JP2008057259A - Door closing implement, and door closing unit of sliding door - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a door closing implement which makes a sliding door forcedly drawn to a door closing-side terminal end by bringing the sliding door close to the vicinity of the door closing-side end of the sliding door, and brings about a proper and quiet door closing operation by properly decreasing the speed of the sliding door immediately before the completion of the closing of the sliding door, and a door closing unit of the sliding door. <P>SOLUTION: An elastic tensile implement 3 in which one end of a linear member 33 is fixed to a proper place on the outer periphery of a drum 31 rotated by a spring 32 is provided in a casing 5, and a reciprocating hydraulic damper 4 for generating resistance T resisting an elastic force F of the spring 32 is provided. The linear member 33 is connected to a sliding member 1 so as to be moved backward from the front in the casing 5, and a hook member 2 is pivotally supported on and connected to the sliding member 1. The hook member 2 is temporarily stopped in a swinging and inclined state only when positioned in the front-side entrance place of the casing 5. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to various storage furniture such as cupboards, book shelves, display shelves, etc., or sliding doors in room partitions and the like, in particular, by bringing the sliding door close to the door closing side end of the sliding door, the sliding door is closed on the door side. A door that can be forcibly drawn to the end portion, and the speed of the sliding door at the end of the door closing can be appropriately reduced to achieve a good and quiet door closing operation, and the operation of the sliding door at the start of opening and closing can be stabilized. The present invention relates to a door closing device for a closing tool and a sliding door.

  Conventionally, there exists a sliding door device as seen in Patent Document 1 below. And, various storage furniture such as cupboards, bookshelves, display shelves, etc. are often equipped with sliding doors equipped with glass windows. If this sliding door is storage furniture with a small frontage, it may have a very simple structure in which guide rails are formed above and below the frontage and the upper and lower ends of the glass plate are inserted into the guide rail. However, in high-quality furniture and high-quality cabinets, the sliding door opening and closing operations are required to be heavy and elegant. In particular, the sliding door becomes large in large furniture, and the weight of the sliding door itself becomes very large.

  In addition, when the sliding door is a large partition sliding door, the weight of the sliding door itself is extremely heavy. Therefore, once the sliding door starts to move, it has a large impact on the storage portion due to its momentum and comes into contact with it. There is a fear. Such a state deteriorates the quality of the house and is not suitable for comfortable operation. 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 causes the quality of the large partition sliding door to deteriorate. Furthermore, in the case of having a buffering function in the moving and storing operation of the sliding door, the device is often increased in size, so that 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.

  The object of the present invention is to bring the sliding door to the door closing side end forcibly by bringing the door close to the door closing side end particularly in a high-quality furniture and cabinet or a room partition, etc. The speed of the sliding door at the moment is appropriately reduced to achieve a good door closing operation, the door closing device is made small, the space for mounting directly on the sliding door guide rail is small, and the sliding door The purpose is to stabilize the operation during opening and closing.

JP 2002-138739 A

  Since such a large sliding door is heavy, once the sliding door starts to move, there is a risk that it will have a large impact on the door closing end due to the momentum of the sliding door. Such a state deteriorates the quality of the furniture and cannot be said to be suitable for high-quality furniture and cabinets. 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. 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. The object of the present invention is to bring the sliding door close to the door closing side end particularly in high-quality furniture and cabinets, so that the sliding door is forcibly drawn to the door closing side end, and the speed of the sliding door is just before the door closing ends. Proper deceleration and good door closing operation, further downsizing of the door closing device, small space for assembly directly into the sliding door guide rail, and stable operation when opening and closing the sliding door The purpose is to let you.

  In view of this, the inventor has intensively studied in order to solve the above-mentioned problems. As a result, the elastic tensioner according to claim 1 is obtained by fixing one end of a linear member to an appropriate position on the outer periphery of a drum portion rotated by a spring. A reciprocating hydraulic damper that is provided in the casing and includes a cylinder housing portion, a piston rod, and a liquid, and that generates a resistance force that resists the elastic force of the mainspring is provided. It is connected to a sliding member so that it can be moved from the front to the rear in the casing, and the hook member is pivotally connected to the sliding member and swings only when it is located at the entrance / exit position on the front side of the casing. The above-mentioned problem was solved by using a door closing tool that temporarily moved in a moving and inclined state.

  The invention according to claim 2 is a casing, a sliding member mounted so as to move in the horizontal direction in the casing, and a hook member that enters and exits from the tip of the casing and is pivotally connected to the sliding member. A drum part rotatably mounted on the casing; a spring with a central end fixed to the casing side and an outer peripheral end fixed inside the drum part; and a longitudinal end. Is an elastic tensioner composed of a linear member fixed to the outer periphery of the drum part, a cylinder housing part, a piston rod reciprocating in the cylinder housing part, and the cylinder housing part is hermetically filled. A reciprocating hydraulic pressure damper made of a liquid that gives resistance to the piston rod, and the other end of the linear member are connected to the sliding member, and the sliding member passes through the casing from the front. The reciprocating hydraulic damper generates a resistance force that reduces the elastic force of the hook member by the mainspring, and the hook member is near the entrance / exit of the casing The above problem has been solved by providing a door closing tool that is temporarily stopped in an inclined state only when it is positioned at the position.

  According to a third aspect of the present invention, in the configuration described above, the hook member includes a locked edge and a contacted edge, and the locked edge is formed shorter in the extending direction than the contacted edge, And the said subject was solved by making the to-be-latched edge into the door closing tool formed in the said inlet side side. According to a fourth aspect of the present invention, in the above-mentioned configuration, a guide protrusion is formed on the lower surface side of the hook member, the guide groove for guiding the guide protrusion in the front-rear direction of the casing, and the introduction port A door formed on the side and continuous with the guide groove, and formed with a locking groove that guides the guide protrusion and swings the hook member in a horizontal plane near the inlet and temporarily stops in an inclined state. By using a closure, the above problems were solved.

  According to a fifth aspect of the present invention, the above-described problem is solved by using the door-closing tool in which the reciprocating hydraulic damper is arranged substantially in parallel with the linear member of the elastic tensioner in the above-described configuration. According to the sixth aspect of the present invention, an elastic tension tool having one end of a linear member fixed to an appropriate position on the outer periphery of the drum portion rotated by the mainspring is provided in the casing and generates a resistance force that resists the elastic force of the mainspring. A buffer member is provided, and the linear member is coupled to the sliding member so as to be moved from the front to the rear in the casing, and the hook member is pivotally coupled to the sliding member, A door closing tool that swings and stops temporarily in an inclined state only when it is located at the entrance / exit part on the front side of the casing, a guide rail, and a traveling body that runs along the guide rail and suspends a sliding door. , And a locking device that locks the hook member of the door closing tool, and the locking member and the hook member are locked at the door closing end position of the sliding door, and the hook member is temporarily stopped. Sliding doors released By was door closing device, the above-mentioned problems are eliminated.

