JP2018159241A - Dual soft closer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a dual soft closer for quietly and slowly carrying out movement from a position just before a complete closing of a sliding door to a completely closed state, and movement from the position just before a complete opening to a completely opened state by biasing of a spring.SOLUTION: A dual soft closer comprises a head jamb side rail 2 and a soft closer body 3A supported by an upper end of a sliding door. The soft closer body 3A includes a body side rail 4, a front roller 53 and a rear roller 63, and a front advance/retreat unit 7 and a rear advance/retreat unit 8 inside the body side rail 4. A movement of completely closing the sliding door is carried out by unlocking a front cam 74 in which a front trigger 21 is caught and biasing the body side rail 4 by a spring in a forward direction. The movement of completely opening the sliding door is carried out by unlocking a rear cam 84 in which a rear trigger 22 is caught and biasing the body side rail 4 by the spring in a rear direction. A load in a counter-clockwise direction is added by a rotary damper 82 to quietly and slowly biases the spring.SELECTED DRAWING: Figure 3

Description

  The present invention is a dual software that allows the movement from the position before the sliding door is closed to the closing position and the movement from the position before the sliding door is completed to the opening position at a low speed by a spring bias and braking by a rotary damper. Regarding closers.

A slide assist device is disclosed in Permitted Literature 1 as a soft closer that automatically closes at a low speed from a position before the sliding door is closed.
This slide assist device has a structure in which the movement from the position immediately before the sliding door closes to the completion of the sliding door is performed by a spring bias.

JP 2013-151855 A

This slide assist device is described in the paragraph “0001” of the publication as “to apply a slide assist force in at least one of the opening and closing directions”. However, in the specification and drawings of the publication, the opening and closing direction is described. Both of them do not have a slide assist structure.
It is desired not only to slide the sliding door in the closing direction and to ensure that the sliding door is closed, but also to make sure that the sliding door is completely closed when the sliding door is opened.

This slide assist device has a structure that performs a slide assist by spring biasing, but does not have a structure that makes the sliding door closing speed low. A structure in which tension springs are provided in parallel is shown in FIG. 1, but simply providing the springs in parallel does not close the sliding door at a low speed.
In general, this type of slide assist device is provided with a linear oil damper at the position where the sliding door is closed, and the closing speed of the spring-biased sliding door is received by the piston portion of this linear damper to apply a load to reduce the sliding speed. Soft closers are also well known. However, in order to reduce the sliding door closing speed, it is necessary to use a linear oil damper with a large expansion / contraction amount of the piston portion, and oil leakage is likely to occur due to repeated use over a long period of time.
Further, in order to apply a load in both directions of opening and closing of the sliding door, it is necessary to provide two linear oil dampers, resulting in an increase in cost.

  The present invention is a dual software that allows the movement from the position before the sliding door to finish to the closing to the end and the movement from the position before the sliding door to the completion to the opening by the spring bias and the rotary damper at a quiet low speed. Providing a closer is the solution.

The dual soft closer according to claim 1 has the following configuration.
(1) It has the Kamoi side rail provided with the trigger in two places inside and behind, and the soft closer main body attached to the upper end part of a sliding door.
(2) The soft closer main body includes an outer main body side rail, a roller for causing the main body rail to travel in the Kamoi rail, and a front advancing / retreating unit and a rear advancing / retreating unit disposed in the main body side rail.
(3) The front advancing / retreating unit is provided with a front cam and a rack gear that protrudes rearward and is provided with a front frame member.
(4) A rotary damper having a pinion gear meshing with the rack gear and a rear cam are attached inside the rear advance / retreat unit.
(5) The front cam is spring-biased and the rear cam is spring-biased, respectively.
(6) The main body side rail and the front part advancing / retreating unit are restricted from moving back and forth by a lock by a front cam provided on the front part advancing / retreating unit.
(7) The main body side rail and the rear part advance / retreat unit are restricted from moving back and forth with respect to each other by being locked by a rear cam provided in the rear part advance / retreat unit.
(8) When the front cam is caught at the position immediately before the front cam finishes closing the sliding door by the advancement of the soft closer body in accordance with the operation in the closing direction of the sliding door, the front cam Is unlocked, and the main body side rail moves forward by pulling the sliding door by the spring bias.
(9) If the rear cam catches the rear trigger in the head rail at the position immediately before the rear cam has finished opening the sliding door due to the retraction of the soft closer body in accordance with the operation in the opening direction of the sliding door, the locking by the rear cam Is released, and the main body side rail moves rearward with the sliding door with the spring bias.
(10) The movement of the main body side rail by these spring biases is configured to be performed at a low speed by a braking torque by the rotary damper.

