JP6776168B2 - Joinery - Google Patents

Description

The present invention relates to fittings.

Conventionally, windows that can be automatically opened and closed to allow natural ventilation in a room due to the natural wind flowing outside the building or the difference in air pressure inside and outside the building have been known. In such a natural ventilation window, a shock absorbing device is installed in the window frame in order to absorb the shock when the shoji is blown by a strong wind and closed vigorously (see, for example, Patent Document 1). The conventional shock absorber has a problem that the structure becomes complicated and the cost becomes high in order to make it compact.

Japanese Unexamined Patent Publication No. 2014-21014

In view of the above circumstances, an object of the present invention is to provide a fitting in which the structure of the shock absorbing device can be simple and inexpensive.

In order to achieve the above problems, the fitting according to the invention according to claim 1 includes a frame, a shoji, and a shock absorbing device, and the shock absorbing device absorbs the impact when the shoji is closed. It has a shock absorbing arm that rotates with the closure of the shock absorbing arm, and a rotary damper that rotates in conjunction with the movement of the shock absorbing arm via a gear on the side opposite to the rotation axis of the shock absorbing arm. It is characterized by.

Since the fitting according to the first aspect of the invention is provided with an impact absorbing device that absorbs the impact when the shoji is closed, it absorbs the impact when the shoji receives the wind and closes, and prevents damage to the window and impact noise. it can. The shock absorbing device consists of a shock absorbing arm that rotates when the shoji is closed, and a rotation that rotates in conjunction with the movement of the shock absorbing arm via a gear on the opposite side of the rotation axis of the shock absorbing arm. Since it is composed of a type damper, the structure is simple and it can be inexpensive.

It is an indoor side front view which shows one Embodiment of the fitting of this invention. FIG. 1A is a cross-sectional view taken along the line AA of FIG. 1, showing a state in which the shoji is open (natural ventilation state). It is a vertical sectional view which shows the upper part of FIG. 2 enlarged. FIG. 1B is a cross-sectional view taken along the line BB in FIG. FIG. 1A is a cross-sectional view taken along the line AA of FIG. 1, showing a state in which the shoji is fully opened (forced ventilation state). (A) is a side view of the stopper device, and (b) is an indoor front view of the stopper device. It is explanatory drawing which shows the operation of the stopper device from the state which a shoji is closed to the state of natural ventilation. It is explanatory drawing which shows the operation of the stopper device from the state which a shoji is closed to the state of forced ventilation. It is explanatory drawing which shows the operation of the stopper device from the forced ventilation state to the closing of a shoji. FIG. 1 is a cross-sectional view taken along the line CC of FIG. 1, showing a state in which the shoji is open (natural ventilation state). It is explanatory drawing which shows the operation of the opening / closing operation means. It is a top view which shows the lock device. It is a vertical sectional view which shows the lock device. It is a perspective view which shows the lock device. It is explanatory drawing which shows the operation of a lock device. (A) is a plan view showing the first embodiment of the shock absorbing device, and (b) is the same side view. It is a perspective view of the shock absorbing device of 1st Embodiment. (A) is a plan view of the shock absorbing device of the first embodiment in a state where the shoji is closed, and (b) is a side view of the same. It is explanatory drawing which shows the operation of the shock absorbing device of 1st Embodiment. It is a side view which shows the 2nd Embodiment of a shock absorber. It is explanatory drawing which shows the operation of the shock absorbing device of 2nd Embodiment. (A) is a front view showing a third embodiment of the shock absorbing device, and (b) is a side view of the same. It is explanatory drawing which shows the operation when the shock absorbing device of 3rd Embodiment is attached to a vertical frame. (A) is a plan view when the shock absorbing device of the third embodiment is attached to the lower stile of the shoji, and (b) is the same side view. It is explanatory drawing which shows the operation when the shock absorbing device of 3rd Embodiment is attached to the lower frame of a shoji. It is explanatory drawing which shows the operation when the shock absorbing device of 3rd Embodiment is attached to the lower frame of a shoji. It is a front view which shows the other embodiment of the joinery which concerns on this invention. It is a side view of the fitting. (A) is a cross-sectional view taken along the line DD of FIG. 26, and (b) is a cross-sectional view taken along the line at the same position, showing a state in which the door is stopped by a stopper device.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. 1 to 19 show an embodiment of a fitting according to the present invention. As shown in FIG. 1, this fitting has an upper frame 19, a lower frame 20, and left and right vertical frames 3, 3 framed, and a transom light 21 is erected in the middle of the left and right vertical frames 3, 3 to form an upper frame. A mullion 4 is erected between 19 and 21 to form a frame 1, and a glass panel 22 is fitted into the opening between the transom 21 and the lower frame 20 to form a window for killing. In the opening between the upper frame 19 and the transom light 21, a natural ventilation window through which the shoji (doors) 2 and 2 open to the outside of the room is provided in a continuous window shape. At the lower parts of the left and right vertical frames 3 and 3, handles 23 for opening and closing each shoji 2 are provided.