  The invention according to claim 7 is a casing, a sliding member mounted so as to move in the horizontal direction in the casing, a hook member that enters and exits from the front end of the casing and is pivotally connected to the sliding member. A drum part rotatably mounted on the casing; a spring with a central end fixed to the casing side and an outer peripheral end fixed inside the drum part; and a longitudinal end. Is composed of an elastic tensioning tool composed of a linear member fixed to the outer periphery of the drum portion, and a buffer member that generates a resistance force that reduces the elastic force of the hook member by the mainspring. The other end is connected to the sliding member, and the sliding member is elastically biased so as to move from the front to the rear in the casing, and the hook member is near the entrance / exit of the casing A door closing tool that is temporarily stopped in an inclined state only when it is positioned, a guide rail, a traveling body that runs along the guide rail and suspends a sliding door, and a hook member of the door closing tool. A sliding door closing device comprising a locking tool, wherein the locking tool and the hook member are locked at the door closing end position of the sliding door, and the temporary stop state of the hook member is released. The above-mentioned problem was solved. Next, the above-mentioned problem is solved by making the invention of claim 8 a sliding door closing device in which the door closing tool is mounted on the guide rail side in the above-described configuration.

  According to the first and second aspects of the present invention, there is provided an elastic tensioning tool in which one end of a linear member is fixed to an appropriate position on the outer periphery of a drum portion rotated by a spring. It can be put on. Furthermore, the elastic force of the elastic tensioning device is appropriately reduced by the resistance force of the reciprocating hydraulic damper, and by appropriately combining the elastic force of various springs and the resistance force of the reciprocating hydraulic damper, It is possible to set a plurality of door closing forces, and it can be more diverse than the case where the elastic force of only the mainspring is used as the door closing force as it is.

  Further, the elastic tensioning tool is one in which one end of a linear member is fixed to an appropriate position on the outer periphery of the drum portion rotated by the spring, and is a single member centering on the drum portion. Therefore, the mounting in the casing can be extremely simplified, and the assembly work efficiency can be greatly improved. Further, the mainspring is usually spiral, and has a more stable elastic force than that in which a shaft-like coil spring is used in the same structure. The invention of claim 3 can ensure the operation of the hook.

  According to the invention of claim 4, a more reliable operation can be secured in the sliding member and the hook. According to the fifth aspect of the present invention, the linear member and the reciprocating hydraulic damper are arranged in parallel, so that the linear member or the reciprocating hydraulic damper of the elastic tensioner can be easily replaced or replaced. . Furthermore, in the above-described configuration, the structure can be greatly simplified by arranging the linear member of the elastic tensioner and the reciprocating hydraulic damper in parallel. According to the sixth and seventh aspects of the present invention, a good deceleration operation can be obtained at the end of the sliding door closing operation. The invention of claim 8 can secure the most stable operation.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The configuration of the present invention includes a door closing device A (member constituting a door closing device) composed of a sliding member 1, a hook member 2, an elastic tensioning tool 3, a reciprocating hydraulic damper 4, a casing 5, and the like, and a sliding door 9 side. The guide travel body 8 is mounted on the guide rail 7, the guide rail 7 and the cabinet or room partition section on which these are mounted.

  First, in the door closing tool A, as shown in FIG. 5 (A), the sliding member 1 is formed with a pivot connecting portion 13 on one end side in the longitudinal direction of the sliding main body portion 11. The pivot connecting portion 13 is formed with a connecting shaft piece 13a, and is pivotally connected to a hook member 2 described later via the connecting shaft piece 13a.

  Further, a guided projection piece 14 is formed in the vicinity of the pivot connecting portion 13 on the longitudinal end surface of the sliding body portion 11 (see FIGS. 5 and 6). The guided projection piece 14 is a portion protruding in the horizontal direction so as to be substantially orthogonal to the longitudinal direction of the sliding main body portion 11, and its upper surface 14 a is formed in a flat surface shape. The upper surface 14a of the guided projection piece 14 is in contact with a main guide portion 53 of the casing 5 to be described later and is a portion that slides along the main guide portion 53 (see FIG. 3).

  Further, a connecting portion 15 to which an end portion of a linear member 33 of the elastic tensioner 3 to be described later is connected and fixed is formed below the guided projection piece 14 (see FIG. 5A). Further, a sliding member operation piece 16 is formed so as to protrude downward from the 14 guided projection pieces (see FIGS. 1, 5 to 7). The sliding main body 11 is formed with a sliding restricting protrusion 17 that engages with a sliding restricting portion 54 formed on the casing 5 side described later. The sliding restricting protrusion 17 is formed at the end close to the door closing side in the longitudinal direction of the sliding member 1 and is formed so as to protrude in a direction perpendicular to the longitudinal direction of the sliding member 1. is there.

  Moreover, the protrusion part 18 which protrudes upwards is formed in the door opening side edge part of the sliding member 1 (refer FIG. 1, FIG. 5 thru | or FIG. 7). The protrusion 18 serves to regulate the swing range of the hook member 2 by abutting the hook member 2 to be described later at the tip portion. Here, the door closing side and the door opening side will be described. The door closing side is a direction of movement when the sliding door 9 is closed, and is a direction from the right side to the left side in FIG. The door opening side is a direction from the left side to the right side in FIG. Further, in the casing 5, as shown in FIGS. 1B and 1C, the right side is the door closing side, and the left side is the door opening side.

Next, as shown in FIGS. 1, 5, 6, 7, and the like, the hook member 2 protrudes upward by the pivoting base portion 21, the hook portion 22, and the swinging motion of the pivoting base portion 21. It is comprised from the engaging part 23 to do. The hook portion 22 includes a locked piece 22a and a contact piece 22b, and the locked piece 22a. And the contacted piece 22b Is formed so as to project in a substantially parallel state. As shown in FIGS. 7A and 7B, the locked piece 22a is formed with a dimension in the height direction lower than that of the contacted piece 22b.

Also, the locked piece 22a And the contacted piece 22b Is a substantially U-shaped recessed portion 22c, and a locking portion 62 of a locking tool 6 mounted on a guide traveling body 8 to be described later is inserted and locked into the recessed portion 22c. Be able to. The pivot base 21 is provided with a pivot hole 21a into which the coupling shaft piece 13a formed in the pivot coupling portion 13 is inserted into the sliding member 1, and the coupling shaft piece 13a. The pivot hole 21a As a result, the sliding member 1 and the hook member 2 are connected to each other, and the hook member 2 is rotatable in the vertical direction with respect to the sliding member 1 (see FIGS. 6 and 7).

As shown in FIGS. 1 and 7, the engaging portion 23 is a portion formed in an arc shape around the pivot hole 21 a of the rotating base portion 21. Specifically, the engaging portion 23 is a portion formed as the outer peripheral side surface of the rotation base portion 21. The engaging portion 23 is a portion that is close to or in contact with an engaged surface portion 55 formed in the casing 5 described later so as to be rotatable in an arc shape. As described above, the connecting shaft piece 13a of the pivot connecting portion 13 between the hook member 2 and the sliding member 1 has the pivot hole 21a. The hook member 2 is pivotably inserted into the hook member 2 so that the center of the hook member 2 is the engagement portion 2.
3 is the center of the arc.

