reliable operation as a specific configuration. In the fifth aspect of the invention, the mounting structure can be simplified with respect to the buffer damper or the air damper, and is extremely suitable for mounting the buffer damper or the air damper.

(A) is a schematic front view of the present invention, and (B) is an enlarged view in which a part of the height direction of (A) is omitted and partially cut away. (A) is a front view of a door closing tool in the present invention, (B) is a front view of a partial cross section of the door closing tool, (C) is a perspective view of a main part of the door closing tool mounted on a sliding door according to the present invention, (D) is XC-Xp arrow sectional drawing of (C). (A) is the perspective view of the state which separated the cover member and rod-shaped casing of this invention, (B) is XA-Xa arrow sectional drawing of (A), (C) is Xb-Xb arrow view of (A). Sectional drawing, (D) is an essential part enlarged perspective view of the longitudinal direction one side of the door closing tool in the present invention, (E) is an essential part enlarged perspective view of the longitudinal direction other side of the door closing tool in the present invention, (F). FIG. 4 is a perspective view of a guide receiving member. (A) is a front view with a partial cross-section of the door closure in the present invention, (B) is a plan view with a partial cross-section of the hook member location, (C) is a partial cross-sectional view of the hook member and the casing body, (D) is a perspective view of a hook member location, (E) is a perspective view of the hook member, and (F) is a perspective view with a part of the mounting member cut away. (A) is a principal part enlarged front view of a part of the door closing tool in the present invention, (B) is a plan view with a partial cross section of the hook member part, (C) is a perspective view of the hook member part, (D) And (E) is a perspective view of the mounting member. (A) is a partially cut-away vertical side view of the embodiment of the present invention in which the lower guide traveling part is attached to the lower end of the sliding door, and (B) is the upper guide traveling part attached to the upper end of the sliding door and the upper guide rail is mounted on the ceiling. FIG. 4C is a partially cutaway side view of the embodiment of the present invention mounted in an exposed state from the surface. FIG. 5C is an embodiment in which the upper guide running part is mounted on the upper end of the sliding door and the upper guide rail is embedded in the ceiling. It is the vertical side view of this invention which partially cut away. (A), (B) is the front view made into the partial cross section of the door closing tool in this invention. It is sectional drawing of the cylinder part, piston rod, and pressure adjustment part of a buffer damper. (A), (B), (C) and (D) are action diagrams of the start state of the left closing. (A), (B), (C) and (D) are operation diagrams in the middle of the left closing. (A), (B), (C) and (D) are operation diagrams immediately before the end of the left closing and in the state of the end of the left closing. (A), (B), (C) and (D) are action diagrams of the start state of right closing. (A), (B), (C) and (D) are operation diagrams in the middle of the right closing. (A), (B), (C) and (D) are operation diagrams immediately before the end of the right closing and in the state of the end of the right closing. It is a perspective view of a door closing tool to which a cover member is not attached. (A) is a perspective view of a fixed projection, (B) is an exploded perspective view of the fixed projection, (C) is a cross-sectional view taken along the line Xc-Xc of (B), and (D) is a view taken along the line Xd-Xd of (B). It is sectional drawing. (A) is a front view with a partial cross section of a door closing tool fitted with a hydraulic type as a buffer damper, and (B) is a door closed with a hydraulic type as a buffer damper. The top view made into the partial cross section of a tool, (C) is the principal part expanded sectional view of a buffer damper. (A) The principal part enlarged view which made the partial cross section which shows the structure which joins a piston rod to a mounting member and a stable part, (B) is the state which the component member isolate | separated in joining a piston rod to a mounting member and a stable part. It is the enlarged view made into the partial cross section shown. (A) is the enlarged view which made the partial cross section which shows the structure which prevents the bending of a piston rod, (B) is the principal part enlarged view of (A). (A) is a front view of the present invention in which a door closure is attached to the upper part of a sliding door, (B) is a sliding door in which two doors are fitted with a door closure on the front side, and the other sliding door has a door. It is a transverse plane schematic diagram in the state where a closure was attached to the back side.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. First, the door closing tool A in the door closing device of the present invention is mainly composed of a rod-shaped casing 1, a guide member 2, a buffer damper 3, and a hook as shown in FIGS. The member 4 is composed of a tensile elastic body 5 and a cover member 8. As shown in FIGS. 2 (B) and 3 (A), the rod-shaped casing 1 includes a casing body 11 having a relatively long length in the longitudinal direction and end members 12 and 12. Are formed with groove-like locking grooves 12a, 12a. Specifically, arc-shaped locking grooves 12 a and 12 a are formed as the same groove on both sides of the end member 12. The tensile elastic body 5 naturally includes a metallic coil spring, but also includes an elastic body such as synthetic rubber.

