JP2012112243A - Sliding door closer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a sliding door closer that enables the use of a standard type sash roller and that can also be used for a normal sliding door.SOLUTION: A sliding door closer includes a spiral spring and a damper mechanism that applies a damper force to a sliding door via a wire. The sliding door closer makes the sliding door self-closed by a spring force of the spiral spring. One or more pulleys for offsetting or changing a wire pulling direction are attached to a surface orthogonal to a surface for attaching a spiral spring pulley housing the spiral spring and a damper pulley housing the damper mechanism, near a wire pull-out portion of the sliding door body.

Description

  The present invention automatically closes the sliding door after opening by winding a wire laid between the building (for example, a sliding door frame) and the sliding door using the spring force of the mainspring (hereinafter, referred to as “the sliding door”). It relates to a sliding door closer.

  Conventionally, as this type of sliding door closer, for example, the one described in Patent Document 1 is known. That is, as shown in FIG. 14, this includes a damper unit 101, a mainspring unit 102, a mainspring 103 whose tip is fixed to a shaft 109 accommodated in the mainspring unit 102, a wire turbulence means 104, and a wire 105. It is equipped.

  This sliding door closer requires an excessive external force to close the sliding door 106 by pinching a hand with an excessive closing inertia force of the sliding door 106 due to the return force of the mainspring 103 or by providing an excessive damper function of the damper unit 101 exceeding the returning force. Such a problem can be solved by appropriately selecting and setting the damper function. In addition, the code | symbol 107 in a figure shows the housing | casing part of a sliding door closer. Moreover, arrow A shows a door opening direction and B shows a door closing direction.

Utility Model Registration No. 3101743 (FIG. 3)

  In the sliding door closer shown in FIG. 14, for example, when changing the spring force (returning force) of the mainspring 103, the central shaft 109 around which the mainspring 103 is wound is rotated by a screwdriver or the like. It is also possible to make fine adjustments with. However, if the shaft 109 is rotated in the opposite direction to increase the spring force, or if the shaft 109 is excessively rotated when the spring force is weakened, the tip of the mainspring 103 comes out of the shaft 109. There is a possibility that the front end side of the mainspring 103 may be broken.

  Furthermore, in such a sliding door closer, for example, by attaching the closer to one of the two sliding doors and fixing the other sliding door, such as a sliding door closer, one of the sliding doors is self-closing. There is a demand for the development of a sliding door having a configuration (hereinafter referred to as a “double sliding door closer”). However, in such a double sliding door closer, when the end of the wire pulled out from one closer is attached and fixed to the other sliding door, in order to avoid collision between the two sliding doors, the wire is pulled from one sliding door. When pulling out, it is necessary to offset the wire (displacement position), and it has been difficult to apply the wire as it is with a conventional sliding door closer.

  In addition, when the sliding door closer as shown in FIG. 14 is not provided in a bare state but is a self-closing type sliding door that is housed in the sliding door and has a good appearance, in the state of horizontal placement (horizontal placement) shown in FIG. If it is tilted 90 degrees and placed vertically, it can be stored in a sliding door. However, in such a vertical type closer, when adjusting the spring force of the mainspring, the end of the shaft 109 is exposed to the front side (perpendicular to the door contact surface) of the sliding door. It is necessary to insert a screwdriver through the hole on the front side and rotate the shaft. Thus, since it is necessary to provide the hole for operation of the shaft edge part in the sliding door front side, an aesthetics is not good.

  Furthermore, in the case of a double sliding door closer that has two or more sliding doors as described above, if the opening direction is mistakenly pushed out in the closing direction, the sliding door will be suddenly closed with a strong closing force. It is conceivable that a high collision sound is generated.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a sliding door closer in which the mainspring does not come out of the shaft or break when adjusting the return force of the mainspring. Another object of the present invention is to provide a sliding door closer that can offset or change the direction of a wire suitable for installation in a double sliding door closer. Another object of the present invention is to provide a sliding door closer that can adjust the return force of the mainspring without providing a hole or the like for operating the shaft end on the front side of the sliding door, and has a good appearance. Furthermore, an object of the present invention is to provide a sliding door closer that makes a loud sound and does not strongly collide with the door stop even if the sliding door is pushed out in the closing direction by mistake.