The dual soft closer according to the present invention prevents the sliding door from being completely closed or rebounded when the sliding door is opened and closed, and not fully opened or rebounded from being opened. Prevents the generation of impact sound when the door is opened and closed.
The dual soft closer according to the present invention performs the movement from the position before the sliding door is completely closed until the sliding door is completely closed and the movement from the position before the sliding door is completely opened until the sliding door is completely opened. A load by the rotary damper is applied to the movement of the sliding door, and the sliding door is moved at a quiet low speed.
The movement of the sliding door in the neutral region from the position before the sliding door is completely closed to the position before the sliding door is completed is not a spring bias but a manual operation.

  When the sliding door is located in this neutral region, the front cam and the rear cam are locked at positions farthest from each other, and the spring is in the most extended state. For this reason, the front cam and the rear cam are biased by a strong spring in a direction approaching each other.

  When the sliding door is manually operated in the opening / closing direction when the front cam and the rear cam are both locked, the main body side rail, the front advancing / retreating unit, and the rear advancing / retreating unit are integrated. Move back and forth.

  When the front cam catches the front trigger by the advancement of the soft closer body in accordance with the operation in the sliding door closing direction, the front cam faces the unlocking direction. When the lock is released, the main body side rail is moved by the spring bias to a position where the rear advancing / retracting unit is pulled to finish opening the sliding door. When the sliding door is completely closed, the front cam returns to the locked position again by the spring bias.

  When the rear cam catches the rear trigger by the retraction of the soft closer body accompanying the operation in the sliding door opening direction, the rear cam faces the unlocking direction. By releasing the lock, the main body side rail is moved by the spring bias to a position where the front advancing / retracting unit is pulled to finish opening the sliding door. When the sliding door is fully opened, the rear cam returns to the locked position again by the spring bias.

  Examples of the spring that performs the spring bias include a tension coil spring, a spring device including a metal tape plate that is spring-biased in the winding direction, and a spring device including a wire that is spring-biased in the winding direction. . It is also possible to provide a plurality of the springs in parallel to obtain a strong spring bias.

  The rotary damper may be a model that applies braking torque when the rotation shaft is rotated counterclockwise, or may be a model that applies braking torque in the fishing rotation direction. In the case of using the former rotary damper, the pinion gear is fixed to rotate at the tip of the rotating shaft. In the case of using the latter rotary damper, a well-known one-way between the rotation shaft and the pinion gear so as to idle in the clockwise direction with respect to the rotation shaft and to rotate with a load in the counterclockwise direction. Insert a clutch.

According to the dual soft closer according to the present invention, since the final process of opening and closing the sliding door is performed by spring bias, the sliding door can be completely closed or fully opened. In addition, since the braking force by the rotary damper acts on the spring bias, the sliding door is opened and closed at a quiet low speed. Since the rotary damper to be used is a rotary type, the amount of oil to be used is small, and the rotary shaft is not advanced or retracted, so that oil leakage is significantly less than that of the linear type. In addition, when a rotary oil damper is used, the amount of sliding door can be increased. One rotary damper is enough.
In the dual soft closer according to the present invention, the final process of opening and closing the sliding door is performed by a spring bias, and therefore, the movement of the sliding door other than the final process is not subjected to a load due to the spring. For this reason, the sliding door can be opened and closed easily.