The shoji 2 is constructed by assembling the upper stile 24, the lower stile 25, and the left and right vertical stiles 26, 26 into four stiles, and fitting a glass panel 27 inside the stile. As shown in FIGS. 3 and 4, a slide shaft 5 is provided at the upper end of the vertical stile 26 so as to project laterally, and a roller 28 is attached to the tip of the slide shaft 5. It is guided by a guide rail 29 provided along the longitudinal direction on the inner peripheral side surfaces of the vertical frame 3 and the mullion 4. As a result, the upper end of the shoji 2 is slidably and rotatably connected to the vertical frame 3 and the mullion 4.
As shown in FIG. 2, one end of the shoji support arm 30 is rotatably connected to the upper frame 19 on the inner peripheral side surface of the vertical frame 3 and the mullion 4 and the position at substantially the center of the transom light 21. The other end of the shoji support arm 30 is rotatably connected above the vertical center position of the outer peripheral side surface of the vertical frame 26 of the shoji 2.
In this way, the shoji 2 is supported by the frame 1 by the slide shaft 5 and the shoji support arm 30, and the slide shaft 5 slides downward and the shoji support arm 30 rotates outward to open to the outside. In this fitting, the center of gravity of the shoji 2 moves slightly downward as the shoji 2 opens. Therefore, in a windless state, the shoji 2 tries to open due to gravity, and a slight natural wind or a pressure difference between indoors and outdoors. As a result, the shoji 2 opens and closes smoothly.

As shown in FIG. 1, vertical slide bars 31 that slide up and down in conjunction with the operation of the handle 23 are provided on the inner peripheral side surfaces of the left and right vertical frames 3 and 3, and are provided at the upper ends of the vertical slide bars 31. Is provided with an opening / closing operation means 32 for controlling the opening / closing of the shoji 2. As shown in FIG. 10, the opening / closing operating means 32 is located in the vicinity of the rotation shaft 75 on the vertical frame 3 side of the shoji support arm 30, and has an operating member 33 that moves up and down together with the vertical slide bar 31 and the shoji support arm 30. It is composed of an opening / closing operation pin 34 projecting from the outer peripheral surface.
The operating member 33 has an upper rib 35 located above, a lower rib 36 located below, and a connecting portion 37 connecting the upper rib 35 and the lower rib 36. The upper rib 35 has an inclined portion 35a that is inclined upward from the indoor side to the outdoor side, and a vertical portion 35b that extends vertically from the upper end of the inclined portion 35a. The lower rib 36 has an inclined portion 36a that is inclined downward from the outdoor side toward the indoor side, and a vertical portion 36b that extends downward from the lower end of the inclined portion 36a.

When the shoji 2 is closed, the operating member 33 is in the most raised position, and as shown in FIG. 11A, the opening / closing operation pin 34 comes into contact with the vertical portion 36b of the lower rib 36 to support the shoji. The rotation of the arm 30 to the outdoor side is restricted, and the shoji 2 is locked in the closed state.
When the handle 23 is operated to the shoji opening side, as shown in FIG. 11C, the operating member 33 is lowered, the opening / closing operation pin 34 is separated from the vertical portion 36b of the lower rib 36, and the opening / closing operation pin 34 is the upper rib. The shoji support arm 30 can move freely within the range between the inclined portion 35a of the 35 and the inclined portion 36a of the lower rib 36, and at this time, the shoji 2 opens and closes due to a natural wind or a pressure difference between indoors and outdoors (natural ventilation state). ).
When the handle 23 is operated to the shoji closing side from the natural ventilation state shown in FIG. 11 (c), the operating member 33 is raised and the opening / closing operation pin 34 is tilted at the lower rib 36 as shown in FIG. 11 (b). The shoji support arm 30 rotates toward the room when pushed by the door, and the shoji 2 closes accordingly.
On the other hand, when the handle 23 is operated to the shoji opening side from the natural ventilation state shown in FIG. 11 (c), the operating member 33 is lowered and the opening / closing operation pin 34 is tilted by the upper rib 35 as shown in FIG. 11 (d). When pushed by the portion 35a, the shoji support arm 30 rotates outward, and the shoji 2 opens accordingly.
After that, when the handle 23 is further operated to the shoji opening side and the operation member 33 is lowered to the lowest position, the opening / closing operation pin 34 comes into contact with the vertical portion 35b of the upper rib 35 as shown in FIG. 11 (e). The shoji support arm 30 is locked in a state of being tilted by about 45 °, and the shoji 2 is maintained in a fully open state of being opened by about 45 ° (forced ventilation state).