  In addition, a guide protrusion 24 may be formed on the hook portion 22 of the hook member 2 as shown in FIGS. The guide protrusion 24 is inserted into an auxiliary guide portion 56 formed on the casing 5 to be described later, and the hook member 2 is favorably moved along the longitudinal direction of the casing 5, and the hook member 2 is rotated (swayed). Motion) The operation is to be performed well and accurately.

  Further, as shown in FIGS. 5 to 7 and the like, a hook operation piece 25 is formed on the rotating base 21 downward. The hook operating piece 25 serves to forcibly move the casing 5 outside the casing 5 via the hook operating piece 25 when the hook member 2 is stopped in the casing 5 due to malfunction. is there. The hook operation piece 25 protrudes to the outside of the casing 5 together with the sliding member operation piece 16, and an operation for forcibly moving the sliding member 1 and the hook member 2 from the outside of the casing 5 is performed manually. (See Figure 1). Further, a locking projection piece 26 is formed at a top portion of the rotation base portion 21 and at a right angle from the width direction of the hook portion 22. When the hook member 2 moves together with the sliding member 1 along a main guide portion 53 described later, the locking projection piece 26 abuts on the main guide portion 53 together with the sliding guided projection piece 14. To move.

Next, the casing 5 is divided into two parts as shown in FIGS. And the second casing portion 52. FIG. 8 shows the first casing part 51. It is the figure seen from the inner side. The first casing portion 51 A main guide portion 53 is formed on the inner side of the first main body 511. The main guide portion 53 is a portion that is linearly formed along the longitudinal direction of the first casing portion 51, and the lower surface side thereof is formed flat. Specifically, the main guide portion 53 has a shape that bulges inward from the surface of the first main body 511.

  Further, the main guide portion 53 is formed in a substantially half region on the door opening side in the longitudinal direction of the first main body 511 as shown in FIG. 3 (A), FIG. 8, FIG. . As described above, the main guide portion 53 is formed such that the lower surface side is flat, the upper end surface of the guided projection piece 14 of the sliding member 1 abuts, and the locking projection piece 26 of the hook member 2. Also contacts the main guide 53.

  As shown in FIG. 3A, FIG. 8, FIG. 9, FIG. 10, etc., an engaged surface portion 531 is formed at the opening side end portion of the main guide portion 53. The engaged surface portion 531 is formed in an arc shape. Specifically, the hook member 2 is a convex arcuate surface, that is, an arcuate convex surface portion, and the engaged surface portion 531 is a concave arcuate surface, that is, an arcuate concave surface portion. The radii of curvature of the engaging portion 23 and the engaged surface portion 531 are substantially equal, and the engaging portion 23 can smoothly rotate along the engaged surface portion 531.

  Then, when the hook member 2 moves along the main guide portion 53 and reaches the position of the engaged surface portion 531, the hook portion 2 moves so that the engaging portion 23 slides along the engaged surface portion 531. 2 can be swung. Then, when the engaging portion 23 of the hook member 2 is engaged with the engaged surface portion 531, the hook member 2 resists the elastic force F of the spring 32 of the elastic tensioner 3 at the engaged surface portion 531. The temporary stop state is entered. The temporary stop state refers to a state in which the stop can be maintained to such an extent that it can move when the locking portion 62 of the guide traveling body 8 comes into contact with the guide travel body 8 although it does not operate with some vibration.

At this time, the hook member 2 is engaged with the locked piece 22a. The upper end of the contact piece 22b It is in an inclined state so as to be lower than the upper end. In this state, the locking tool 6 of the guide traveling body 8 is in a state where it can freely enter and exit between the locked piece 22a and the contacted piece 22b. Further, the first casing portion 51 A damper storage chamber 59 in which the reciprocating hydraulic damper 4 is mounted is formed inside, and the reciprocating hydraulic damper 4 is mounted in the casing 5 through the damper storage chamber 59. The guided protrusion 14 of the sliding member 1 is brought into contact with the lower side of the main guide portion 53. The elastic force F of the spring 32 of the elastic tensioner 3 is required to be larger than the resistance force T generated by the reciprocating hydraulic damper 4, but the difference between the elastic force F and the resistance force T is appropriately determined. Set to

Next, the second casing portion 52 Will be described. FIG. 1A shows the second casing portion 5.
2 In this figure, the sliding member 1, the hook member 2, the elastic tensioning tool 3, and the reciprocating hydraulic damper 4 are mounted. FIG. 2B is a view of the second casing portion 52 as viewed from the outside. FIG. 3A shows the second casing portion 52 and the first casing portion 51. It is the figure which combined.

  The second body 522 is formed with a sliding restricting portion 54 and an auxiliary guide portion 56. The sliding restricting portion 54 is linear, and the sliding restricting projection 17 of the sliding member 1 is inserted to restrict the range of movement of the sliding member 1 within the casing 5. That is, the sliding member 1 can appropriately move in the casing 5 and also serves to prevent the sliding member 1 and the hook member 2 from dropping out of the casing 5 [FIG. 2 (B). reference〕. The proper movement of the sliding member 1 means movement within a range in which the hook member 2 pulled out in the door opening direction by the locking portion 62 of the guide traveling body 8 can be temporarily stopped at the engaged surface portion 531. Say. The sliding restricting portion 54 is formed in a slit shape, and has a groove width that allows the sliding restricting projection 17 of the sliding member 1 to move smoothly.

  Next, the auxiliary guide portion 56 is a portion for guiding the movement and swinging operation of the casing 5 in the longitudinal direction while the guide protrusion 24 of the hook member 2 is inserted and the hook member 2 is stable. The auxiliary guide portion 56 includes a linear sliding guide portion 561 formed in a linear slit shape and a swing guide portion 562 in which the hook member 2 swings. The linear sliding guide portion 561 serves to support the movement of the hook member 2 when the hook member 2 moves in the longitudinal direction in the casing 5 together with the sliding member 1. Further, the swing guide portion 562 can move in a stable state when the hook member 2 performs a swing operation.

The auxiliary guide part 56 includes the first casing part 51. The main guide portion 53 and the engaged surface portion 531 serve to further ensure the operation of the sliding member 1 and the hook member 2. Therefore, the auxiliary guide part 56 may not be formed. Further, it is possible to form only the auxiliary guide portion 56 without forming the main guide portion 53 and the engaged surface portion 531, but in this case, the sliding member 1 is slid. Another guide part is required.

Second casing portion 52 Is formed with a mounting projection 57 for mounting on the end of a guide rail 7 described later (see FIG. 2). The mounting protrusion 57 can maintain the casing 5 in a stable state on the guide rail 7 by being inserted along the longitudinal direction from the longitudinal end of the guide rail 7. Further, the swing guide portion 562 of the auxiliary guide portion 56 is formed on the mounting projection portion 57 so that a stable swing operation can be performed in a state where a part of the hook member 2 protrudes from the casing 5. Can be performed. In the lower part of the second casing part 52, the sliding member operation piece 16 and the hook operation piece 25 protrude to the outside of the casing 5 at a jointed position with the first casing part 51 in a line shape or a line shape. The cutting part 52a which can form the operation slit is formed [see FIGS. 1 and 3A].