  Preferred embodiments of the invention are described in detail in the following examples.

It is a use state figure of the dual soft closer concerning an embodiment of the present invention, (a) shows the state where a sliding door is in a position before full closure, and (b) shows the position in front before full closure of a sliding door. (A) is the perspective view which showed the state which attached the soft closer main body to the sliding door, (b) is a front view similarly. The disassembled perspective view of a dual soft closer. (A) is a perspective view including a partially broken portion of a front advancement / retraction unit, (b) is an enlarged perspective view of a front cam, and (c) is a front sectional view showing a part of the front advancement / retraction unit. (A) is a perspective view including a partially broken portion showing a rear advance / retreat unit, (b) is an enlarged perspective view of a rear cam, and (c) is a front sectional view of the rear advance / retreat unit. (A) is a side sectional view showing a hanging structure of a sliding door via a roller, (b) is a side sectional view of a front part of a dual soft closer showing a mounting structure of a front cam, and (c) is a rear cam. The side sectional view of the rear part of the dual soft closer showing the mounting structure, (d) is a side sectional view of the rear part of the dual soft closer showing the mounting structure of the rotary damper. In a state where the sliding door is in the neutral position, (a) is a front view of the upper part of the sliding door to which the dual soft closer is attached, (b) is an enlarged front sectional view of the front portion of the dual soft closer, and (c) is a front view of the dual soft closer. FIG. (A) is a front sectional view showing a hanging structure of a sliding door via a dual soft closer, (b) is an enlarged front sectional view of a front portion of the dual soft closer, (c) in a state immediately before the sliding door starts to automatically close. ) Is an enlarged front sectional view of the front part of the dual soft closer. In a state where the sliding door is closed, (a) is a front sectional view showing a hanging structure of the sliding door via the dual soft closer, (b) is an enlarged front sectional view of the front portion of the dual soft closer, and (c) is a dual sectional view. The expanded front sectional view of the soft closer front. (A) is a front sectional view showing a hanging structure of a sliding door via a dual soft closer, (b) is an enlarged front sectional view of a front portion of the dual soft closer, (c) in a state immediately before the sliding door starts to automatically open. ) Is an enlarged front sectional view of the front part of the dual soft closer. In a state where the sliding door has been opened, (a) is a front sectional view showing a hanging structure of the sliding door via the dual soft closer, (b) is an enlarged front sectional view of the front portion of the dual soft closer, and (c) is a dual sectional view. The expanded front sectional view of the soft closer front. (A)-(e) is the figure which showed the direction and position of the front cam corresponding to the position change of the opening / closing direction of a sliding door, and a rear cam. (A) is the front view which showed the use condition of the dual soft closer concerning 2nd Embodiment, (b) is the expansion front sectional drawing of the principal part. (A) is the enlarged front sectional view of the principal part which showed the state just before a sliding door started automatically closing about the dual soft closer concerning a 2nd embodiment, (b) is the principal which showed the state where the sliding door was also finished closing The expanded front sectional view of a part. (A) is the expanded front sectional view of the principal part which showed the state just before a sliding door began to open automatically about the dual soft closer concerning a 2nd embodiment, (b) is the principal which showed the state where the sliding door finished opening similarly The expanded front sectional view of a part.

[Overview]
As shown in FIG. 1A, the dual soft closer 1 according to the embodiment of the present invention manually operates the sliding door 100 in the closing direction, and when the sliding door 100 reaches the position before full closing, It closes automatically at a low speed by spring bias.
As shown in FIG. 1B, even when the sliding door 100 is manually operated in the direction to open the sliding door 100 and the sliding door 100 reaches the position before full opening, the sliding door 100 is fully opened at a low speed by a spring bias, and the door pocket 120 is opened. Store inside. For this reason, the sliding door 100 is completely closed and fully opened. When the sliding door 100 has been closed and opened, the sliding door 100 does not bounce or collide.