As shown in FIG. 3, the guide rail 29 for guiding the slide shaft 5 of the shoji 2 is continuous with the vertical portion 29a parallel to the longitudinal direction of the mullion 4 and the upper end of the vertical portion 29a and is inclined toward the indoor side. It has an inclined portion 29b. When the shoji 2 is closed, the slide shaft 5 rises along the inclined portion 29b, so that the upper portion of the shoji 2 is pulled toward the room and is pressed against the tight material 38 of the upper frame 19. A lower limit stopper 39 is provided at the lower end of the vertical portion 29a, and the slide shaft 5 comes into contact with the lower limit stopper 39 when the shoji 2 is fully opened (forced ventilation state).

As shown in FIG. 3, a stopper device 6 for stopping the shoji 2 at a fixed position in a natural ventilation state is provided at a position on the indoor side of the guide rail 29 on the inner peripheral side surface of the mullion 4. As shown in FIG. 6, the stopper device 6 includes a base 40 attached to the inner peripheral side surface of the mullion 4, a stopper 7 rotatably supported on a support shaft 41 erected on the base 40, and a stopper 7 on the base 40. It has 8 rotary dampers attached to.
The stopper 7 has a protrusion 42 that protrudes toward the outdoor side and is located on the locus of the slide shaft 5, and a gear portion 43 that is provided concentrically with the support shaft 41 on the lower side of the support shaft 41. A spring 44 that urges the stopper 7 in a clockwise direction is held on the root side of the support shaft 41, and one end portion 44a of the spring 44 is locked to a spring hanging shaft 45 erected on the base 40. The other end 44b of the spring 44 is locked to the stopper 7. A stopper shaft 46 is provided on the base 40 to stop the force by which the spring 44 rotates the stopper 7 in the clockwise direction, whereby the stopper 7 is shown in FIG. 6 when it is not in contact with the slide shaft 5. It is held in place. A spring 47 is provided on the tip end side of the support shaft 41 to urge the stopper 7 in a counterclockwise direction. The spring 47 on the tip side of the support shaft is weaker than the spring 44 on the base side of the support shaft.
The rotary damper 8 is commercially available, and when the pinion gear 49 attached to the rotary shaft 48 meshes with the gear portion 43 of the stopper 7, and the stopper 7 rotates around the support shaft 41, the rotary shaft 48 rotates in conjunction with it. However, resistance is generated. The strength of the resistance increases as the rotation speed of the rotating shaft 48 increases. Further, the rotary damper 8 has a strong resistance when the rotating shaft 48 rotates clockwise, and a weak resistance when the rotating shaft 48 rotates counterclockwise.

FIG. 7 shows the operation of the stopper device 6 from the closed state of the shoji 2 to the natural ventilation state. FIG. 7A shows a state in which the shoji 2 is closed. At this time, the slide shaft 5 is located on the inclined portion 29b at the upper part of the guide rail 29 and is separated from the stopper 7.
When the handle 23 is operated to the shoji opening side, the shoji support arm 30 is unlocked by the operating member 33 as described above, and the shoji pushing member 71 (sliding on the shoji 21 in conjunction with the handle operation) ( (See FIGS. 24 and 25) pushes the lower part of the shoji 2 to the outdoor side to open the shoji 2, and the slide shaft 5 is lowered accordingly. As shown in FIG. 7 (b), the slide shaft 5 is a stopper 7. Contact the protrusion 42. The stopper 7 is pushed by the slide shaft 5 and rotates counterclockwise. Then, the spring 44 on the base side of the support shaft exerts a force to push the stopper 7 back clockwise, and the rotary damper 8 suppresses the rotation of the stopper 7. Resistance works.
As shown in FIG. 7C, when the shoji 2 is further opened and the slide shaft 5 is lowered due to a negative pressure applied to the shoji 2, the stopper 7 is rotated counterclockwise by being pushed by the slide shaft 5. , The spring 44 on the base side of the support shaft pushes the stopper 7 back clockwise, and at the same time, the rotary damper 8 acts as a resistance to suppress the rotation of the stopper 7.
After that, when the downward force of the slide shaft 5 becomes smaller than the reaction force of the spring 44 on the root side of the support shaft, as shown in FIG. 7D, the reaction force of the spring 44 on the base side of the support shaft causes the stopper 7 to move. Return to the position shown in FIG. 7 (b).