  Next, the elastic tensioner 3 uses a spring 32 as an elastic source. As shown in FIGS. 1 (B), 3 (B), (C), (D), FIG. 4 and the like, the elastic tensioning tool 3 includes a drum portion 31, a spring 32, and a linear member 33. Yes. A spring 32 is housed in the drum portion 31, and a linear member 33 is wound around the outer periphery of the drum portion 31. The drum portion 31 is pivotally supported at the end portion of the casing 5 in the longitudinal direction.

  As shown in FIG. 3D, the drum portion 31 includes a drum main body portion 311 and a cover portion 312. The drum main body 311 has a flat cylindrical shape, and includes a main body side surface portion 311a and a circumferential side surface portion 311b. The main body side surface portion 311a has a disk shape, and a bearing hole 313 is formed at the center position thereof. Furthermore, the outer peripheral edge of the main body side surface portion 311a protrudes outward from the circumferential side surface portion 311b and has a substantially bowl shape. The drum main body 311 has a storage container shape, in which the mainspring 32 is stored.

  As shown in FIG. 3D, the cover portion 312 is formed in a disc shape and has a diameter equivalent to that of the main body side surface portion 311a of the drum main body portion 311. A bearing hole 313 is also formed at the center of the cover portion 312. By joining the cover 312 to the drum body 311, a substantially pulley-shaped drum 31 is formed [see FIG. 3C]. The cover portion 312 is formed with a circular bulging portion 312a that can be fitted and joined to the inner peripheral surface of the circumferential side surface portion 311b of the drum body portion 311. The circular bulging portion 312a and the circumferential side surface are formed. The portion 311b is fitted, and the drum main body portion 311 and the cover portion 312 are joined.

  The spring 32 is formed by spirally forming a thin strip steel plate, and a normal spring is used. The center end 321 of the spiral of the mainspring 32 is fixed to the drum support shaft 58 that passes through the bearing hole 313 located at the center of the drum 31, and the outer peripheral end 322 of the spiral of the mainspring 32 is fixed to the drum 31. The drum body 311 is fixed to an appropriate position on the inner peripheral side of the circumferential side surface portion 311b (see FIG. 4).

  The spring 32 is normally set in a state where the spiral interval around the central end 321 is wide (see FIG. 4B). One end of a linear member 33 is fixed to the outer periphery (circumferential side surface portion 311 b) of the drum portion 31, and the other end is connected to the pivot connecting portion 13 of the sliding member 1. As the linear member 33, a steel wire, a synthetic resin wire, a fiber material wire or the like is used. The linear member 33 is formed in a wire shape, a string shape, or a band plate shape.

  The elastic tensioner 3 is in a state in which the linear member 33 is wound around the circumferential side surface portion 311 b of the drum portion 31, and the spring 32 is pulled out by pulling the linear member 33 from the drum portion 31. Elastic energy accumulates in the center of the. When the linear member 33 separated from the drum portion 31 is made free, the drawn linear member 33 returns to the inside of the drum portion 31 and can be restored so as to be wound around the drum support shaft 58. It can be done. When the spring 32 is restored, the drum portion 31 rotates.

  When the hook member 2 is in the temporarily stopped state, the winding interval of the linear member 33 from the drum portion 31 is narrowed, and the elastic (triggering) energy is accumulated, and the elastic force F [See FIG. 4A]. When the temporarily stopped state of the hook member 2 is released, the spiral portion of the central end portion 321 of the spring 32 is expanded so as to expand radially, and the elastic force F due to the elastic energy of the spring 32 is the line. The hook member 2 can be forcibly moved in the pulling direction by the linear member 3333.

  Further, in the elastic tensioning tool 3, Sa is defined as an interval between the 13 pivotally connected portions of the sliding member 1 and the separation point Q between the drum portion 31 and the linear member 33 when the hook member 2 is temporarily stopped. [Refer to FIG. 4 (A)], 13 points of the pivotal connection portion of the sliding member 1 in the state where the hook member 2 has reached the movement end position (refer to FIG. 4 (B)), the drum portion 31 and the line Assuming that the distance from the separation point Q to the shaped member 33 is Sb, the moving distance of the sliding member 1 is (Sa−Sb), and this moving distance is Sc (see FIG. 4B).

  From the above, the elastic energy of the mainspring 32 may be set such that the drum portion 31 can obtain an amount of rotation corresponding to at least the distance Sc. The movement distance Sc is short, and the diameter of the drum section 31 and the elastic force of the spring 32 are sufficient so that the rotation of the drum section 31 corresponding to the movement distance Sc is sufficient in approximately half rotation. It is preferably set.

  21 shows a case where a spring 32 is used as the elastic tensioning tool 3 of the door closing tool A (see FIG. 21A) and a case where a coil spring is used as the elastic tensioning tool 3 (see FIG. 21B). ] Are compared. The elastic tensioning tool 3 provided with the mainspring 32 has a better advantage that it can achieve orderly and space saving than the case where a coil spring is used.

  Next, the reciprocating hydraulic damper 4 is mainly composed of a cylinder housing 41 and a piston rod 42 as shown in FIGS. The cylinder housing portion 41 is filled with a liquid, and a viscous liquid is particularly preferable. The liquid is specifically oil or grease. Further, the material and the substance are not limited as long as the liquid is viscous. The cylinder housing 41 has a sealing property so that these liquids do not leak.

  Further, a return spring is mounted in the cylinder housing portion 41, and is elastically biased so that the piston rod 42 is constantly protruded from the cylinder housing portion 41. And even if the piston rod 42 is once pulled into the cylinder housing part 41, it can immediately return to the original protruding state via the return spring and return. In the reciprocating hydraulic damper 4, the piston rod 42 is normally in a protruding state as shown in FIG. 1B, and when the piston rod 42 is pulled into the cylinder housing portion 41, The liquid filled in the inside, the return spring or the like becomes a resistance force, and the elastic force F of the spring 32 of the elastic tensioner 3 can be attenuated.

As described above, the reciprocating hydraulic damper 4 is mounted in the casing 5, and there are two types of mounting configurations. In the first type mounting configuration, the mainspring 32 and the reciprocating hydraulic damper 4 are arranged in parallel in the casing 5. First, the first casing part 51 or the second casing part 52 A damper storage chamber 59 for storing the reciprocating hydraulic damper 4 is formed in at least one of the casings 5. The reciprocating hydraulic damper 4 is fixed in a stationary state in the damper storage chamber 59. Specifically, as shown in FIGS. 1A to 1C, the damper storage chamber 59 is configured by a partition wall 591, and the reciprocating hydraulic damper 4 includes the partition wall 591. It is attached to the casing 5 so as to be surrounded by.

  The reciprocating hydraulic damper 4 is arranged in parallel so that its piston rod 42 is substantially parallel to the linear member 33 of the elastic tensioner 3 in the casing 5. As a result, the elastic tensioning tool 3 and the reciprocating hydraulic damper 4 can be replaced and replaced relatively easily when deterioration occurs. The piston rod 42 of the reciprocating hydraulic damper 4 enters the cylinder housing 41 while resisting the elastic force F of the spring 32.

