JP2018119390A - Assisting device for sliding door - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an assisting device for a sliding door capable of improving the spring characteristic of the force accumulating spring, simplifying the structure of the spring to improve the durability of the force accumulating spring, and reducing the manufacturing cost.SOLUTION: A casing 20, an end block 21, and a changeover tool 23 are provided. In the casing 20, a damper 25, a slider 26, a trigger body 29, and a force accumulating spring 31 are arranged. The trigger body 29 is switched to between a standby position and an operating position by the switching tool 23. The trigger body 29 in the standby position is engaged with the catch opening 47 of the casing 20 to hold the force accumulating spring 31 with an accumulated force. Since the trigger body 29 in the operating position is disengaged from the catch opening 47, a door panel 1 can be moved by an elastic force of the force accumulating spring 31. The force accumulating spring 31 is formed of a compression coil spring disposed between the slider 26 and the end block 21, and is held by a spring retainer 32 which is arranged, effectively for the extension and retraction stroke of the force accumulating spring 31, not to allow the force accumulating spring to be curved during deformation.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a sliding door assist device that slowly moves a door panel of a sliding door toward the stroke end in the vicinity of the opening / closing stroke end.

  With regard to this type of assist device, the present applicant has proposed a sliding door assist device according to Patent Document 1 and has already commercialized it. There, an assist device is configured by a closing support unit and an opening support unit, a case for housing these units, a closing side switching tool and an opening side switching tool fixed to the guide rail corresponding to each supporting unit. ing. Each support unit includes a power storage spring, a closed structure and an open structure for closing or opening the door panel, a state in which the power storage spring can be stored by switching the closed structure or the open structure, and a stored power storage spring It is composed of a switching structure for switching to a state in which the elastic force of the motor can be output, a cylinder-type damper for braking, and the like. The accumulator spring consists of a tension spring and is hooked on a pair of switching structures. Further, the end of the damper on the cylinder side is connected to one switching structure, and the end of the piston rod is connected to the other switching structure.

  A similar assist device is also disclosed in the sliding door closing device of Patent Document 2. There, a rod-shaped casing, a buffer damper, an elastic body (spring), a pair of hook members guided and supported by the casing so as to be slidable to the left and right, a fixed protrusion that is fixed to the guide rail and switches the hook member, etc. Constitutes a door closing device. One hook member is connected to the tip of the piston rod of the shock absorber via an attachment member, and the other hook member is connected to the end of the cylinder via the attachment member. Each mounting member has a U-shaped cross section or a frame with a pair of front and rear inverted T-shaped frames. Both ends of the shock absorber and the elastic body are connected and fixed to each mounting member, and the hook member swings with each mounting member. I support it as possible. The elastic body is formed of a tension spring, and the engaging portions at both ends are hooked on the pair of hook members. A latching groove for dropping and engaging a locking projection provided on the hook member is formed at the side end of the casing.

Japanese Patent No. 5679309 (paragraph number 0028, FIG. 1) JP 2009-127293 A (paragraph number 0017, FIG. 1)

  According to the assist device of Patent Literature 1, the door panel can be slowly closed or opened in the vicinity of the closed end and the open end. In addition, since the basic parts of each support unit are shared, it is possible to prevent the overall cost of the assist device from increasing, and the length of the overall device can be reduced to apply to a small-sized door panel. Furthermore, the generation of operating noise when the switching structure operates is small and excellent in quietness. However, since the number of component parts of the switching structure shared for closing and opening is large, there is a limit to reducing the overall cost of the assist device.

  In that respect, since the door closing device of Patent Document 2 has a small number of components of the assist device, the cost required for manufacturing can be reduced. However, when the pin-like hooking projection fixed to the hook member falls into the hooking groove of the casing and engages, the elastic force of the stretched elastic body acts on the hook member, so an unpleasant tapping sound (click) ) Is unavoidable and lacks quietness. Moreover, in the door closing apparatus of patent document 2, the both ends of a casing are being fixed to a pair of runner which supports a door panel. Therefore, it is inevitable that the left and right dimensions of the door closing device are increased, and there is a limit to downsizing the door closing device. Furthermore, since the locking projection provided on the hook member slides and displaces along the upper edges of the front and rear walls of the casing, the locking projection may float off the casing, and the hook member can be reciprocated and slid in a stable state. Absent.