In this way, the sliding shaft 5 comes into contact with the stopper 7, so that the shoji 2 can be stopped at a fixed position when there is no wind, and the sliding door slides due to the natural wind or the difference in air pressure between indoors and outdoors. As the shaft 5 moves up and down in the range from the position when the shoji is closed shown in FIG. 7A to the position where the shaft 5 abuts on the stopper 7 shown in FIG. (Natural ventilation). When the stopper 7 is pushed by the slide shaft 5 and rotates from a fixed position, the spring 44 that pushes the stopper back and the rotary damper 8 that gives resistance to the rotation of the stopper 7 are provided, so that the shoji 2 is placed in the fixed position. It absorbs the impact when it stops and suppresses the fluttering of the shoji 2.

FIG. 8 shows the operation of the stopper device 6 from the closed state of the shoji 2 to the forced ventilation state. As shown in FIG. 8A, when the shoji 2 is closed, the slide shaft 5 is separated upward from the stopper 7, and the stopper 7 is stopped at a fixed position.
When the handle 23 is operated to the shoji opening side to open the shoji 2, the slide shaft 5 descends and comes into contact with the stopper 7, and the stopper 7 is pushed by the slide shaft 5 and counterclockwise, as shown in FIG. 8 (b). Rotate clockwise. At this time, the spring 44 on the root side of the support shaft exerts a force to push the stopper 7 back clockwise, and the rotary damper 8 acts to resist the rotation of the stopper 7.
After that, when the handle 23 is further operated to the shoji opening side, as shown in FIG. 8 (c), the stopper 7 is pushed by the slide shaft 5 and further rotates counterclockwise to mesh with the pinion gear 49 of the gear portion 43. Comes off. As a result, the resistance of the rotary damper 8 is eliminated, and the operating force of the handle 23 is reduced.
After that, when the handle 23 is further operated to the shoji opening side, as shown in FIG. 8D, the slide shaft 5 slides downward beyond the stopper 7 and comes into contact with the lower limit stopper 39 at the lower end of the guide rail 29. Stop. As a result, the shoji 2 is held in a state of being opened by about 45 °. After the slide shaft 5 slides downward beyond the protrusion 42 of the stopper 7, the stopper 7 rotates clockwise due to the reaction force of the spring 44 on the base side of the support shaft, and when the shoji is closed in FIG. 8A. Return to the state. At this time, the rotational direction of the rotary damper 8 is opposite (counterclockwise), so that the resistance is small.

As described above, in this fitting, the stopper 7 of the slide shaft 5 is a rotary type, and the slide shaft 5 moves downward beyond the stopper 7 to be in the forced ventilation state. When the forced ventilation state is set, the gear portion 43 and the pinion gear 49 are disengaged, so that the resistance of the rotary damper 8 does not work, so that the operating force can be reduced.

FIG. 9 shows the operation of the stopper device 6 from the forced ventilation state to the closed state of the shoji. As shown in FIG. 9A, the slide shaft 5 is separated downward from the stopper 7 in the forced ventilation state, and the stopper 7 is stopped at a fixed position.
When the handle 23 is operated to the shoji closing side, as shown in FIG. 9B, the slide shaft 5 rises as the shoji 2 closes, and the slide shaft 5 comes into contact with the protrusion 42 of the stopper 7 from below. ..
After that, when the handle 23 is further operated to the side of closing the shoji, as shown in FIG. 9C, the stopper 7 is pushed by the slide shaft 5 and rotates clockwise. At this time, only the reaction force of the weak spring 47 on the tip side of the support shaft is generated, and the reaction force of the spring 44 on the base side of the support shaft is not generated. Further, since the gear portion 43 is disengaged from the pinion gear 49, the resistance of the rotary damper 8 does not occur.
After that, when the handle 23 is further operated toward the shoji closing side, as shown in FIG. 9D, the slide shaft 5 rides over the protrusion 42 of the stopper 7 and slides upward, and the stopper 7 is a spring on the tip side of the support shaft. The reaction force of 47 returns to the original position.

As described above, in this fitting, the sliding shaft 5 of the shoji 2 hits the stopper 7 of the mullion 4, so that the shoji 2 can be stopped at a fixed position, and the plurality of shoji 2 and 2 of the continuous window are the same. By stopping at the position, there is a sense of unity and the appearance is good. Further, since the damper 8 operates when the stopper 7 is pushed by the slide shaft 5 and moves from the fixed position, the impact when the shoji 2 is stopped at the fixed position can be absorbed.
Since the stopper 7 is urged toward a fixed position where it can come into contact with the slide shaft 5, the stopper 7 can be returned to the fixed position after the stopper 7 moves from the fixed position and the damper 8 works.
Since the stopper 7 is provided so as to be rotatable and the damper 8 is a rotary damper 8 that meshes with the stopper 7, the stopper device 6 can be made compact and can be attached regardless of the size of the fitting.
Further, in this fitting, since the slide shaft 5 can move beyond the stopper 7, the shoji 2 can be opened wider than the fixed position.