  The reciprocating hydraulic damper 4 serves to reduce the speed in the door closing direction of the sliding member 1 due to the elastic force F of the spring 32. In the reciprocating hydraulic damper 4, as shown in FIG. 1B, FIG. 4, FIG. 6, etc., a resistance force T against the elastic force F that moves the sliding member 1 to the door closing side is generated, The sliding member 1 and the hook member 2 are moved to the door closing side by the door closing force P obtained by subtracting the resistance force T from the elastic force F. That is, the guide traveling body B that supports the sliding door 9 is moved by the force of FT = P, and the initial speed Vn of the sliding door 9 is locked to the guide traveling body B as shown in FIG. The low speed Vm by the door closing force P until the door closing is completed after the part 62 is engaged with the hook member 2 can be achieved.

Next, the locking tool 6 is a guide traveling body 8. 12 (B) and 12 (C), an arm-shaped portion 61 extending along the moving direction and a locking portion 62 formed at the tip of the arm-shaped portion 61 are configured. The locking portion 62 is formed so as to protrude in the horizontal direction with respect to the longitudinal direction of the arm-like portion 61. In the door closing operation, the engaged surface portion 531 contacts the contact piece 22b of the hook member 2 that is temporarily stopped, and the hook member 2 is moved from the engaged surface portion 531 to the main guide portion 53. At the same time, the locking portion 62 is accommodated between the locked piece 22a and the contacted piece 22b and is engaged with the hook member 2 (see FIGS. 13 and 14).

  The locking member 6 is a connecting portion provided on each of the upper guide traveling body 8 and the lower guide traveling body 8, specifically, a traveling portion that is a main portion of the upper and lower guide traveling bodies 8. 81. The upper and lower guide traveling bodies 8 serve to move the sliding door 9 along the upper and lower guide rails 7. The guide rail 7 is formed with one or a plurality of rail portions 71, 71. Each of the rail portions 71, 71 has a guide opening 72 formed on the lower side.

First, the guide traveling body 8 As shown in FIGS. 1 and 12, the hang roller type corresponds to the guide rail 7, and the traveling unit 81 includes a traveling main body unit 811 and roller units 812 and 812. The traveling main body 811 is provided with a support shaft 82 that serves to adjust the vertical position of the sliding door 9, and a connecting tool 83 for connecting to the sliding door 9 is provided below the support shaft 82. It is installed. The guide traveling body 8 and the sliding door 9 are connected via the connection tool 83.

Further, on the lower side of the sliding door 9, a guide traveling body 8 is provided. Is installed. The lower guide traveling body 8 is substantially the same as the upper guide traveling body 8, but the connecting member 83 is formed in a screw shaft shape or the like and is attached to the lower surface side of the sliding door 9. The guide traveling body 8 is attached to the lower guide rail 7 and slides in the guide rail 7. Similarly to the upper guide rail 7, the door closing tool A may be mounted on the door closing side end of the lower guide rail 7.

  Next, the specific example of the structure which assembles the sliding door 9 and the door closing tool A as the partition between the upper and lower guide rails 7 or a cabinet is shown. First, in the case of a cabinet, as shown in FIGS. 11 and 12, the cabinet is composed of an upper portion 100, both side portions 200, and a bottom portion 300, and its front surface is an opening 400 for installing the sliding door 9. . Therefore, as an example of the first type of assembly, the upper guide rail 7 is mounted on the upper portion 300 of the cabinet C so as to correspond to the upper and lower end portions of the sliding door 9. A lower guide rail 7 is attached to the bottom 300 of the cabinet C.

As the upper and lower guide rails 7, those having two rail portions 71 and 71 are used so as to have two lanes, respectively (see FIG. 12A). The two sliding doors 9 and 9 can be mounted at 400 openings of the cabinet C. A guide traveling body 8 is mounted on the two rail portions 71 and 71 of the upper guide rail 7. Similarly, a lower guide traveling body 8 is disposed on the two rail portions 71 and 71 of the lower guide rail 7, and the upper and lower guide traveling bodies 8 and 8 are arranged. Thus, the sliding door 9 is connected to the sliding door 9 through a connecting device such as the connecting tool 83 so as to support the upper and lower ends thereof.

  In this way, the sliding doors 9 are arranged on the two lanes (rail portions 71, 71), respectively, and the two sliding doors 9, 9 open and close, respectively. 12 and 16, the sliding door 9 located in the front of the opening 400 moves to the left end to form a closed state, and the sliding door 9 located on the back side (back side) than the sliding door 9 is on the right side. It moves to the end and constitutes a closed state.

  As shown in FIGS. 1, 13 to 15, the casing 5 of the door closing tool A is substantially straight at the door closing side end in the longitudinal direction of the rail portions 71, 71 of the guide rail 7. And connected. That is, it is a structure in which the upper and lower guide rails 7 are continuously connected to the rail portions 71 and 71 in the same line. This is because space saving can be realized by attaching the door closing tool A, and the engaging operation between the upper and lower guide traveling bodies 8 and the door closing tool A can be smoothed.

  Next, as an assembly example of the second type, as shown in FIGS. 16 and 18, the casing 5 of the door closing tool A is arranged in parallel with the upper and lower guide rails 7. Specifically, the casing 5 of the door closing device component (door closing tool) is disposed adjacent to the longitudinal direction of the upper and lower guide rails 7. That is, it is installed so as to be at a right angle to the mounting state of the casing 5 in the case of the first type assembly example described above.

  Further, a spacer 500 for height adjustment is provided between the casing 5 and the upper portion 100 of the cabinet C, and the insertion port of the locking tool 6 in the casing 5 and the locking tool of the guide traveling body 8 are provided. It is set so that the position of 6 matches. The lower guide rail 7 has a rail portion 71 composed of one lane, and the guide traveling bodies 8 of the two sliding doors 9 and 9 share the rail portion 71 composed of the one lane. .

Furthermore, the lower guide traveling body 8 attached to the two sliding doors 9, 9. In order to prevent the two sliding doors 9 and 9 from interfering with each other, the lower guide traveling body 8 is attached to each of the two sliding doors 9 and 9 only at the door closing side end portion. Also in the lower guide rail 7, the casing 5 of the door closing device constituent part (door closing tool) is mounted on the bottom via a spacer 500. In this way, the locking tool 6 of the lower guide traveling body 8 and the position of the entrance / exit of the casing 5 are matched. Each lower guide traveling body 8 is mounted near a lower end of the sliding door 9 via a bracket.

  The bracket is formed by bending a band plate material into a substantially “L” shape. Then, one end of the bracket is in contact with the back side of the sliding door 9 and is fixed by a fixing tool such as a screw. Further, the other end side of the bracket is bolted and connected by a screw shaft-like connection tool 83 provided in the lower guide traveling body 8.