  The soft closer 1 according to the embodiment of the present invention is configured by the Kamoi side rail 2 and the soft closer body 3A. The Kamoi side rail 2 has a long rectangular frame shape with the center of the bottom surface opened in the length direction, and triggers (front trigger 21 and rear trigger 22 are provided at two front and rear positions. Kamoi side rail. 2 is attached to a groove provided on the inner lower surface of the Kamoi 110 by being screwed or screwed.

The soft closer body 3 </ b> A is attached along the upper end portion of the sliding door 100.
The sliding door 100 is suspended and supported from the Kamoi side rail 2 via the sliding door suspensions 5 and 6 provided at the front end portion and the rear end portion of the soft closer 1, and is in a state in which it can move forward and backward.

  The soft closer 1 according to the embodiment of the present invention can be attached to a sliding door, a sliding door, a window, or a closet door having a lower end attached thereto, in addition to the hanging type sliding door 100 shown in the drawing.

[Soft closer 3A]
As shown in FIGS. 2 and 3, the soft closer body 3 </ b> A includes a body-side rail 4, front and rear sliding door suspensions 5, 6, a front advancing / retreating unit 7, a rear advancing / retreating unit 8, and a spring 9. .

[Body side rail 4]
The main body side rail 4 is formed of a rectangular metal molded product having an upper end, a front end, and a rear end opened. On both side surfaces of the front portion of the main body side rail 4 in the length direction, straight long holes 41, 41 on the front portion side are provided in the front-rear direction. Rear straight long holes 42 and 42 are also provided in the front-rear direction on both side surfaces around the center of the main body side rail 4 in the length direction.
The front end portions of the straight long holes 41, 41 on the front side continue downward as engaging portions 41a, 41a having a short notch shape, and the rear end portions of the straight long holes 42, 42 on the rear side are also The engaging portions 42a and 42a have a short notch shape and continue downward. The straight long holes 41 and 41 on the front side and the straight long holes 42 and 42 on the rear side have a longitudinally symmetrical shape.

[Sliding door hanger 5, 6]
A sliding door suspension 5 is attached to the front end portion of the main body side rail 4, and a sliding door suspension 6 is also attached to the rear end portion of the main body side rail 4.
The sliding door suspensions 5 and 6 have a front-rear contrast shape that becomes the same shape when the front and rear directions are changed. The sliding door suspension 5 includes a front roller 53 composed of two left and right wheels, a mounting member 52 that mounts the front roller 53 on the front end of the main body side rail 4, and an embedded member positioned below the mounting member 52. 51. The embedded member 51 is mounted in the upper surface of the front end of the sliding door 100.
Similarly, the sliding door suspension 6 is configured by an assembly of a rear roller 63, a mounting member 62, and an embedded member 61. The embedded member 61 is mounted in the upper surface of the rear end of the sliding door 100.

[Forward Advance / Retreat Unit 7]
As shown in FIG. 3 and FIG. 4A, the front advancing / retracting unit 7 includes a front frame member 71 having a short front and rear length with the upper end, the front end, and the rear end open, a front cam 74, a rack gear, and the like. 73 and an assembly product.

As shown in FIGS. 4A, 4B, and 4C, the front cam 74 has a thickness that is slightly narrower than the lateral width of the front frame member 71, and has a laterally-oriented lever shape in a front view. .
On the upper surface of the rear portion of the front cam 74, a trigger receiving portion 74c made of a laterally oriented square groove is provided. Short support shafts 74a and 74a protrude from both side surfaces of the rear portion of the front cam 74, and swing shafts 74b and 74b longer than the support shafts 74a and 74a are formed on both side surfaces of the front portion of the front cam 74. Is protruding. A spring receiver 75 is protruded and supported from the rear to the rear of the front cam 74.