In this fitting, the slide shaft 5 of the shoji 2 comes into contact with the stopper 7 of the vertical frame (mullion 4), so that the maximum opening angle of the shoji 2 in the natural ventilation state can be set at a fixed position. When placed, the left and right shoji screens 2 and 2 stop at the same position, so there is a sense of unity and the appearance is good. Further, when the slide shaft 5 moves beyond the stopper 7, the forced ventilation state can be obtained.
Further, since this fitting is provided with a damper 8 that suppresses the movement of the stopper 7 when the slide shaft 5 is in contact with the stopper 7, it absorbs the impact when stopping the shoji 2 and suppresses the fluttering of the shoji 2. Be done. Further, when the stopper 7 is pushed by the slide shaft 5 and rotates by a predetermined angle or more, the resistance of the rotary damper 8 disappears, so that the operating force in the forced ventilation state can be reduced.

The fitting includes a locking device 9 that locks the shoji 2 in conjunction with the closing operation when the handle 23 is operated to the shoji closing side to close the shoji 2. As shown in FIGS. 12 and 13, a horizontal slide bar 51 is provided on the upper surface of the transom 21 so as to be slidable in the longitudinal direction of the transom 21, and the horizontal slide bar 51 is a vertical frame as shown in FIG. It is connected by a vertical slide bar 31 that slides along 3 and a corner drive 52. Therefore, when the vertical slide bar 31 slides up and down by operating the handle 23, the horizontal slide bar 51 slides left and right in conjunction with it.

As shown in FIGS. 12 to 14, the locking device 9 has a pulling member 10 rotatably attached to a support shaft 53 perpendicular to the horizontal slide bar 51 and a side of the pulling member 10 opposite to the support shaft 53. It has a lock pin 11 provided on the outdoor side of the door and a lock receiver 12 provided on the lower frame 25 of the shoji 2 and engaged with the lock pin 11. The pulling member 10 is provided with an elongated hole 54 along the left-right direction, and the elongated hole 54 has a valley portion 55 protruding toward the indoor side at a position biased to one side in the left-right direction. .. A posture regulation pin 56 is fixedly provided on the transom light 21, and the posture regulation pin 56 is inserted into a long hole 54 of the pulling member 10. The pulling member 10 is urged by a spring 57 in a direction of rotating clockwise. A rubber roller 58 is attached to the outdoor side of the tip of the pulling member 10 in order to prevent the pulling member 10 from colliding with the shoji 2.

As shown in FIG. 15A, when the shoji 2 is in the open state (natural ventilation state or forced ventilation state), the pulling member 10 is in a position where it slides to the left and is fixed to the transom light 21. The pin 56 is locked to the indoor side edge 54a parallel to the longitudinal direction of the transom 21 on the right side of the valley 55 of the elongated hole 54, and the pulling member 10 is held in a direction parallel to the longitudinal direction of the transom 21. There is.
When the handle 23 is operated to the closing side of the shoji, the pulling member 10 slides to the right as the shoji 2 closes, rather than the lock pin 11 coming into contact with the lock receiver 12 of the shoji 2 as shown in FIG. 15 (b). Previously, the posture control pin 56 fixed to the transom light 21 enters the valley portion 55 of the elongated hole 54 of the pulling member 10, so that the pulling member 10 rotates outdoors with the support shaft 53 as a fulcrum. As a result, the lock pin 11 moves to the outside of the room and picks up the lock receiver 12 of the shoji 2. After that, as shown in FIG. 15 (c), the posture control pin 56 fixed to the transom light 21 While moving in the valley portion 55 of the elongated hole 54 of the pulling member 10, the lock pin 11 of the pulling member 10 comes into contact with the lock receiver 12 of the shoji 2.
After that, while the pulling member 10 is pulled to the right, the posture regulating pin 56 fixed to the transom light 21 rides on the inclined portion 55a of the valley portion 55 of the elongated hole 54 of the pulling member 10, so that the pulling member 10 Rotates indoors with the support shaft 53 as a fulcrum, and at this time, since the lock pin 11 is already engaged with the lock receiver 12, the shoji 2 is attracted to the indoor side.
After that, as shown in FIG. 15 (e), the posture control pin 56 fixed to the transom 21 rides on the indoor side edge 54b parallel to the transom longitudinal direction on the left side of the valley 55 of the pulling member 10. The pulling member 10 returns to a direction parallel to the longitudinal direction of the transom light 21, and the shoji 2 is closed and locked.