  As shown in FIG. 3 (F), the guide member 2 has a cylindrical guide portion 21 formed on the upper portion thereof, and mounting pieces 22 and 22 formed on the lower side of the guide portion 21. It is attached to the front and rear sides of the rod-shaped casing 1 via the attachment pieces 22 and 22. The guide portion 21 is configured such that the two cylindrical portions 21a and 21a are separated from each other and are linearly adjacent. As shown in FIGS. 2 (B), 3 (A), 7 and 8, etc., the buffer damper 3 includes a cylinder portion 31, a piston rod 32, a pressure adjusting portion 33, and a liquid or gas (air). It is configured. The liquid is a liquid such as oil or gel-like grease, or air (air). In the case of a liquid, as long as it is a viscous liquid, it is not limited to the said material and substance.

The buffer damper 3 is often configured as an air damper 30. The cylinder part 31 has a sealing property so that these liquids do not leak. In the cylinder part 31 in the liquid, a return spring is attached if necessary, and the piston rod 32 may be elastically biased so as to be constantly protruded from the cylinder part 31. is there. The guide member 2 is fixed in the middle of the rod-shaped casing 1, and the cylinder portion 31 is loosely inserted into the guide portion 21 of the guide member 2, and the cylinder portion 31 is configured to be slidable with respect to the guide member 2. ing.

  The pressure adjusting unit 33 is provided with a known configuration that accelerates or slows the flow of liquid. Further, as shown in FIG. 8, the pressure adjusting unit 33 for controlling the air amount is provided with a needle valve 33a and a rotating operation unit 33b capable of adjusting the air amount. 33c and 33d are air holes, and 33e is a cover part through which air can flow. By tightening or loosening the needle valve 33a, the amount of air escape is adjusted to appropriately cope with the impact force.

  When the air damper 30 is configured, the shock absorption can be improved and a product having an excellent buffering effect can be obtained, and the pressure adjusting unit 33 can be easily adjusted. In addition, a stabilizing portion 32a is attached to the tip of the piston rod 32 (see FIGS. 4A, 4B, and 4D). The stabilizing portion 32 a is a substantially rectangular plate-like member, and is provided such that its longitudinal direction is substantially orthogonal to the longitudinal direction of the rod-shaped casing 1. The stabilizing portion 32a is placed on the upper end edge of the rod-shaped casing 1 and slides on the upper end edge, so that the piston rod 32 can move smoothly and satisfactorily.

  The hook member 4 is directly connected to the base end of the cylinder portion 31 (the right end in FIGS. 2A and 2B) and the tip of the piston rod 32 (the left end in FIGS. 2A and 2B). Or it is axially supported 42a via the attachment members 6 and 7, respectively. The hook member 4 includes a substantially U-shaped hook portion 41, a rotation base portion 42, and a locking projection 43. Specifically, as shown in FIG. 4, the hook portion 41 is formed such that a rising contact portion 41c is formed through a recess 41b on the rear side of the triangular locking portion 41a on the tip side. Yes. That is, the triangular locking portion 41a, the recessed portion 41b, and the contact portion 41c are substantially U-shaped. Abutting pieces (fixed protrusions 9 and the like to be described later) that are fixed at appropriate positions are inserted and locked in the recess 41b. The abutted piece is attached in the vicinity of the door closing side of the sliding door 100 in various storage furniture such as cupboards, book shelves, display shelves, cabinets or room partitions.

  Further, the hook member 4 has a mounting member 6 at the base end of the cylinder portion 31 (the right end in FIGS. 2A and 2B) and the tip of the piston rod 32 (FIGS. 2A and 2B). ), The attachment member 7 is rotatably supported on the left side end]. The mounting member 6 is configured by providing inverted T-shaped portions 61, 61 symmetrically with the rear portion being connected by a connecting piece 62. An engaging groove 62a for engaging the end engaging portions 51, 51 on both ends of the tensile elastic body 5 is formed at the center of the connecting piece 62.