  4 (a) and 4 (c) with reference to FIG. 4 (b), the front cam 74 has a support shaft entry hole 71a in which support shafts 74a and 74a are provided on the side surface of the front frame member 71. 71a, and the swinging shafts 74b and 74b enter the swinging shaft support holes 71b and 71b, which are formed by oblique long vertical holes provided on the side surface of the front frame member 71. It is attached to the inside of the material 71 so as to be rotatable up and down. For this reason, the front cam 74 is in a state of being rotatable up and down around the support shafts 74a and 74a. This rotation is performed within a range in which the swing shaft 74b moves into the swing shaft support hole 71b.

  As shown in FIG. 3, the rack gear 73 is formed integrally with a rack bracket 72 facing forward. As shown in FIGS. 4A and 4B, the rack bracket 72 is mounted on the upper surface of the bottom plate 71 c of the front frame member 71, and the rack gear 73 protrudes long behind the front frame member 71.

[Rear Advance / Retreat Unit 8]
As shown in FIGS. 5A and 5C, the rear advancing / retreating unit 8 includes a rear frame member 81 made of a rectangular metal molded product having a short front and rear length with the upper end, the front end, and the rear end open, and a rear cam 84. And a brazed product with a rotary damper 82.
The rear frame member 81 has substantially the same width as the front frame member 71 shown in FIG.
As shown in FIGS. 5 (a), 5 (b), and 5 (c), the rear cam 84 has a front / rear symmetrical shape in which the front / rear direction is changed from the front cam 74 shown in FIG. 4 (b). 84a and 84a are support shafts of the rear cam 84, 84b and 84b are swinging shafts, and 84c is a trigger receiving portion.
As shown in FIGS. 5 (a) and 5 (c), the rear cam 84 has support shafts 84a and 84a that enter into the support shaft entry holes 81a and 81a provided on the side surfaces of the rear member 81, and the swing shaft 84b. , 84b enter into swinging shaft support holes 81b, 81b, which are formed by slanted vertical holes in the side surface of the rear frame member 81, and are attached to the inner side of the rear frame member 81 so as to be vertically rotatable. It has been.

  The rotary damper 82 is mounted on one side that is behind the rear cam 84 inside the rear frame 81. A pinion gear 83 is attached to the tip of the rotary shaft 82 a of the rotary damper 82. As the rotary damper 82, a one-way type model is used in which a load (rotational torque) is not applied in the clockwise direction of the rotary shaft 82a but a load (rotational torque) is applied in the counterclockwise direction.

[Assembly structure of the main body side rail 4, the front part advance / retreat unit 7, and the rear part advance / retreat unit 8]
As shown in FIG. 6A with reference to FIGS. 2B and 3, the lower end portions of both side surfaces of the Kamoi rail 2 are bent in directions facing each other. The front rollers 53 and 53 are movably placed on the bent surface. The same applies to the rear rollers 63 and 63.
As shown in FIGS. 6B, 7 </ b> A, and 7 </ b> B, the main body side rail 4 is located inside the Kamoi side rail 2. A front frame member 71 is located inside the front side of the main body side rail 4. The swing shafts 74b and 74b of the front cam 74 protrude into the straight long holes 41 (including the engaging portions 41a and 41a) of the main body side rail 4.
As shown in FIGS. 6C, 7 </ b> A and 7 </ b> C, the rear frame member 81 is located inside the main body side rail 4. The swing shafts 84b and 84b of the rear cam 84 protrude into the straight long holes 42 (including the engaging portions 42a and 42a) of the main body side rail 4.
As shown in FIGS. 6D, 7 </ b> A, and 7 </ b> C, the rack gear 73 enters the rear frame member 81 in a state of riding on the inner upper surface of the rear frame member 81 and meshes with the pinion gear 83. Yes.

  As shown in FIGS. 7A, 7B and 7C, there is a spring (a tension coil spring) 9 between a spring receiver 75 attached to the front cam 74 and a spring receiver 85 attached to the rear cam 84. Is hung.