As described above, the present fitting has a pulling member 10 that slides in the frame 1 (eyeless 21) in conjunction with the opening and closing of the shoji 2, and the pulling member 10 engages with the lock receiver 12 of the shoji 2. It has a lock member (lock pin) 11 to be released, and when the lock member 11 engages with the lock receiver 12 in a state before the shoji 2 is completely closed, and the lock member 11 engages with the lock receiver 12, the pulling member 10 is engaged. Since the shoji 2 is rotated toward the room and pulled toward the room side, it is possible to prevent the lock from being unlocked even if negative pressure is applied to the shoji 2 when the shoji is closed.
The pulling member 10 is in a posture parallel to the longitudinal direction of the frame 1 (transom light 21) when the shoji 2 is open, and when the shoji 2 is closed, the pulling member 10 rotates once outdoors and then rotates indoors. When the shoji 2 is open, the pulling member 10 fits within the expected dimensions of the frame 1, and the pulling member 10 does not get in the way.

Further, as shown in FIGS. 1 and 2, this fitting is provided with a shock absorbing device 13 for absorbing the impact when the shoji 2 is vigorously closed by a strong wind in a natural ventilation state. 16 to 19 show a first embodiment of the shock absorbing device 13. The shock absorbing device 13 is attached to the inner peripheral side surface of the frame 1 (mullion 4), and includes a base 59 fixed to the mullion 4 with screws, a shock absorbing arm 14 pivotally supported by the base 59, and the like. It has a rotary damper 17 attached to the base 59.
The shock absorbing arm 14 includes a first arm 14a pivotally supported by a rotating shaft 60 erected on the base 59 and a second arm 14b pivotally supported by another rotating shaft 61 located above the first arm 14a. The second arm 14b is urged by a spring 62 so as to rotate toward the outdoor side as shown in FIG. 17, and the tip portion of the second arm 62 is formed. The pin 63 is locked to the elongated hole 64 provided in the first arm 14a, and when the obstacle 2 is open, the pin 63 is locked to the end of the elongated hole 64 on the rotation shaft 60 side. Then, the shock absorbing arm 14 is held at an angle of about 45 ° so as to protrude from the frame 1 to the outside of the room. A rubber roller 18 serving as a shoji contact portion is provided at the tip of the first arm 14a. The rubber roller 18 serves as an action point when the shock absorbing arm 14 is pushed by the shoji 2 and rotates toward the room side, and as shown in FIG. 18A, the chamber of the vertical frame 26 of the shoji 2 It comes into contact with fins 66 provided so as to project outward on the outer peripheral side. A gear 15 is fixedly provided to the first arm 14a on the opposite side of the rubber roller 18 (point of action) with respect to the rotation shaft 60 of the first arm 14a, and the first arm 14a is provided when the shoji is closed. When rotating toward the indoor side, the gear 15 also rotates about the rotation shaft 60.
The rotary damper 17 is arranged below the rotary shaft 60 of the first arm 14a, and the pinion gear 16 attached to the rotary shaft 68 meshes with the gear 15 of the shock absorbing arm 14, and when the shock absorbing arm 14 rotates, it engages with the pinion gear 16. The rotating shaft 68 rotates in conjunction with the rotation, and resistance is generated. The strength of the resistance increases as the rotation speed of the rotation shaft 68 increases. The ratio of the pitch circle diameters of the gear 15 of the shock absorbing arm 14 and the pinion gear 16 of the rotary damper 17 is 6: 1. Therefore, the rotation of the rotary damper 17 is 6 times as large as the rotation of the shock absorbing arm 14. It will be accelerated.

When the shoji 2 is closed by receiving a positive pressure in the natural ventilation state, the rubber roller 18 is pushed by the shoji 2 and the shock absorbing arm 14 rotates toward the indoor side as shown in FIG. At this time, a reaction force that pushes the shock absorbing arm 14 back to the outdoor side acts by the spring 62, and the rotary damper 17 rotates in conjunction with the movement of the shock absorbing arm 14, thereby suppressing the rotation of the shock absorbing arm 14. Resistance arises. As a result, the impact when the shoji 2 is closed is absorbed, and it is possible to prevent the generation of noise and the damage of the shoji 2 and the frame 1.
Since the strength of the resistance due to the rotary damper 17 increases according to the moving speed of the shock absorbing arm 14, the moving speed of the shock absorbing arm 14 is slow at a wind speed of 5 m or less, so that the resistance of the rotary damper 17 is weak and exclusively. The spring 62 absorbs the impact. When the wind speed is 5 m or more, the shock absorbing arm 14 moves faster, so that the shock is mainly absorbed by the rotary damper 17.
When the handle 23 is operated to close the shoji 2, the shock absorbing arm 14 moves slowly, so that the resistance of the rotary damper 17 becomes weak. When the shoji 2 is closed, as shown in FIG. 18, the entire shock absorbing device 13 including the shock absorbing arm 14 fits within the prospect of the frame 1.