18 shows a door closing device component (door closing tool) in the door closing state at the right end of the cabinet C and the lower guide traveling body 8. The state is shown. As shown in FIGS. 17 (A) and 17 (B), the locking member 6 attached to the upper guide traveling body 8 and the lower guide traveling body 8 in the second type assembly example has an arm-shaped portion 61 as shown in FIGS. Main arm piece 61a The main arm piece 61a and the protruding piece 61b are substantially L-shaped.

The main arm piece 61a The protruding direction is determined by the closing direction of the two sliding doors 9. The main arm piece 61a indicated by the solid line is used for the right closing sliding door 9, and the main arm piece 61a indicated by the imaginary line is used. Is used for the sliding door 9 closed on the left side. The locking tool 6 and the traveling main body 811 may be integrally formed or may be formed as separate members. Since it is set as such a structure, as shown in FIG. 18, the locking tool 6 protrudes in the direction orthogonal to the longitudinal direction of a rail from the upper and lower guide rails 7. As shown in FIG.

Next, each operation | movement of the door closing of the sliding door 9 and the door opening by the door closing apparatus in 1st type is demonstrated based on FIG. 13 thru | or FIG. FIGS. 13 to 15 show the respective operations of closing and opening the sliding door 9 by the door closing tool A such as the casing 5 attached to the upper guide rail 7 and the upper guide traveling body 8. is there. The upper guide rail 7, the upper guide traveling body 8, and the door closing operation are respectively performed for the lower guide rail 7, the lower guide traveling body 8, and the door closing and opening operation of the sliding door 9 by the door closing tool A. The operation is equivalent to the operation of closing and opening the sliding door 9 by the tool A.

  First, the door closing operation of the sliding door 9 will be described with reference to FIGS. As shown in FIG. 13A, the sliding member 1 and the hook member 2 are pivotally connected, and in the initial state, the engaging portion 23 of the hook member 2 is covered by the casing 5 (first casing portion 51). It is in a temporarily stopped state in a state of being engaged with the engaging surface portion 531. Then, when the sliding door 9 in the open state moves in the door closing direction (from the left side to the right side in FIG. 13A), the sliding door 9 gradually approaches the hook member 2, and as shown in FIG. The distal end of the locking portion 62 comes into contact with the contact piece 22b of the hook member 2.

Furthermore, the guide traveling body 8 Is moved in the door closing direction, the engaging portion 62 acts to press the contact piece 22b, and the engaging portion 23 is rotated while the rotating base portion 21 of the hook member 2 is rotated with respect to the sliding member 1. Is detached from the engaged surface portion 531 of the casing 5, and the temporarily stopped state of the hook member 2 is released. Specifically, the engaging portion 23 is disengaged from the engaged surface portion 531 while the rotation base portion 21 rotates in the clockwise direction. At this time, the engaging portion 62 of the guide traveling body 8 is engaged with the contact piece 22b of the hook member 2 through the process shown in FIGS. 13C and 14A. 22a and contact piece 22b It fits in the recessed part 22c of the substantially U shape between.

  Then, together with the locking operation of the locking portion 62 and the hook member 2, the temporarily stopped state of the hook member 2 is released, and the sliding surface portion 27 formed in the flat shape of the hook member 2 is substantially the same as the main guide portion. The sliding surface portion 27 of the hook member 2 is moved in the door closing direction by the elastic force F of the spring 32 of the elastic tensioner 3 together with the guided projection piece 14 of the sliding member 1. . When the sliding member 1 and the hook member 2 are moved in the door closing direction by the elastic tensioner 3, the resistance force T by the reciprocating hydraulic damper 4 is elasticized by the elastic force F of the spring 32 of the elastic tensioner 3. Operates against the direction of force.

  As a result, a force obtained by subtracting the resistance force T of the reciprocating hydraulic damper 4 from the elastic force F of the elastic tensioner 3, that is, a force FT becomes a substantial door closing force P. The sliding door 9 is decelerated from the initial door closing speed Vn by the person's door closing operation by the door closing force P, and becomes a gentle speed Vm by the door closing force P, and the door closing operation is performed. It is forcibly moved to the door closing side, reaches the door closing direction end, and completes the door closing operation (see FIGS. 14B and 19).

This series of door closing operations is performed by the upper and lower guide traveling bodies 8 by the door closing tool A mounted on the upper and lower guide rails 7 respectively. At the same time, the sliding door 9 is moved in a decelerating direction in the door closing direction via the locking tool 6. As a result, when the sliding door 9 is forcibly moved to the door closing side by the door closing tool A, the sliding door 9 is decelerated in a well-balanced manner in the vertical direction and can move stably in the door closing direction without play.

  Next, the door opening operation | movement of the sliding door 9 is demonstrated based on FIG. First, as shown in FIG. 15 (A), the hook member 2 is positioned near the door closing side (right side in FIG. 15 (A)) in the initial state, and the hook member 2 is attached to the guide traveling body 8. The stopper 6 is in a locked state with the locked piece 22 a of the hook member 2. And as shown in FIG.15 (B), the locking tool 6 with which the guide traveling body 8 was mounted | worn by moving the said sliding door 9 in a door opening direction [from FIG. 15 (B) to the left side from the right side]. The hook member 2 and the sliding member 1 are forcibly moved to the door opening side along the main guide portion 53 so as to pull the locked piece 22a of the hook member 2 in the locked state.

  When the sliding door 9 is further moved in the door opening direction and the hook member 2 reaches the engaged surface portion 531, the sliding restriction projection 17 comes into contact with the door opening side end of the sliding restriction portion, and the sliding member 1. This serves as a stopper in the sliding operation, and the sliding of the sliding member 1 is stopped. At this time, the engaging portion 23 of the hook member 2 has reached the engaged surface portion 531 location. Further, by continuing the door opening operation of the sliding door 9, the hook member 2 moves the rotation base 21 so that the locked piece 22 a of the hook member 2 is pulled out by the locking portion 62 of the guide traveling body 8. Rotate through.

  Specifically, the hook member 2 rotates counterclockwise around the rotation base 21, and the engaging portion 23 moves to the engaged surface portion 531 and is engaged. The hook member 2 is engaged with the engaging portion 23 and the engaged surface portion 531 by an appropriate pressure by the elastic force F of the sliding member 1 and the elastic tensioner 3 connected to the sliding member 1. The contact state is maintained, whereby the hook member 2 is temporarily stopped at the engaged surface portion 531.

Since the hook member 2 is inclined at the door opening side, the locked piece 22a. As a result, the locking portion 62 of the guide traveling body 8 is detached from the locked piece 22a, the locked state between the locking portion 62 and the hook member 2 is released, and the sliding door 9 further Move to the opening side and complete the opening operation. Since the main guide portion 53 and the engaged surface portion 531 are formed on the first casing portion 51 side, the main guide portion 53 and the engaged surface portion 531 are described with imaginary lines. .

The series of door opening operations is performed by the upper and lower guide traveling bodies 8 by the door closing tool A mounted on the upper and lower guide rails 7 respectively. Through the respective locking tool 6, the elastic tensioning tool 3 in the door closing tool A
The sliding door 9 can be moved against the elastic force F. This makes it possible to perform a forcible movement in a stable door opening direction with good balance and no play in the upper and lower portions of the sliding door 9.