  When the sliding door 100 shown in FIGS. 7A, 7B, and 7C is in a neutral position that is a region that is manually opened and closed, the swing shaft 74b of the front cam 74 is the lower end of the swing shaft support hole 71b. Therefore, the front cam 74 is in a locked state, located in the engaging portion 41a of the front end portion of the straight long hole 41. Similarly, the rear cam 84 is also locked, and the locked posture of the front cam 74 and the rear cam 84 is maintained by a strong tension in the pulling direction of the spring 9.

  When the front cam 74 and the rear cam 84 are both locked, when the sliding door 100 is opened and closed within the range of the neutral position, the software including the main body side rail 4, the front advancing / retracting unit 7 and the rear advancing / retreating unit 8 is provided. The entire closer body 3A moves in the opening / closing direction. The front trigger 21 is positioned in front of the front cam 74 when it is positioned in the neutral region where the sliding door 100 is manually opened and closed.

As shown in FIGS. 8A, 8B, and 8C, when the sliding door 100 is manually moved forward, the entire soft closer 3A moves forward. When the trigger receiving portion 74c of the front cam 74 catches the trigger 21 by this movement, the front portion of the front cam 84 swings upward, and the swing shaft 74b is detached from the engaging portion 41a of the linear long hole 41. As a result, the straight long hole 41 moves to the front end position, and the front cam 74 is unlocked.
In this state, as shown in FIGS. 9A, 9B and 9C, the rear advancing / retreating unit 8 and the main body are moved to a position where the front cam 74 reaches the rear end of the long hole 41 by the pulling force of the spring 9. The side rail 4 moves forward. This movement is performed at a low speed because braking torque by the rotary damper 82 is applied to the forward movement of the rack gear 73. 9A, 9B, and 9C are shown in a state where the sliding door 100 has been closed.

  When the sliding door 100 is closed, the front cam 74 returns to the locked direction by the pulling force of the spring 9 (the state is the same as the neutral position).

As shown in FIGS. 10A, 10B, and 10C, when the sliding door 100 is manually moved backward, the trigger receiving portion 84c of the rear cam 84 catches the trigger 22, and the rear portion of the rear cam 84 is moved upward. By swinging, the swing shaft 84b is detached from the engaging portion 42a of the straight long hole 42 and moves to the front end position of the straight long hole 42, and the rear cam 84 is unlocked.
In this state, as shown in FIGS. 11 (a), 11 (b) and 11 (c), the main body side rail 4 is moved forward and backward until the rear cam 84 reaches the front end of the long hole 42 by the pulling force of the spring 9. Moves forward with the unit 7. This movement is performed at a low speed because braking torque by the rotary damper 82 is applied to the rearward and forward movement of the rack gear 73.

  When the sliding door 100 finishes opening, the rear cam 84 returns to the locked direction by the pulling force of the spring 9 (the state is the same as the neutral position).

  When the sliding door 100 that has been opened is moved in the closing direction by manual operation, the front cam 84 moves in the direction away from the trigger 21 (rearward) and rotates in the direction locked by the pulling force of the spring 9 (neutral position). Will be the same state).

[Direction and position of front cam 74 and rear cam 84]
The locked state of the front cam 74 and the rear cam 84 will be summarized.
When the sliding door is in a position where it can be manually operated, both the front cam 74 and the rear cam 84 are in the locked direction as shown in FIG.
When the sliding door moves forward with a spring bias, as shown in FIG. 12B, the front cam 74 is in the unlocked direction, and the rear cam 84 remains in the locked direction.
When the sliding door is closed, as shown in FIG. 12C, the front cam 74 is positioned at the rear end of the straight long hole 41 on the front side moved forward in the unlocked direction. The rear cam 84 remains locked.
When the sliding door moves backward with spring bias, the front cam 74 remains in the locked orientation and the rear cam 84 is in the unlocked orientation, as shown in FIG.
When the sliding door has been opened, as shown in FIG. 12 (d), the front cam 74 remains in the locked orientation, and the rear cam 84 is in the unlocked orientation and moved rearward in the straight line length. It is located at the front end of the hole 42.