  The rotation base portion 42 of the hook member 4 is pivotally supported 42 a on the attachment member 7 at the base end (right end in FIG. 2) of the cylinder portion 31. As shown in FIG. 4 (F), the attachment member 7 is composed of a main body 71 having a U-shaped cross section when viewed from above, and the other side of the tensile elastic body 5 is disposed below the rear wall piece. An engaging groove 71a for engaging the side end engaging portion 51 is formed. The tension elastic body 5 is often used as a tension coil spring 52.

  Further, as shown in FIGS. 4D and 4E, the locking protrusions 43, 43 of the hook member 4 are formed so as to protrude to the left and right sides on the tip side of the hook portion 41. The locking projection 43 is configured to be locked in the locking groove 12 a of the rod-shaped casing 1. In the normal state of the door closing tool of the present invention, as shown in FIG. 2 (B), the tension elastic body 5 is stretched between the mounting members 6 and 7 between the hook members 4 and 4. ing. In the present invention, a very important point is that the door closing tool A has a very simple shape and structure, and can be satisfactorily closed on the right side or the left side with respect to the open / close door, etc. It is an invention that can be satisfactorily handled with few members.

  Next, the cover member 8 is a member that is attached to the rod-shaped casing 1 and can be fixed to the sliding door 100 together with the rod-shaped casing 1. As shown in FIGS. 2 and 3A to 3E, the cover member 8 is formed in a substantially gate-shaped cross section, and is composed of side portions 81 and 81 and an upper surface portion 82 on both sides in the width direction. Side surfaces 81 are integrally formed on both sides of the upper surface 82 in the width direction. The cover member 8 is formed such that its longitudinal direction is substantially equal to the length of the rod-shaped casing 1. Both side surface portions 81, 81 of the cover member 8 are parallel, and sandwich the compatible ascending side portions 11a, 11a of the rod-shaped casing 1 as shown in FIGS. 2 (C), 3 (D), 3 (E) and the like. It has a configuration that can.

  Then, the side surface portions 81, 81 of the cover member 8 are fastened and fixed to the rising side portions 11a, 11a by fixing tools 85 such as screws. A plurality of through holes 81a, 81a,... For the fixing tool 85 are formed in the both side surface parts 81, 81, and the through holes of the cover member 8 are formed in the rising side parts 11a, 11a of the rod-like casing 1. Screw holes 11b, 11b,... Screwed to the fixing tool 85 are formed at positions corresponding to the locations where 81a, 81a,... Are formed (see FIG. 3A). With such a configuration, the cover member 8 is covered from the upper side of the rod-shaped casing 1 and, as described above, the compatible upward side portions 11a of the rod-shaped casing 1 are formed on the side surface portions 81, 81 of the cover member 8 as described above. While holding the pin 11a, the positions of the through hole 81a and the screw hole 11b are aligned, and a fixing tool 85 such as a screw is inserted into the through hole 81a and tightened to the screw hole 11b to cover the rod-shaped casing 1 with the cover member 8. Are bonded and fixed (see FIG. 2D).

  As shown in FIGS. 2, 3 (D), (E), etc., the upper surface portion 82 is formed in the width direction of the buffer damper 3, the hook member 4 and the tensile elastic body 5 mounted in the rod-shaped casing 1. Covers both sides. Further, the upper surface portion 82 is provided with an opening corresponding to the moving range of the both hook members 4 and 4. The opening is referred to as a notch 83 (see FIGS. 2B and 3C and FIGS. 3A, 3B, 3D, and 3E). The notch 83 can receive the tip of the protrusion into which the fixed protrusion 9 enters, and can come into contact with the hook member 4 in the cover member 8, whereby the hook member 4 swings. [See FIG. 9 (C), (D), FIG. 10 (A), (B), etc.)].

  The cover member 8 can protect the hook member 4, the buffer damper 3 and the tension elastic body 5 attached to the rod-shaped casing 1, and the hook member 4, the buffer damper 3 and the tension member 5 when attached to the sliding door device. It can be installed without touching internal components such as the elastic body 5. At both ends in the longitudinal direction of the cover member 8, as shown in FIGS. 2, 3 (A), (D), (E), FIG. 7, etc., substantially plate-like end attachment pieces 84 are formed. Yes.