  In order to achieve the above object, the sliding door closer of the present invention is a sliding door closer that self-closes the sliding door by the spring force of the mainspring housed in the mainspring pulley, and the mainspring is provided on the center side of the mainspring pulley. The presser plate is wound in a state in which the tip end is engaged with the groove of the shaft, and a presser plate is provided in the groove of the shaft to hold the front end part of the mainspring and prevent it from coming off, Is that the cross section is substantially Z-shaped.

  The sliding door closer of the present invention is a sliding door closer comprising a mainspring and a damper mechanism that imparts a damper force to the sliding door through a wire, and the sliding door closer that self-closes with the spring force of the mainspring. A pulley for offsetting or changing the direction of pulling of the wire on a surface perpendicular to a spring pulley for housing the mainspring and a damper pulley for housing the damper mechanism in the vicinity of the wire drawing portion of the wire. It is characterized in that one or a plurality are attached.

  The sliding door closer according to the present invention includes a mainspring housed inside a mainspring pulley, and a damper mechanism that applies a damper force to the sliding door via a wire, and the sliding door closer that self-closes the sliding door with the spring force of the mainspring. The spring force of the mainspring can be adjusted from the outside of the surface in the direction orthogonal to the opening / closing direction of the sliding door.

  The means for adjusting the tensile force of the wire includes one or a plurality of rotating plates provided in connection with a shaft mounted inside the mainspring pulley and winding the tip of the mainspring, and a rotating shaft of the rotating plate. And an adjustment member having an engaging portion that engages with an engaged portion provided along or near the outer peripheral edge portion of the rotating plate. Good.

  The sliding door closer of the present invention includes a mainspring and a damper mechanism that imparts a damper force to the sliding door via a wire, and is a sliding door closer that self-closes the sliding door with the spring force of the mainspring. It has a closing speed restricting means for restricting the closing speed.

  A sliding door frame in the vicinity of the closing of the sliding door is installed in a state facing the portion of the outer peripheral surface of the damper pulley that accommodates the damper mechanism, avoiding the wire V-groove, and includes an elastic body that brakes the rotational movement of the damper pulley. It may be configured. Further, a configuration in which a pinion is provided on the outer peripheral surface of the damper pulley in the vicinity of closing and a rack that meshes with the pinion is provided in a sliding door frame may be employed.

  According to the present invention, it is possible to provide a sliding door closer in which the mainspring does not come out of the shaft or break when adjusting the return force of the mainspring. Moreover, according to this invention, the position of the wire suitable for making it install in a double type sliding door closer etc. can be offset, and the sliding door closer which can change a direction can be provided. Further, according to the present invention, it is possible to adjust the return force of the mainspring without providing a hole or the like for operating the shaft end portion on the front side of the sliding door, and it is possible to provide a sliding door closer with excellent aesthetics. Furthermore, according to the present invention, it is possible to provide a sliding door closer that makes a loud sound and does not collide strongly with the door stop even if the sliding door is pushed out in the closing direction by mistake.

It is a block diagram which shows the mainspring mechanism used for the sliding door closer which concerns on 1st Embodiment of this invention. It is explanatory drawing which shows a state when a shaft is reversely rotated in the mainspring mechanism shown in FIG. 1 (a return force is weakened). It is an enlarged view which shows the principal part of the mainspring mechanism shown in FIG. The sliding door which built the sliding door closer which concerns on the 2nd Embodiment of this invention is shown, (A) is sectional drawing of the sliding door which incorporates the sliding door closer, (B) is a top view which shows the principal part. is there. (A) is a top view which shows the upper surface of the sliding door which installed the sliding door closer which concerns on the 2nd Embodiment of this invention, (B) is the BB sectional drawing. It is a top view which shows the modification of the sliding door closer. It is a top view which shows the other modification of the sliding door closer. (A) is a top view which shows the upper surface of the sliding door which installed the sliding door closer of the further another modification of the sliding door closer, (B) is the sectional drawing. It is sectional drawing which shows another another modification of the sliding door closer. (A) is a cross-sectional view showing a configuration of a sliding door closer according to a third embodiment of the present invention, (B) is a longitudinal cross-sectional view thereof, and (C) is an explanatory view showing the principle of this embodiment. (A) is sectional drawing which shows the structure of the modification of the sliding door closer which concerns on the 3rd Embodiment of this invention, (B) is explanatory drawing which shows the principle. (A) is explanatory drawing which shows the sliding door which installed the sliding door closer which concerns on the 4th Embodiment of this invention, (B) is the sectional drawing. (A) is explanatory drawing which shows the sliding door which installed the thing of the modification of the sliding door closer, (B) is the sectional drawing. (A) is a perspective view which shows the sliding door which attached the conventional sliding door closer, (B) is explanatory drawing which shows the structure of the conventional sliding door closer.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
(First embodiment)
FIG. 1 shows a mainspring mechanism 1 of a sliding door closer (hereinafter abbreviated as “closer”) that automatically closes a sliding door with the spring force of the mainspring according to the first embodiment of the present invention. The mainspring 11 is housed in a mainspring pulley 10 and includes a wound mainspring 11, a shaft 12 for fixing the mainspring 11, and a pressing plate 13 attached to the shaft 12. In addition, the code | symbol 2 in a figure shows a wire.