Next, the door closing and opening operations of the two sliding doors 9 in the second type are also substantially the same as those in the first type described above, and the upper and lower guide rails 7 are rail sections 71 and 71 of two lanes. Yes, except that the guide rail 7 is composed of a rail portion 71 having only one lane, the door 9 is closed by the guide rail 7, the guide traveling body 8, and the door closing tool A attached to the guide rail 7. The door closing operation and the door opening operation of the sliding door 9 by the door closing device components (door closing tool) such as the guide rail 7, the guide traveling body 8, and the casing 5 are substantially the same. FIG. 20 is a perspective view of an embodiment in which the sliding door 9 is a room partition. When the sliding door 9 is used as a partition, the guide rail 7 may be only the upper part.

  According to the present invention, a gentle door closing operation of the sliding door 9 can be obtained, and the initial operations of the door closing and the door opening can be made stable without play. That is, the sliding member 1 and the hook member 2 are pivotally connected so that the hook member 2 can swing freely. The force that the sliding member 1 moves in the casing 5 in the door closing direction depends on the elastic force F of the elastic tensioner 3, but the reciprocating hydraulic pressure damper 4 that reduces the elastic force F is provided. The guide traveling body 8 can be moved in the door closing direction by a force obtained by subtracting the resistance force T of the reciprocating hydraulic damper 4 from the elastic force F of the elastic tensioner 3, and is extremely gentle and stable and extremely good door closing. The action can be performed. Both the upper and lower guide rails 7 are fitted with a door closing tool A, and the upper and lower guide traveling bodies 8 can perform stable door closing and opening operations without play by the respective locking tools 6. It is.

  Further, the hook member 2 is configured such that the sliding member 1 swings only at the position of the door opening side end portion, and the engaging portion 23 is freely engageable with the engaged surface portion 531, thereby By bringing the sliding door 9 in the vicinity of the door closing side end, the sliding door 9 is forcibly drawn to the door closing side end, and the speed of the sliding door 9 is moderately reduced immediately before the door closing end to obtain a good door closing operation. be able to. Further, the entire door closing device can be made compact, and the space for incorporating the sliding door device directly into the guide rail 7 of the sliding door 9 into the sliding door device can be reduced. In addition, the sliding door 9 can be made stable and free of backlash without tilting the sliding door 9 in the initial operation of closing and opening the door.

That is, the locked piece 22a And the contacted piece 22b The hook member 2 is formed so as to be swingable with respect to the sliding member 1, and the engaging portion 23 protrudes upward by the turning operation of the turning base portion 21. . In the hook member 2, the sliding member 1 swings only at the position of the door opening side end portion, and the engaging portion 23 is engageable with the engaged surface portion 531. Therefore, in the case of the door closing operation, the hook member 2 can be temporarily stopped in a state where the hook member 2 is stable on the door opening side in the initial state. In other words, the hook member 2 is less likely to swing in the left-right direction when performing a swinging motion, and therefore can be extremely troublesome.

  Further, when the locking portion 62 of the locking tool 6 mounted on the guide traveling body 8 tries to lock the hook member 2, the locking member 62 is smoothly locked and the sliding member 1 and the hook member are locked by the elastic tensioning tool 3. 2 is moved in the door closing direction. At this time, the resistance force T of the reciprocating hydraulic damper 4 acts on the elastic tensioner 3 so as to reduce the elastic force F, and the sliding member that moves the guide traveling body 8 is moved. 1 and the hook member 2 can be moved within the casing 5 at an appropriately moderate speed. The sliding member 1 and the hook member 2 move along the longitudinal direction in the casing 5, and the moving direction is the same as the moving direction of the guide traveling body 8 in the guide rail 7.

  Therefore, the casing 5 can be mounted on the end portion of the guide traveling body 8 in the longitudinal direction, and therefore is substantially integrated with the guide rail 7 so that the apparatus of the present invention can be easily mounted and the mounting location can be saved. Can be realized. Further, the upper and lower guide rails 7 are each provided with a door closing tool A, so that when the sliding door 9 is closed and opened, the upper and lower guide rails 7 and the door closing tool A and the upper and lower guides respectively attached thereto. The traveling body 8 can be operated in a well-balanced manner via the locking member 6, and can be made stable and free of backlash without tilting the sliding door 9 in the initial operation of door closing and door opening.

  In the above-described configuration, the casing 5 is installed in a substantially straight line at the longitudinal ends of the upper and lower guide rails 7, so that the entire configuration of the door closing device can be compactly integrated. Further, the casing 5 is installed on the top plate rear surface side and the bottom plate upper surface side of the cabinet C and adjacent to the upper and lower guide rails 7 in a parallel state, whereby the casing 5 of the door closing tool A is attached to the upper portion 100 of the cabinet C and Since it is attached to the bottom portion 300, a relatively strong attachment structure can be obtained.

  Further, the engaging portion 23 and the engaged surface portion 531 are formed in an arc-shaped convex surface portion and an arc-shaped concave surface portion having the pivot connection portion as a rotation center, so that the hook member 2 is engaged from the main guide portion 53. The movement of the hook member 2 can be performed very smoothly when the mating surface portion 531 moves to engage with the engaging portion 23 and the engaged surface portion 531. Further, the reciprocating hydraulic damper 4 generates a resistance force T against the movement of the sliding member 1 in the door closing direction by the elastic tensioner 3, so that the sliding door 9 can be decelerated very easily and satisfactorily. It can be carried out.

  Next, a sliding member operating piece 16 and a hook operating piece 25 projecting outside the casing 5 are formed on the sliding member 1 and the hook member 2, respectively. Even when only the hook member 2 enters the casing 5 in a state in which the stopper 62 is not locked to the hook member 2, the hook member 2 is moved outside the casing 5 by the sliding member operation piece 16 and the hook operation piece 25. Can protrude. As described above, according to the present invention, it is extremely suitable as a sliding door device for high-quality furniture and cabinets or room partition points, and can be opened and closed smoothly without rattling or vibration during the initial opening / closing operation of the sliding door. The operation feeling of opening and closing is very good. Also, the sound when the door is closed can be made extremely quiet.