  The end attachment piece 84 is a part that serves to attach the door closing tool A to the sliding door 100. Specifically, the end attachment piece 84 is formed in a substantially rectangular plate piece, is formed on either one of the side surface portions 81, 81, and the side surface portion 81 It is formed at both ends in the longitudinal direction (see FIGS. 2 and 3). Further, the surface of the end mounting piece 84 is formed to be flush with the surface of the side surface portion 81 [FIGS. 2C, 3A, 3D, 3E]. And FIG. 4 (A)].

  The end attachment piece 84 is provided with an attachment through hole 84a for a fixing tool 86 such as a screw. Then, the door closing tool A is mounted and fixed near the substantially upper end position or the substantially lower end position in the height direction of the sliding door 100 via the end attaching piece 84 and the fixing tool 86 [FIG. See FIG. 2C and FIG. In the door closing tool A, the cover member 8 may not be mounted (see FIG. 15). In this case, end attachment pieces 12b are integrally formed on the end members 12 at both ends in the longitudinal direction of the rod-shaped casing 1, and the door closing tool A is attached to the sliding door 100 by the end attachment pieces 12b. .

  FIG. 16 shows an embodiment of the fixing protrusion 9. As shown in FIGS. 16A and 16B, the fixed protrusion 9 is composed of a plurality of members, and is composed of a protrusion member 91, a base member 92, and a pressing member 93. The protruding member 91 is a member having elasticity, but is a member that can sufficiently withstand the collision with the hook member 4 and is made of hard rubber, synthetic resin, or the like. The protruding member 91 includes a protruding piece 91a and a substrate portion 91b. The protruding piece 91a is formed as a substantially trapezoidal plate piece, and the substrate portion 91b is a small piece and is formed at a right angle to the protruding member 91. ing. Further, a stopper 91c is formed on a part of the substrate portion 91b [see FIG. 16B].

  The base member 92 is formed as a substantially rectangular plate, and a substantially long insertion hole 92a is formed along the longitudinal direction thereof. Reinforcing ribs 92b and 92b are formed on both sides in the width direction of the insertion hole 92a, and the reinforcing ribs 92b and 92b are formed in a trapezoidal shape. Furthermore, two screw holes 92d are formed in the base member 92 (see FIG. 16D). The board portion 91b of the protruding member 91 is inserted into the insertion hole 92a of the base member 92, and the stopper 91c abuts on the back surface side of the base member 92 (see FIG. 16C).

  The protruding piece 91a of the protruding member 91 is sandwiched between the reinforcing ribs 92b and 92b. The protruding piece 91a has a larger area than the reinforcing rib 92b, and the protruding piece 91a slightly protrudes from the surrounding of the reinforcing ribs 92b and 92b when the protruding member 91 is mounted on the base member 92. It is like that. The protruding piece 91a is reinforced by the reinforcing ribs 92b and 92b so that the protruding piece 91a can sufficiently withstand an impact when the protruding piece 91a collides with the hook member 4. A fixing tool 94 such as a screw is inserted into the screw hole 92d of the base member 92 and attached to the upper guide rail 102 and the vicinity thereof (see FIG. 6).

  Specifically, when the upper guide rail 102 has a rectangular concave shape provided on the ceiling, the base member 92 of the fixing protrusion 9 is fixed to the ceiling [see FIG. 6 (A)]. Further, in the case where the upper guide rail 102 made of a metal shape is embedded in the ceiling, the base member 92 of the fixing protrusion 9 is similarly fixed to the ceiling [see FIG. 6C]. In the case where the upper guide rail 102 is of a type that is mounted on the ceiling with substantially the entire surface exposed, a bracket 95 is used. The bracket 95 is made of a metal profile having a substantially L-shaped cross section [see FIG. 6B].

  One plate piece of the bracket 95 is fixed to the outer surface of the upper guide rail 102 with a fixing tool such as a screw, and the base member 92 of the fixing projection 9 is fixed to the other plate piece of the bracket 95 with a screw or the like. Are fixed by the fixing tool 94 (see FIG. 6B). Further, in the case of a sliding door device provided with two sliding doors 100, one sliding door 100 is mounted on the front surface side 100c (or the outer surface side), and the other sliding door 100 is mounted on the rear surface side 100d (or the inner surface). (See FIG. 20B).