Although not shown, the front and rear straight elongated holes (41, 41 and 42, 4) are connected to the front and back (continuous), and the opening / closing amount by the spring bias of the sliding door is further increased. Also good.
A cushioning material may be provided to suppress cam noise that occurs when the front cam 74 is in the locked or unlocked orientation when the front cam 74 catches the trigger 21 on the front side. . The same may be applied to the rear cam 84.

[Soft Closer Body 3B of Second Embodiment]
The soft closer body 3B of the second embodiment shown in FIGS. 13A and 13B has the same basic structure and operation as the soft closer 3A described above. For this reason, below, the structure peculiar to the soft closer main body 3B which concerns on 2nd Embodiment is demonstrated.

  The guide rail portions 43, 43 replace the straight elongated holes 41, 41 on the front side shown in FIG. 3, and have ridges facing each other. Engaging portions 43a and 43a directed downward are provided at the front end portions of the guide rail portions 43 and 43, respectively.

Rollers 75 and 76 are supported at front and rear portions on both sides of the front frame member 71. The rollers 75 and 76 are supported in elongated holes 5 and 45 that are provided on the front side of both side walls of the main body side rail 4 and are directed in the front-rear direction. For this reason, the main body side rail 4 and the front part advancing / retreating unit 7 are in a state in which they can move back and forth with respect to each other within the range of the long holes 45, 45.
Rollers 85 and 86 are also supported at front and rear portions on both sides of the rear frame member 81. The rollers 85 and 86 are supported in long holes 46 and 46 that are provided on the rear side of both side walls of the main body side rail 4 and are directed in the front-rear direction. For this reason, the main body side rail 4 and the rear advancing / retreating unit 8 are in a state in which they can move back and forth within the range of the long holes 46, 46.

In the soft closer body 3B according to the second embodiment, a take-up spring device is used.
In this spring device, one end of the tape-shaped metal thin plate spring 9 is fed backward from the inside of the spring winding case 91, and this one end is folded back in the spring guide case 92. The other end of the spring 9 is connected and biased in the winding direction in the spring winding case 91.

  The spring winding case 91 is connected to the rear from the front cam 74, and the spring guide case 92 is connected to the front from the rear cam 84. Therefore, the front cam 74 is urged rearward and the rear cam 84 is urged forward.

  The front cam 74 is supported on both side walls of the front frame member 71 so as to be swingable up and down. In this support, the support shafts 74d and 74d of the front cam 74 and the swinging shafts 74b and 74b enter the guide rail portions 43 and 43 on the front side provided on the inner side surfaces of the both side walls of the main body side rail 4. Has been done.

  The guide rail portions 43 and 43 replace the straight elongated holes 41 and 41 on the front side shown in FIG. 3, and are formed by substantially elliptic frame-shaped ridges facing left and right. Engaging portions 43a and 43a directed downward are provided at the front end portions of the guide rail portions 43 and 43, respectively.

The rear cam 84 is supported on both side walls of the front frame member 71 so as to swing up and down. For this support, the support shafts 84d and 44d and the swinging shafts 84b and 44b of the rear cam 74 are inserted into the rear guide rail portions 44 and 44 provided on the inner side surfaces of the both side walls of the main body side rail 4. Has been done.
The guide rail portions 44, 44 replace the straight elongated holes 42, 42 on the rear side shown in FIG. 3, and are formed by substantially elliptic frame-shaped protrusions facing left and right. Engagement portions 44a and 44a directed downward are provided at the rear end portions of the guide rail portions 44 and 44, respectively.

  The soft closer body 3B shown in FIGS. 13A and 13B is shown in a state where the sliding door is in the neutral position. In this state, the front cam 74 is locked at the front end position of the guide rail portions 43, 43, and the rear cam 84 is locked at the rear end position of the guide rail portions 44, 44.