  The mainspring 11 has a central end portion (tip) 11A engaged with a shaft 12 provided at the central portion of the mainspring pulley 10. That is, the mainspring 11 is sandwiched in a state where the tip 11A is bent into a substantially V shape and inserted into the groove 12A of the shaft 12. Further, one end (tip) of the wire 2 is connected to the outer periphery of the mainspring 11, and the other end (base end) of the wire 2 is fixed to a building side (not shown).

  The shaft 12 is formed of a cylindrical member that is rotatably installed at the center of the mainspring pulley 10 and is provided with the aforementioned groove 12A so as to divide the shaft 12 from the center.

  The presser plate 13 presses the front end 11A of the mainspring 11 to prevent the mainspring 11 from coming off, and the press plate 13 has a substantially Z-shaped cross section in the groove 12A of the shaft 12 into which the mainspring front end 11A is inserted. It is dressed together.

  Therefore, according to the present embodiment, when the return force is adjusted by changing the spring force of the mainspring 11, the return force can be adjusted by inserting and rotating the groove 12A of the shaft 12 using a screwdriver or the like. . For example, when increasing the return force, the shaft 12 in FIG. 1 may be rotated clockwise.

  On the other hand, when the return force is decreased, the shaft 12 in FIG. 1 may be rotated counterclockwise (the direction of FIGS. 2 and 3). However, when the return force is decreased, if the unfamiliar operator or the like mistakes the amount of angle and turns it too much, the mainspring tip 11A may come out of the groove 12A or break. However, according to the present embodiment, such troubles can be prevented even when the vehicle is rotated too much.

  That is, as shown in FIG. 3, when the shaft 12 is rotated counterclockwise, the circumferential portion 11C near the weakly strong portion (weakest portion) 11B bent near 90 degrees of the mainspring tip 11A is pressed down. The inner surface of the one end portion 13A of the plate 13 is contacted. For this reason, the mainspring 11 can prevent the circumferential portion 11C in the vicinity of the weakest portion 11B from pushing outward and causing the tip 11A to escape from the groove 12A.

(Second Embodiment)
Next, a second embodiment according to the present invention will be described. In the present embodiment, the same parts as those in the first embodiment are denoted by the same reference numerals to avoid redundant description. FIG. 4 shows a sliding door closer (double sliding door closer) 3 according to the present embodiment, and this sliding door closer 3 includes a pair of sliding doors 4 and 5, and one sliding door (hereinafter referred to as a movable side sliding door) 5. The sliding door (hereinafter, fixed-side sliding door) 4 that is fixed is self-closed.

  In the fixed side sliding door 4, the base end of the wire 2 is fixed to a fixing member 41 provided on the ceiling surface 4 </ b> A. In addition, this ceiling surface 4A exists in the same level (surface state) as the ceiling surface 5B which attaches the pulley which the movable side sliding door 5 mentions later.

  The movable-side sliding door 5 is provided with a damper force applied to the sliding door 5 via the mainspring device 31 and the wire 2 that apply a return force (self-closing force) to the movable-side sliding door 5 inside the main body 5A of the sliding door 5. The apparatus 32 is provided, and two pulleys (hereinafter referred to as first and second pulleys 51 and 52) for offsetting the drawing direction of the wire 2 are attached to the ceiling surface 5B of the main body 5A.

  In the mainspring device 31, a mainspring mechanism (not shown) (including a mainspring) is accommodated in a later-described mainspring pulley 31A, and is attached to the front surface which is an attachment surface of the main body 5A. On the other hand, the damper device 32 includes a damper pulley 32A (described later) that houses a damper mechanism (not shown) (using a blade rotation resistance to liquid, etc.), and is similarly attached to the front side of the main body 5A.