  The structure which attached the door closing tool A of this invention to the sliding door 100 is demonstrated in FIG. 6 thru | or FIG. The sliding door 100 is equipped with traveling means for traveling in the moving direction. As a specific example of the traveling means, a lower guide traveling unit 104 is attached to the lower end 100 b of the sliding door 100. The lower guide traveling unit 104 is of a door type and is guided by a floor guide rail 103. A circumferential groove 104b is formed at the center in the width direction of the wheel 104a of the lower guide traveling unit 104. The floor guide rail 103 is engaged with the circumferential groove 104b in a loosely inserted state. The upper end 100a of the sliding door 100 is supported by the upper guide rail 102 (see FIG. 6A).

  Further, as another type of traveling means, the sliding door 100 is provided with an upper guide traveling unit 105. The upper guide traveling unit 105 is configured to be able to roll on an upper guide rail 102 provided on a ceiling or a top plate-like material. The upper guide traveling unit 105 is a hang roller type corresponding to the upper guide rail 102, and the sliding door 100 is suspended from the upper guide rail 102 by the upper guide traveling unit 105 mounted on the upper guide rail 102. However, it can move freely in the moving direction. The upper guide traveling unit 105 includes a traveling main body unit 105a and roller units 105b and 105b (see FIG. 6B).

  In the present invention, the configuration of the door closing device of the sliding door in which the door closing tool A is attached to the sliding door 100 will be described with reference to FIGS. 9 to 14 and 20. The door closure A of the present invention is one, as shown in FIGS. 1 and 6, in the partition sliding door 100 in the room or various storage furniture such as a cupboard, a book shelf, a display shelf, and the cabinet sliding door 100. The action that can cope with closing and right closing will be described with reference to FIGS. The left closing action is a case where the left closing portion is brought into contact with the left closing portion in FIGS. 9 to 11 and 20A. There is also a concept of the door closing side and the door opening side, and in FIGS. 9 to 11 and 20, the direction from the right side to the left side is the door closing side, but in the case of FIG. In this specification, it is described as left closed or left closed open, right closed or right closed open because it is a door closed side or a door open side. In FIG. 20, W0 is a free state area that can move to the left and right sides at a free speed (high speed, etc.), and W1 is a low speed area when the sliding door 100 is moved when left or right closed. .

  First, the operation of closing the left will be described with reference to FIGS. As shown in FIG. 9, the sliding door 100 is movable while the locking projections 43 of the left and right hook members 4, 4 are locked in the locking grooves 12 a on the left and right sides of the rod-like casing 1. It has become. A position where the locking protrusion 43 of the hook member 4 is locked in the locking groove 12a is defined as a fixed position. In this case, the left and right sides of the home position are present. Then, the sliding door 100 in the open state moves to the left in FIG. This detailed state is as shown in FIG.

  Next, the hook member 4 comes close to the fixed protrusion 9, and at that moment, the contact portion 41c of the hook member 4 contacts the fixed protrusion 9, as shown in FIGS. 9C and 9D. At this moment, as shown in FIGS. 10A and 10B, the hook member 4 is rotated. At this time, the hook member 4 is engaged with the fixed protrusion 9. That is, the fixed protrusion 9 and the hook member 4 are integrated. Further, at this moment, the load and acceleration of the sliding door 100 are applied, and the hook member 4 is brought into an impact state, and the impact force is buffered by the buffer damper 3. This action will be described in detail.

  This buffering action allows the buffer damper 3 to rapidly reduce the vigorous speed V to the low speed v, and at the same time, the position of the sliding door 100 can be brought closer to the door closing side instantly. In other words, the piston rod 32 contracts by the distance Lx during buffering. In order to change from the state of FIGS. 10 (A) and (B) to the state of FIGS. 10 (C) and (D), a buffering action is made instantaneously (several hundred seconds or less). Briefly, the states of FIGS. 10A and 10B and the states of FIGS. 10C and 10D are performed substantially simultaneously.