  When the sliding door is in a state of automatically starting to close by spring bias, the front cam 74 is in the unlocked direction as shown in FIG. When the front cam 74 catches the trigger 21 on the front side shown in FIG. 13A, the front cam 74 is in the unlocked direction, and is moved back and forth by the front advancing / retracting unit 7 and the main body side rail 4. Will be lifted. For this reason, the main body side rail 4 moves forward by spring biasing to the position shown in FIG. 14B (position where the sliding door is closed). At this time, the support shafts 74 d and 74 d of the front cam 74 are located at the rear ends of the guide rail portions 43 and 43.

  When the soft closer main body 3B is moved backward by manually operating in the direction to open the sliding door and the rear cam 84 catches the trigger 22 on the rear side, the front cam 74 is unlocked as shown in FIG. The forward / backward movement restriction by the rear advancing / retreating unit 7 and the main body side rail 4 is released, and the main body side rail 4 is moved backward by the spring bias to the position shown in FIG. 15 (b) (position where the sliding door has finished opening). Moving. At this time, the front cam 74 is positioned at the front ends of the guide rail portions 43 and 43, and the rear cam 84 is positioned at the front ends of the guide rail portions 44 and 44.

Also in the case of the soft closer body 3B according to the second embodiment, the front cam 745 and the rear cam 84 are oriented as shown in FIG.
Also in the case of the soft closer body 3B according to the second embodiment, the front and rear guide rail portions (43, 43 and 44, 44) are connected in the front and rear (continuous), and the front and rear elongated holes (45 , 45 and 46, 46) may be connected to the front and rear (continuous), and the opening / closing amount by the spring bias of the sliding door may be further increased.

  The dual soft closer according to the present invention is used in the fields of architecture and construction hardware.

DESCRIPTION OF SYMBOLS 1 Dual soft closer 2 Kamoi side rail 3A Soft closer main body 4 Main body side rail 41 Front side straight long hole 41a Engagement part 42 Rear side straight long hole 42a Engagement part 5 Sliding door hanging tool 53 Front roller 6 Sliding door hanging Tool 63 Rear roller 7 Front part advance / retreat unit 71 Front frame member 71a Support shaft hole 71b Oscillating shaft hole 73 Rack gear 74 Front cam 74c Trigger receiving part 75 Spring receiver 8 Rear part advance / retreat unit 81 Rear frame member 81a Support shaft entry hole 81b Dynamic shaft support hole 82 Rotary damper 83 Pinion gear 84 Rear cam 84c Trigger receiving part 85 Spring receiver 9 Spring

Claims (1)

It has a Kamoi side rail equipped with triggers at the two front and rear positions inside, and a soft closer body attached to the upper end of the sliding door,
The soft closer body includes an outer main body side rail, a roller that causes the main body rail to travel in the Kamoi rail, and a front advancing / retracting unit and a rear advancing / retreating unit disposed in the main body side rail,
The front advancing / retreating unit is provided with a front frame member including a front cam and a rack gear that protrudes rearwardly long,
Inside the rear advance / retreat unit, a rotary damper having a pinion gear meshing with the rack gear and a rear cam are attached,
The front cam is spring-biased, and the rear cam is forward-biased, respectively.
The main body side rail and the front part advance / retreat unit are restricted from moving back and forth by a lock by a front cam provided on the front part advance / retreat unit,
The main body side rail and the rear advancing / retreating unit are restricted from moving back and forth by locking by a rear cam provided on the rear advancing / retreating unit,
When the front cam catches the front trigger in the rail at the position immediately before the front cam finishes closing the sliding door by the advancement of the soft closer body in accordance with the operation in the closing direction of the sliding door, the lock by the front cam is locked. Released, the main body side rail moves forward with the spring biased with the sliding door,
When the rear cam catches the rear trigger in the moor side rail at a position immediately before the rear cam has finished opening the sliding door due to the retraction of the soft closer body in accordance with the operation in the opening direction of the sliding door, the lock by the rear cam is released. The main body side rail is moved rearward by pulling the sliding door by the spring bias,
The dual soft closer is configured such that the movement of the rail on the main body side by these spring biases is performed at a low speed by a braking torque by the rotary damper.

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