  The first and second pulleys 51 and 52 are installed in the vicinity of the wire drawing portion of the ceiling surface 5B of the main body 5A, which is a surface orthogonal to the mounting surfaces (front surfaces) of the mainspring device 31 and the damper device 32. In particular, the first and second pulleys 51 and 52 are arranged in a state in which they are close to each other with a very small distance therebetween, thereby preventing the wire 2 from coming out between these pulleys. In the present embodiment, the second pulley 52 is made larger in diameter than the first pulley 51 so that the drawing position of the wire 2 is largely shifted (offset).

  Therefore, according to the present embodiment, the sliding door can be automatically closed by offsetting the drawing position of the wire 2 by the first and second pulleys 51 and 52, and a self-closing sliding door can be realized.

  In the present embodiment, the second pulley 52 has a large diameter. However, as shown in FIG. 5, a pair having the same diameter may be installed. Also in this case, the wire 2 can be pulled out and offset. Therefore, the wire 2 avoids the support portion 532 that rotatably supports the wheel 531 in the suspension wheel 53 that is fixed to the ceiling surface 5B of the sliding door 5 in order to suspend the sliding door 5 on the guide rail 61 on the door frame 6 side. Can pass through.

  In this embodiment, the drawing position of the wire 2 is greatly shifted (offset) by two pulleys, but the drawing position of the wire 2 is offset by only one pulley 52 as shown in FIG. You may make it make it. Moreover, as shown in FIG. 7, it is good also as a structure which changes the running direction of the wire 2 simultaneously with offsetting the drawer position of the wire 2 only with the single pulley 52. FIG. 6 and 7, the traveling position of the wire 2 can be offset from the support portion 532 of the suspension vehicle 53, so that a standard type suspension vehicle can be used, as shown in FIG. 4. Such a normal sliding door can be used.

  Moreover, in this embodiment, although the 1st, 2nd pulleys 51 and 52 are installed in the movable side sliding door 5, as shown in FIG. While installing, the fixing member 54 may be installed in the ceiling surface 5B of the movable-side sliding door 5, and the base end of the wire 2 may be fixed to this.

  Further, as shown in FIG. 9, the sliding door closer 3 is built in the wall 7 side, and a fixing member 54 for fixing the proximal end of the wire 2 to the movable side sliding door 5 (near 6A per door) is installed. It is good. Also in this case, by installing the first and second pulleys 71 and 72 on the wall 7 side, the traveling direction of the wire 2 can be changed from the drawing position of the wire 2, so that the sliding door with respect to the wall 7 Even if 5 is installed in a direction perpendicular to or 90 °, a self-closing sliding door can be realized.

(Third embodiment)
Next, a third embodiment according to the present invention will be described. In the present embodiment, the same parts as those in the first and second embodiments are denoted by the same reference numerals to avoid redundant description. FIG. 10 shows the sliding door closer 3 according to the present embodiment. The sliding door closer 3 is orthogonal to the opening / closing (α) direction of the sliding door in the casing 30 that houses the mainspring device 31 and the damper device 32 (building). There is provided a tensile force adjusting means 8 capable of adjusting the tensile force of the wire 2 with a screwdriver or the like from the end face 30A side facing the door stop (not shown) of the sliding door frame. Moreover, in this embodiment, although the wire 2 is installed in the state inclined diagonally with respect to the horizontal direction, you may install in a horizontal state like 2nd Embodiment.

  The tensile force adjusting means 8 of the present embodiment adjusts the tensile force of the wire 2 by changing the spring force of the mainspring 11, and includes a rotating plate 81 and an adjusting member 82.

  Of these, the rotating plate 81 is composed of a single disc having a function as a sprocket, and is integrated with the shaft 12 wound in a state where the front end of the mainspring 11 is fixed at the central portion of the mainspring pulley 31A. It is linked to. The rotating plate 81 has a plurality of small holes 81A, which are engaged portions, formed at equal intervals along the outer peripheral edge (or the vicinity of the outer peripheral edge). Note that the rotation axis of the rotary plate 81 is also used as the shaft 12, and the rotary plate 81 is integrally fixed to the shaft 12. Accordingly, by rotating the rotating plate 81, the mainspring 11 is also rotated, and the spring force of the mainspring 11 can be adjusted.