As described above, since the fitting has an impact absorbing device 13 that absorbs the impact when the shoji 2 closes, it absorbs the impact when the shoji 2 receives the wind and closes, and the window is damaged or impacted. Sound can be prevented. The shock absorbing device 13 is provided via gears 15 and 16 on the opposite side of the action point (rubber roller 18) with respect to the shock absorbing arm 14 that rotates with the closure of the shoji 2 and the rotating shaft 60 of the shock absorbing arm 14. Since it is composed of a rotary damper 17 that rotates in conjunction with the movement of the shock absorbing arm 14, the structure is simple and can be made inexpensive.
In the shock absorbing device 13, the shoji contact portion (rubber roller 18) at the tip of the shock absorbing arm 14 protrudes to the outside of the frame 1 with the shoji 2 open, and the stroke of the shoji contact portion in the indoor / outdoor direction is increased. Since it is large, the range in which the movement of the shoji 2 can be controlled is large, and the shock absorption performance is high. Moreover, when the shoji 2 is closed, the entire shock absorbing device 13 fits within the prospect of the frame 1, and the shock absorbing device 13 does not protrude into the indoor side of the frame 1, so that the shock absorbing device 13 does not get in the way. In addition, the interior design of the window can be improved.
Since the rotary damper 17 rotates in conjunction with the movement of the shock absorbing arm 14 via the gears 15 and 16, the rotation of the rotary damper 17 can be made faster and larger than the rotation of the shock absorbing arm 14. As a result, the impact can be efficiently absorbed with a small damper.

FIG. 20 shows a second embodiment of the shock absorbing device 13. This embodiment is also attached to the frame 1, and the rubber roller 18 serving as the shoji contact portion is not the first arm 14a to which the gear 15 is attached, but the second arm 14b urged by the spring 62. It is attached to the tip of the rubber. The first arm 14a is provided with an elongated hole 64 in which a pin 63 attached to the second arm 14b is engaged, and the elongated hole 64 is inclined at both ends with respect to the longitudinal direction of the first arm 14a. It has a corrugated shape having inclined portions 64a and 64b and a parallel portion 64c parallel to the longitudinal direction of the first arm 14a in the intermediate portion.

In the shock absorbing device 13, the second arm 14b is pushed by the shoji 2 to rotate, and the first arm 14a to which the gear 15 is attached is pulled by the pin 63 engaged with the elongated hole 64 to rotate. In the initial stage of contacting the shoji 2, as shown in FIG. 21A, the pin 63 is located at the inclined portion 64a of the elongated hole 64, so that the first arm is relative to the rotation amount of the second arm 14b. The amount of rotation of 14a is small, and therefore the resistance of the rotary damper 17 is small. When rotated indoors to some extent, as shown in FIGS. 21 (b) and 21 (c), the pin 63 is located at the parallel portion 64c of the elongated hole 64, so that the amount of rotation of the first arm 14a is the second arm 14b. Therefore, the resistance of the rotary damper 17 becomes stronger. Immediately before the shoji 2 is completely closed, as shown in FIG. 21D, the pin 63 is located at the inclined portion 64b of the elongated hole 64, so that the first arm 14a is relative to the rotation amount of the second arm 14b. The amount of rotation of the rotary damper 17 is small, and therefore the resistance of the rotary damper 17 is small.
As described above, the shock absorbing device 13 of the present embodiment starts and ends in the movement of the shock absorbing arm 14 from the time when the shoji contact portion (rubber roller 18) comes into contact with the shoji 2 until the shoji 2 is closed. The resistance can be weakened and the resistance can be increased in the middle, so that when the handle 23 is operated to close the shoji 2, the operation can be smoothly performed without discomfort.

FIG. 22 shows a third embodiment of the shock absorbing device 13. In this shock absorbing device 13, the shock absorbing arm 14 is composed of a single arm, and a rubber roller 18 serving as an action point is provided at the tip thereof, and the rubber roller 18 is provided with respect to the rotation shaft 60 of the shock absorbing arm 14. A gear 15 is provided on the opposite side to the above side, and the gear 15 meshes with the pinion gear 16 attached to the rotating shaft 68 of the rotary damper 17. The shock absorbing arm 14 is urged by a spring 62 in a direction in which the rubber roller 18 projects outward, and the pin 70 fixed to the base 59 is engaged with the elongated hole 64 provided in the shock absorbing arm 14. , The movable range of the shock absorbing arm 14 is regulated. The entire shock absorbing device 13 is within the range of the frame 1 even when the shoji 2 is open.