  When the piston rod 32 of the buffer damper 3 is pulled into the cylinder portion 31, the liquid or air filled therein becomes the resistance force R, and the elastic force F of the tensile elastic body 5 is reduced. The speed of the member 4 in the door closing direction is decreased, and the member 4 is moved to the rear side of the rod-shaped casing 1. Then, after the low speed v in FIGS. 10C and 10D is reached, the sliding door 100 is moved at the low speed v this time by the elastic force F of the tensile elastic body 5. That is, assuming that the resistance force R by the buffer damper 3 (at a normal speed other than at the time of impact), the force obtained by removing the resistance force R while contracting the piston rod 32 from the elastic force F of the tension elastic body 5 pulls the sliding door 100. Force: P. That is, P = F−R.

  The door is closed at a considerably slow speed v as shown in FIGS. 11A and 11B. In (A) and (B) of FIG. 11, although it is trying to hit the door closing side, it moves further to the left side at a low speed v. Then, as shown in FIGS. 11C and 11D, the left side of the sliding door 100 comes into contact with the door closing side and the movement stops. Also at this time, it is necessary that the piston rod 32 is not completely contracted but remains even for a short stroke. If it is not in this state, the door closing action by the elastic force F of the tensile elastic body 5 does not occur.

  In particular, in the state shown in FIGS. 11C and 11D, the fixing protrusion 9 and the hook member 4 are integrated with each other while the hook member 4 rotates counterclockwise by the elastic force of the tensile elastic body 5 while being integrated. The locking projections 43, 43 of the hook member 4 are slidable while coming into contact with the upper edges of the left and right rising side portions 11a, 11a of the rod-like casing 1, The member 4 is configured so that it cannot be released. In the above left closed state, the right side where the locking projection 43 of the hook member 4 is locked in the locking groove 12a functions as a fixed position. Further, when the hook member 4 urged by the tensile elastic body 5 is not locked in the locking groove 12a, the hook member 4 is configured to be locked to the fixed protrusion 9, and the hook member 4 is movable.

  Next, the operation of releasing the left closing will be described. This is reversed from the state of FIGS. 11C and 11D, as shown in FIGS. 9A and 9B. First, the sliding door 100 is moved rightward from the states of FIGS. As described above, since the force P (= FR) is applied to the sliding door 100 in the left direction, the sliding door 100 is moved in the right direction with a force larger than the force P. Further, while extending the piston rod 32, the state shown in FIGS. 11 (A) and (B) is changed to the state shown in FIGS. 10 (C) and (D), and further from the state shown in FIGS. 10 (C) and (D). It moves to the state of FIG. 9 (A) and (B).

  10 (A) and 10 (B), as shown in FIGS. 9 (C) and 9 (D), the locking protrusion 43 of the hook member 4 is locked to the left side of the rod-shaped casing 1 as shown in FIGS. At the same time as the position of the groove 12a, the locking projection 43 of the hook member 4 rotates counterclockwise and locks into the locking groove 12a on the left side of the rod-shaped casing 1. At this time, as shown in FIG. 2 (B) or FIGS. 9 (A) and (B), the locking protrusions 43 of the hook member 4 are locked in the locking grooves 12a and 12a on the left and right sides of the rod-shaped casing 1. Then, the force P (= F−R) of the door closing device does not work, that is, the sliding door 100 can be suddenly lightened and moved. The state of the sliding door 100 is a state in which the left closing force P (= FR) is released.

  Next, the right closing operation will be described with reference to FIGS. As shown in FIGS. 12A and 12B, the locking projections 43 of the left and right hook members 4 and 4 are held in the locking grooves 12 a on the left and right sides of the rod-shaped casing 1. The sliding door 100 is movable. This state is the same as that shown in FIG. Then, the sliding door 100 in the open state is moved to the right in FIG. This detailed state is as shown in FIG.

  Then, the hook member 4 comes close to the fixed protrusion 9 and at that moment, the contact portion 41c of the hook member 4 contacts the fixed protrusion 9 as shown in FIGS. At this moment, as shown in FIGS. 13A and 13B, the hook member 4 is rotated counterclockwise. At this time, the fixed projection 9 and the hook member 4 are integrated. Further, at this moment, the load and acceleration of the sliding door 100 are applied, and the hook member 4 is brought into an impact state, and the impact force is buffered by the buffer damper 3. This action is the same as the left closing action, but this time the role of the movable member is changed.