  The adjustment member 82 is for enabling the spring force of the mainspring to be adjusted from the outside of the casing 30 by a driver or the like from the end face 30A side facing the door stop on the sliding door frame side on the building side. Are arranged in an orthogonal direction (opening / closing direction of the sliding door). The adjustment member 82 includes an operation shaft 821 and a pinion (small gear) 822 that is integrally fixed to the operation shaft 821.

  The operation shaft 821 has a head portion 821A protruding from the end face 30A of the casing 30, and the operation shaft 821 is rotated by engaging a driver tip or the like in a groove 821B provided in the head portion 821A.

  The pinion 822 is fixed to the end opposite to the head 821A, which is the end of the operation shaft 821, and is constituted by a small gear provided with a large number of teeth. The pinion 822 can rotate the adjusting member 82 by engaging the tooth tip 822A with the small hole 81A of the rotating plate 81 (composing an engaging portion).

  The stopper pin 823 holds the rotating plate 81 (integrated with the mainspring pulley 31 </ b> A) in a fixed (locked) state with respect to the casing 30. One or a plurality of stopper pins 823 are fixed to the inner wall of the casing 30. It is comprised by the pin, and is installed in the appropriate position so that it can be inserted in the small hole 81A of the rotating plate 81.

  This stopper pin 823 is normally fitted into the small hole 81A of the rotating plate 81 to fix the rotating plate 81, and thus the base end of the mainspring 11, and is pulled by the wire 2 particularly when the sliding door is opened. Thus, the mainspring 11 has a mainspring fixing force that allows the mainspring 11 to be wound up. Further, when the spring force of the mainspring 11 is changed to adjust the return force of the sliding door, the rotating plate 81 is rotated by the rotation operation force of the operation shaft 821 exceeding the stop force (spring fixing force) of the stopper pin 823. The stop force of the stopper pin 823 is set to the extent that can be allowed.

  In this embodiment, a stopper pin 823 is provided in order to fix and hold the rotating plate 81 in a locked state. However, instead of attaching this stopper pin 823, it is not during the spring force change operation of the mainspring. In this case, the rotation plate 81 may be provided with a function that can maintain the rotation stop state.

  Therefore, according to the present embodiment, when adjusting the return force of the sliding door by changing the spring force of the mainspring 11, the rotating plate 81 is desired with the rotational operation force of the operation shaft 821 exceeding the stop force of the stopper pin 823. It is only necessary to rotate in the direction of. Moreover, according to the present embodiment, the hole for changing the spring force of the mainspring 11 is not formed on the front side of the sliding door where the sliding door is conspicuous (considering the design), but on the end surface 30A of the sliding door orthogonal to this. Since it can be installed, it looks good.

  Further, in this embodiment, the tensile force adjusting means 8 is composed of one rotating plate 81 and the adjusting member 82. However, in addition to this, for example, instead of one rotating plate 81 as shown in FIG. You may comprise two (or more) gear trains.

That is, as shown in FIG. 11, the tensile force adjusting means 8A includes first and second geared adjustment plates 83 and 84 and an adjustment member 82 engaged with the second geared adjustment plate 84. ing.
Of these, the first geared adjustment plate 83 is fixed integrally with the shaft 12 and is rotatable with respect to the inner wall of the casing 30, and outer teeth 83 </ b> A are provided on the outer periphery. On the other hand, the second geared adjustment plate 84 has external teeth 84A meshing with the external teeth 83A along the outer periphery, and has a small hole 84B along the outer peripheral edge portion closer to the inside than the external teeth 84A. This is also functioning as a sprocket.

  Therefore, with such a gear train, when the adjustment member 82 is rotated from the end face 30A side of the casing 30, the first geared adjustment plate 83 is reliably rotated with a small rotational force, so that the mainspring 11 can be rotated. The spring force can be changed.

(Fourth embodiment)
Next, a fourth embodiment according to the present invention will be described. In the present embodiment, the same parts as those in the first to third embodiments are denoted by the same reference numerals to avoid redundant description.
FIG. 12 shows a sliding door 5 in which the sliding door closer 3 according to the present embodiment is installed, a sliding door frame 6 on the building side in which the sliding door 5 is suspended, and the like. The sliding door frame 6 includes a closed door when the sliding door 5 is closed. An elastic body 9A is provided as a closing speed regulating means for regulating the speed. In addition, the code | symbol 6A in a figure shows the door stop on the building side.