As shown in FIG. 23, the shock absorbing device 13 is attached near the lower part of the guide rail 29 on the inner peripheral side surface of the mullion 4, and when the shoji 2 is closed, the rubber roller 18 comes into contact with the shoji support arm 30. When pushed, the shock absorbing arm 14 rotates toward the room, and the reaction force of the spring 62 and the resistance of the rotary damper 17 can absorb the shock when the shoji 2 is closed.

As shown in FIG. 24, the shock absorbing device 13 of the third embodiment can also be attached to the lower stile 25 of the shoji 2. Reference numeral 71 in the drawing is a shoji pushing member for pushing the lower part of the shoji 2 to the outdoor side when the shoji 2 is opened by sliding left and right together with the horizontal slide bar 51.

As shown in FIG. 25-1 (a), when the shoji 2 is closed, the shoji extrusion member 71 is in a position where it escapes to the side of the rubber roller (frame contact portion) 18 of the shock absorbing arm 14.
When the handle 23 is operated to the shoji opening side, as shown in FIG. 25-1 (b), the shoji extrusion member 71 slides toward the shock absorber 13, and the rubber roller 18 is pushed by the inclined surface 71a of the shoji extrusion member 71. By doing so, the shoji 2 opens.
In the natural ventilation state, as shown in FIG. 25-1 (c), the rubber roller 18 of the shock absorbing arm 14 is located at a position facing the outdoor side of the shoji extrusion member 71, and the shoji 2 is in the natural wind or indoors and outdoors. When the rubber roller 18 comes into contact with the shoji extrusion member 71 of the frame 1, the shock absorbing arm 14 rotates, and the reaction force and rotation of the spring 62, as shown in FIG. 25-2 (d). The resistance of the type damper 17 absorbs the impact when the shoji 2 is closed.
When the handle 23 is operated to close the shoji 2, as shown in FIG. 25-2 (e), the shoji pushing member 71 slides sideways as the shoji 2 is closed, so that the shock absorbing device 13 slides the shoji. It does not prevent the closing of 2 and the operating force of the handle 23 does not become heavy.

26-28 show other embodiments of fittings according to the present invention. This fitting is applied to a hanger-type partition, and is a rail 72 fixed to a ceiling or the like, and a door suspended from the rail 72 by a hanging door wheel 73 and a slide shaft 5 so as to be slidable along the rail 72. A 74 and a stopper device 6 attached adjacent to the rail 72 are provided. The stopper device 6 is the same as that shown in FIG. 6 and the like described above.

As shown in FIG. 28A, when the door 74 is slid to the right and opened, the stopper 7 is pushed by the slide shaft 5 and rotates counterclockwise, and the slide shaft 5 pushes the stopper 7. You can slide over and to the right.
When the door 74 is slid to the left to close, as shown in FIG. 28 (b), the slide shaft 5 comes into contact with the stopper 7, so that the door 74 stops at a fixed position. As a result, it is possible to prevent a finger from being caught between the door 74 and the wall or the like. When the door is stopped by the 74 stopper 7, the reaction force of the spring 44 that urges the stopper 7 to the fixed position and the resistance of the rotary damper 8 act, so that the impact when the door 74 is stopped to the fixed position can be absorbed. ..

The present invention is not limited to the embodiments described above. The composition of the frame and shoji, and how to open the shoji are arbitrary. The form of the shock absorbing arm can be changed as appropriate. The present invention can be applied to windows other than natural ventilation windows.

1 frame 2 shoji (door)
3 Vertical frame 4 Mullion (Vertical frame)
5 Slide shaft 6 Stopper device 7 Stopper 8 Rotating damper (damper)
9 Locking device 10 Pulling member 11 Locking pin (locking member)
12 Lock receiver 13 Shock absorber 14 Shock absorption arm 15 Gear 16 Pinion gear (gear)
17 Rotary damper 18 Rubber roller (point of action)
72 rails (frame)
74 units

Claims (1)

It is provided with a frame, a shoji, and a shock absorbing device. The shock absorbing device absorbs the shock when the shoji is closed, and the shock absorbing arm that rotates with the closing of the shoji and the rotation of the shock absorbing arm. A fitting characterized by having a rotary damper that rotates in conjunction with the movement of the shock absorbing arm via a gear on the side opposite to the point of action with respect to the shaft.

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