  This buffering action allows the buffer damper 3 to rapidly reduce the speed V to a low speed v and simultaneously bring the sliding door 100 closer to the door closing side. In other words, the piston rod 32 contracts by the distance Lx during buffering. Certainly, the piston rod 32 is contracted, but the tip of the piston rod 32 is in a fixed state, and the cylinder portion 31 moves in the guide portion 21. Thereafter, the tip is held in a fixed state. Next, the buffer action is instantaneously (a few hundredths of a second or less) from the state of FIGS. 13A and 13B to the state of FIGS. 13C and 13D. Briefly, the states of FIGS. 13A and 13B and the states of FIGS. 13C and 13D are performed almost simultaneously.

  Then, after the low speed v in FIGS. 13C and 13D is reached, the sliding door 100 is moved at the low speed v by the elastic force F of the tensile elastic body 5. The point is the same as the above-described left closing action. Further, from the state of FIGS. 14A and 14B to the completion of the right closing of the state of FIGS. 14C and 14D, the cylinder portion 31 moves in the guide portion 21 as described above. This is the same as the action of closing left. Therefore, the description thereof is omitted.

  In the state of the right closing operation described above, the left side where the locking projection 43 of the hook member 4 is locked in the locking groove 12a functions as a fixed position. Also, the action of releasing the right closing will be described. This is performed in reverse from the state of FIGS. 14 (C) and 14 (D), as shown in FIGS. 12 (A) and 12 (B). Except for this, it is the same as the above-described left-closing release action, and this description is omitted. The door closing tool of the present invention can be attached to the lower part of the sliding door 100. In this case, the fixing projection 9 protruding from the lower guide rail of the sliding door 100 is provided, and the operation of the sliding door 100 is the same as when the present invention is attached to the upper portion, and the description is omitted.

  17 to 19 show a hydraulic type of the buffer damper 3, and as described above, the cylinder portion 31 is filled with a liquid such as oil or gel grease as the liquid. The cylinder part 31 is stored and used in a cylinder storage case 31a. The cylinder storage case 31a is formed in a cylindrical shape, and the cylinder portion 31 of the buffer damper 3 is fixed and stored therein. The piston rod 32 projects from the cylinder storage case 31a to the outside. As the buffer damper 3, an existing one that is sold (or commercially available) may be used, and in this type, there are various types of shaft diameters of the piston rod 32 from a large diameter to a small diameter. To do.

  When the existing buffer damper 3 is used, the cylinder storage case 31a has a small diameter of the existing cylinder portion 31b, and is not slidably stored in the cylindrical portion 21a of the guide member 2 as it is. Can be used for That is, if the diameter of the cylinder storage case 31a is formed to be smoothly slidable on the cylindrical portion 21a of the guide member 2, the cylinder portion 31b of the existing buffer damper 3 is stored in the cylinder storage case 31a. Thus, the cylinder portion 31b of the existing buffer damper 3 having a number of different diameter sizes can be used.

  A valve member 321 is attached to the piston rod 32 to form an orifice hole 321a, and the flow of liquid is controlled through the orifice hole 321a (see FIG. 17C). The tip part of the piston rod 32 is a part to be joined to the mounting member 7 and the stabilizing part 32a, and the joining structure in the wire-like thing with a particularly small shaft diameter of the piston rod 32 has the following structure. Exists. For the piston rod 32, a first joining member 34, a second joining member 35, a retaining ring 36 and a washer 37 are used (see FIGS. 17A, 17B, and 18). The first joining member 34 and the second joining member 35 are each formed in a substantially nut shape having a hexagonal outer shape, and the first joining member 34 has an inner screw portion 34a and an axial direction along the axial direction. A through hole 34b is formed. The through hole 22 is formed with a diameter smaller than the inner diameter of the inner screw portion 34a, and is formed so that the piston rod 32 penetrates.

  As described above, the inner screw portion 34a has an inner diameter larger than that of the through hole 34b. An inner diameter of the inner screw portion 34a is large enough to accommodate the retaining ring 36 and the washer 37. The second joining member 35 is formed with an external screw portion 35a along the axial direction thereof, and a shaft through hole 35b is formed along the axial direction inside the external screw portion 35a. An inner screw portion 35c for joining is formed on the end of the shaft through hole 35b in the axial direction and on the side opposite to the side where the outer screw portion 35a is formed.