  The elastic body 9A is for suppressing the return force of the sliding door 5 by the wire 2, and is formed of a material having a large friction coefficient such as rubber, and is installed on the door frame 6 in the vicinity when the sliding door 5 is closed. Yes. The elastic body 9A of the present embodiment is provided on one surface of the sliding door frame 6 facing the outer peripheral surface of the damper pulley 32A. Specifically, the sliding door frame 6 near the closing of the sliding door 5 is installed in a region through which a part of the outer peripheral surface of the damper pulley 32A that houses the damper mechanism passes. In particular, since the wire V-groove 321 is formed on a part of the outer peripheral surface of the damper pulley 32A, the elastic body 9A is installed in a region through which a portion avoiding the wire V-groove passes.

  Therefore, according to the present embodiment, for example, when the sliding door is accidentally pressed strongly in the closing direction, the wire 2 is lifted from the V groove 321 of the damper pulley 32A, and the damper force does not work, so that the sliding door 5 tends to be closed quickly. . At that time, the damper pulley 32 </ b> A that rotates with the closing operation of the sliding door 5 contacts and slides on the elastic body 9 </ b> A, so that the damper works reliably and the closing speed when the sliding door 5 is closed can be regulated. Thereby, it can prevent making a loud noise and colliding strongly with the door stop. In this embodiment, the elastic body 9A is in contact with and slides on the outer peripheral surface of the damper pulley 32A. However, a material that causes friction other than the elastic body may be used.

  In the present embodiment, the closing speed regulating means is formed by forming an elastic body 9A formed of a material having a large friction coefficient such as rubber on a surface facing the outer peripheral surface of the damper pulley of the door frame 6. However, for example, a rack and pinion mechanism as shown in FIG. 13 may be used.

  That is, this is provided with a rack 9B in the door frame 6 in the vicinity of closing, and a pinion 9C that meshes with the rack 9B on a part of the outer peripheral surface of the damper pulley 32A.

  The present invention is not limited to the embodiment described above, and can be implemented in various forms without departing from the scope of the invention.

  The sliding door closer according to the present invention has the effect of improving the reliability without causing the mainspring to come out of the shaft or breakage when adjusting the return force of the mainspring. Useful as a device. Further, according to the present invention, a wire suitable for being installed in a double sliding door closer or the like can be shifted or changed in direction, so that the self-closing device can be directly installed on a sliding door to which a commercially available suspension vehicle is attached. Useful as. In addition, according to the present invention, it is possible to adjust the return force of the mainspring without adding a hole or the like for operation of the shaft end on the front side of the sliding door by simply installing a few parts on a commercially available sliding door or the like. Can provide a good sliding door closer. Furthermore, according to the present invention, even if the sliding door is accidentally pushed in the closing direction, there is an effect that a high-quality sound can be obtained without making a strong noise and strongly colliding with the door stop, which is slightly different from a commercially available sliding door or the like. Since it is only necessary to install additional parts or replace a few parts, it is useful as a self-closing device.

DESCRIPTION OF SYMBOLS 1 Mainspring mechanism 10 Mainspring pulley 11 Mainspring 11A Tip 11A Tip 11B Weakest part 11C Circumferential part 12 Shaft 12A Groove 13 Holding plate 2 Wire 3 Sliding door closer 30A End surface 31 Mainspring device 31A Mainspring pulley 32 Damper wire 32A Damper wire pulley Side sliding door 5 Movable side sliding door 5B Ceiling surfaces 51, 52, 71, 72 First and second pulleys 53 Suspension wheel 54 Fixing member 6 Sliding door frame 6A Door contact 7 Wall 8 Tensile force adjusting means 81 Rotating plate 81A Small hole 82 Adjusting member 821 Operation shaft 822 Pinion (small gear)
823 Stopper pins 83, 84 First and second adjustment plates with gears 83A, 84 A External teeth 84B Small holes 9A Elastic body (closing speed regulating means)
9B rack (closing speed regulating means)
9C pinion (closing speed regulating means)

Claims (1)

A mainspring and a damper mechanism that imparts a damper force to the sliding door via a wire, and a sliding door closer that self-closes the sliding door with the spring force of the mainspring,
In order to offset or change the direction of pulling the wire to a surface perpendicular to the mounting surface of the mainspring pulley that houses the mainspring and the damper pulley that houses the damper mechanism, in the vicinity of the wire drawer portion of the sliding door body. A sliding door closer having one or more pulleys attached thereto.

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