(A) is a principal part front view of the sliding door apparatus with which the door closure in this invention was mounted | worn, (B) is a front view of the door closure in which a hook part shows the inside of a temporary stop state, (C) is a hook part. It is a front view of the door closing tool which shows the inside of a temporary stop cancellation | release state. (A) is the side view which looked at the principal part of the door closure from the 1st casing part side, (B) is the side view which looked at the principal part of the door closure from the 2nd casing part side. (A) is Xa of FIG. 2 (A). -Xa (B) is a cross-sectional view taken along the line Xb-Xb in FIG. 2 (A), (C) is a longitudinal side view of the elastic tensioner, and (D) is a longitudinal side view of the elastic tensioner disassembled. It is. (A) is an effect | action figure of an elastic tension tool in case a hook member is a temporary stop state, (B) is an effect | action figure in a hook member cancellation | release state of a temporary stop. (A) is an exploded perspective view of a sliding member and a hook member provided with a reciprocating hydraulic pressure damper, and (B) is an enlarged view of a main part of a part of a section where the reciprocating hydraulic pressure damper is mounted. . (A) is a side view of a sliding member and a hook member to which a reciprocating hydraulic damper is attached, and (B) is a perspective view of the sliding member and a hook member to which a reciprocating hydraulic damper is attached. (A) is an enlarged side view of the sliding member and the hook member in an inclined state, and (B) is an enlarged side view of the sliding member and the hook member. FIG. 6 is a front view showing the internal structure of the first casing part. (A) is an action figure in the state where a hook member is located in a main guide part, (B) is an action figure in the state where a hook member is located in a to-be-engaged surface part. (A) is an enlarged action figure in the state in which the hook member is located in the main guide part, (B) is an enlarged action figure in the state in which the hook member is located in the to-be-engaged surface part. (A) is a front view of the cabinet with which the door closing device in this invention was mounted | worn, (B) is a transverse plane schematic diagram of the principal part of (A). (A) is an enlarged vertical side view of the first type sliding door device, (B) is a perspective view of the upper guide traveling body used in the first type assembly example, and (C) is the first type assembly. It is a perspective view of the lower guide traveling body used for an example. (A) is an operational view of the first type sliding door device in which the engaging portion of the guide traveling body is close to the hook member of the casing, and (B) is an application of the engaging portion of the guide traveling body to the hook member of the casing. FIG. 5C is an operation diagram in a state where the engaging portion of the guide traveling body is engaged with the hook member of the casing. (A) is an operation view in which the locking portion of the guide traveling body of the first type sliding door device is locked to the hook member of the casing to release the temporarily stopped state of the hook member, and (B) is a state in which the door closing is completed. FIG. (A) is an operational view of the door opening start in which the locking portion of the guide traveling body of the first type sliding door device is locked to the hook member in the casing, and (B) is the sliding door moved in the door opening direction. FIG. 4C is an operation diagram in a state in which the hook member is moved to the door open end, and FIG. 4C is an operation diagram in which the engaging portion of the guide traveling body is detached from the hook member of the casing and the hook member is temporarily stopped. It is an expansion vertical side view of the 2nd type sliding door apparatus. (A) is a perspective view of the upper guide traveling body used for the second type sliding door device, and (B) is a perspective view of the lower guide traveling body. It is a principal part cross-sectional top view of the 2nd type sliding door apparatus. It is an operation outline figure showing operation of a sliding door in the present invention. It is the perspective view which used the sliding door apparatus in this invention as a partition of a room.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Sliding member, 12 ... Rack part, 2 ... Hook member, 3 ... Elastic tension tool, 31 ... Drum part, 32 ... Spring, 33 ... Linear member, 4 ... Reciprocating hydraulic damper, 5 ... Casing,
7 ... guide rail, 8 ... running body, 9 ... sliding door.

Claims (8)

  An elastic tensioning tool in which one end of a linear member is fixed to an appropriate position on the outer periphery of the drum portion rotated by the mainspring is provided in the casing, and is composed of a cylinder housing portion, a piston rod, and a liquid, and the elastic force of the mainspring. A reciprocating hydraulic damper that generates a resistance force that resists the linear member is connected to the sliding member so that the linear member is moved from the front to the rear in the casing. The door closing tool characterized in that the hook member is pivotally connected and is temporarily stopped in a swinging and inclined state only when it is located at an entrance / exit portion on the front side of the casing.   A casing, a sliding member mounted so as to move in the horizontal direction in the casing, a hook member that is inserted and removed from the front end of the casing and pivotally connected to the sliding member, and is rotatable to the casing A drum portion mounted on the drum portion, a mainspring having a central end fixed to the casing side and an outer peripheral end fixed in the drum portion, and one longitudinal end on the outer periphery of the drum portion. An elastic tensioning tool composed of a fixed linear member, a cylinder housing part, a piston rod that can reciprocate in the cylinder housing part, and the cylinder housing part are hermetically filled, and resisting force is exerted on the piston rod. The reciprocating hydraulic damper composed of the liquid to be applied and the other end of the linear member are connected to the sliding member, and the sliding member moves from the front to the rear in the casing. The reciprocating hydraulic damper is elastically biased to generate a resistance force that reduces the elastic force of the hook member by the mainspring, and the hook member is inclined only when the hook member is located near the entrance / exit of the casing. A door closure characterized by being temporarily stopped in a state.   3. The hook member according to claim 1, wherein the hook member includes a locked edge and a contacted edge, and the locked edge is formed shorter in the extending direction than the contacted edge, and the locked member is formed. A door closing tool characterized in that an edge is formed closer to the introduction port side.   The guide projection is formed on the lower surface side of the hook member according to claim 1, and the casing has a guide groove for guiding the guide projection in the front-rear direction of the casing and a side closer to the introduction port side. And a locking groove that is continuous with the guide groove, guides the guide protrusion, swings the hook member in a horizontal plane in the vicinity of the inlet, and temporarily stops in an inclined state. Door closure to do.   The door closing tool according to claim 1, 2, 3, or 4, wherein the reciprocating hydraulic damper is disposed substantially in parallel with a linear member of the elastic tensioner.   An elastic tension tool in which one end of a linear member is fixed to an appropriate position on the outer periphery of the drum portion rotated by the mainspring is provided in the casing, and resistance means for generating a resistance force against the elastic force of the mainspring is provided, The linear member is connected to a sliding member so as to be moved from the front to the rear in the casing, and the hook member is pivotally connected to the sliding member, and an entrance on the front side of the casing A door closing tool that swings and temporarily stops in an inclined state only when located at a location, a guide rail, a traveling body that runs along the guide rail and suspends a sliding door, and a hook for the door closing tool A locking tool that locks to the member, wherein the locking tool and the hook member are locked at the door closing end position of the sliding door, and the temporary stop state of the hook member is released. Of sliding door Closing device.   A casing, a sliding member mounted so as to move in the horizontal direction in the casing, a hook member that is inserted and removed from the front end of the casing and pivotally connected to the sliding member, and is rotatable to the casing A drum portion mounted on the drum portion, a mainspring having a central end fixed to the casing side and an outer peripheral end fixed in the drum portion, and one longitudinal end on the outer periphery of the drum portion. An elastic tensioning tool comprising a fixed linear member; and a resistance means for generating a resistance force that reduces the elastic force of the hook member by the mainspring, the other end of the linear member being the sliding member The sliding member is elastically biased so as to move from the front to the rear in the casing, and the hook member is only located near the entrance / exit of the casing. A door closing tool temporarily stopped in an oblique state, a guide rail, a traveling body that runs along the guide rail and suspends a sliding door, and a locking tool that locks the hook member of the door closing tool. The sliding door closing device, wherein the locking member and the hook member are locked at the door closing end position of the sliding door to release the temporarily stopped state of the hook member.   8. The sliding door closing device according to claim 6, wherein the door closing tool is mounted on the guide rail side.

Images