  The joining inner screw portion 35c is an inner screw that serves to join the tip of the piston rod 32 to the attachment member 7 and the stabilizing portion 32a with a fixing tool 38 such as a screw. A circumferential groove 32b is formed in the piston rod 32 along the circumferential direction of the tip portion. Then, after inserting the shaft portion of the piston rod 32 into the through hole 34b of the first joining member 34 and the one washer 37, the retaining ring 36 is fitted into the circumferential groove 32b of the piston rod 32. The

  Then, another another washer 37 is prepared, the piston rod 32 is inserted, and the retaining ring 36 is held between the two washers 37, 37. In this state, the outer thread of the second joint member 35 is inserted into the inner thread 34a of the first joint member 34 while the tip end portion of the piston rod 32 is slightly inserted into the shaft through hole 35b of the first joint member 34. The part 35a is screwed together. Furthermore, while joining the second joining member 35 and the mounting member 7, the screw part of a fixing tool such as a screw is screwed into the joining internal thread part 35 c of the second joining member 35, The second bonding member 35 is bonded and fixed to the stable portion 32a [see FIGS. 18A and 19B].

  In particular, when the shaft diameter of the piston rod 32 is small, when performing the operation of locking the locking protrusion 43 of the hook member 4 to the locking groove 12a of the rod-shaped casing 1 in the initial setting, Along with the operation of the hook member 4, the piston rod 32 may be bent in the axial direction. Such bending of the piston rod 32 is likely to occur when the piston rod 32 has a diameter as thin as a wire.

  Therefore, the first joining member 34, the second joining member 35, the retaining ring 36, and the two washers 37 serve to connect the tip end portion in the axial direction of the piston rod 32, which is a connection point between the mounting member 7 and the stabilizing portion 32a. As shown in FIG. 19, the piston rod 32 can be made to be extremely difficult to bend. Therefore, in particular, the hook member 4 on the piston rod 32 side is forcibly brought into the position of the locking groove 12a of the rod-shaped casing 1 in order to lock the locking protrusion 43 of the hook member 4 in the locking groove 12a of the rod-shaped casing 1. In the case of setting that needs to be moved, etc., the piston rod 32 itself is reinforced, so that the setting operation can be performed in an extremely stable state.

A ... door closing tool, 1 ... rod-shaped casing, 12a ... locking groove, 2 ... guide member,
3 ... buffer damper, 31 ... cylinder part, 32 ... piston rod, 4 ... hook member,
42 ... Rotating base, 5 ... Tensile elastic body, 8 ... Cover member, 84 ... End attaching piece,
9 ... fixed projection, 100 ... sliding door.

Claims (5)

A rod-shaped casing having locking grooves on both ends in the longitudinal direction, a buffer damper composed of a cylinder portion and a piston rod, a hook member pivotally supported at the base end of the cylinder portion and the tip end of the piston rod, A tension elastic body provided between the hook members, and a cover member that covers the buffer damper, the hook member, and the tension elastic body, and that has an upper surface open corresponding to a movement range of the hook member and can be fixed to the sliding door. The rod-shaped casing is attached to the cover member, and at least one of the hook members is locked in a locking groove of the rod-shaped casing, and a guide member is fixed to the middle of the rod-shaped casing, The cylinder portion is loosely inserted into the guide portion of the guide member, and the cylinder portion is configured to be slidable with respect to the guide member. Door閉具characterized by comprising.   2. The cover member according to claim 1, wherein a substantially plate-like end attachment piece is formed at both longitudinal ends of the cover member, and the cover member can be attached to the sliding door via the end attachment piece. Door closure. The door closing tool according to claim 1 or 2 , wherein a locking protrusion formed on the hook member by a tensile elastic body between the hook members is locked in the locking groove. In the description of any one of claims 1, 2 or 3, wherein the hook member is composed of a hook portion and the rotating base, the hook portion is triangular shaped engaging portion and the rising-shaped contact portion recessed A door closing tool, wherein the tension elastic body is stretched between the rotation bases of the hook members. In the description of any one of claims 1, 2, 3 or 4, wherein the hook member has a characterized by being pivotally supported on a mounting member provided respectively at the base end and the piston rod end of the cylinder portion Door closing tool.

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