  Generally, in this type of assist device and door closing device, a tension spring is often used as a force accumulation spring (elastic body), and hook-shaped connecting portions are formed at both ends thereof. In such an accumulator spring, since the large elastic force of the spring is concentrated on the connecting portion, the connecting portion is easily broken early. In recent years, in order to improve the strength of the connecting part, the end of the spring is formed in a tightly wound trumpet shape, so that the elastic force of the spring is concentrated on the connecting part to avoid breaking. Although many springs are used, it is inevitable that these accumulating springs are expensive.

SUMMARY OF THE INVENTION An object of the present invention is to provide a sliding door assist device that can reduce the overall cost by simplifying the overall structure of the assist device or can be downsized and made compact.
The object of the present invention is to improve the spring structure of the accumulator spring and improve the spring characteristics as compared with the accumulator spring formed of a tension spring, and further simplify the structure of the spring to improve the durability of the accumulator spring. An object of the present invention is to provide a sliding door assist device capable of reducing costs while improving.

  The sliding door assist device of the present invention moves and operates the door panel 1 that opens and closes along the guide rail 2 toward the stroke end in the vicinity of the opening and closing stroke end. As shown in FIG. 19, the assist device includes a casing 20, an end block 21 fixed to at least one end of the casing 20, and a switching tool 23 fixed near the stroke end of the guide rail 2. Inside the casing 20 is at least one cylinder-type damper 25, a slider 26 joined to at least one end of the damper 25, and a trigger body pivotally supported by a swing shaft 28 provided on the slider 26 so as to be able to swing left and right. 29 and at least one energy storage spring 31 are arranged. The trigger body 29 is switched by the switching tool 23 in the vicinity of the stroke end of the door panel 1 and can swing back and forth between the standby posture and the operating posture. The trigger body 29 in the standby posture holds the force accumulation spring 31 in a state where the trigger claw 70 is engaged with the catch portion 47 provided on the casing 20 or the end block 21. The trigger body 29 in the operating posture is engaged and held by the switching tool 23 in a state where the trigger claw 70 is detached from the catch portion 47. In a state where the trigger body 29 is switched from the standby posture to the operating posture by the switching tool 23, the door panel 1 can be moved toward the stroke end by the elastic force of the accumulating spring 31 acting on the end block 21. The accumulator spring 31 is a compression coil spring that is disposed between the opposing surfaces of the slider 26 and the end block 21 and biases the slider 26 and the end block 21 away from each other. The spring shaper 32 provided facing the stroke is held so as not to bend and deform.

  As shown in FIG. 6, a pair of end blocks 21, 22, a pair of sliders 26, 27, a pair of trigger bodies 29, 30, a pair of energy storage springs 31, 31, The spring shape holders 32 and 32 are arranged. Switching tools 23 and 24 are fixed in the vicinity of the stroke ends of both ends of the guide rail 2.

  As shown in FIG. 3, the catch portion that captures and engages the trigger claw 70 is formed by catch openings 47 and 77 that are opened in the bottom wall of the casing 20 that faces the movement region of the trigger bodies 29 and 30.

  As shown in FIG. 15, a clearance E that allows the trigger claws 70 and 70 to enter and exit is secured between the accumulator spring 31 and the front and rear walls of the casing 20. The catch portion that captures and engages the trigger pawl 70 is formed by catch shafts 47 and 77 that are fixed to the casing 20 and the end blocks 21 and 22 and cross the gap E forward and backward.

  As shown in FIG. 18, a damper 25 </ b> A that brakes the door panel 1 that closes and moves toward the stroke end and a damper 25 </ b> B that brakes the door panel 1 that moves open toward the stroke end are disposed inside the casing 20. .

  As shown in FIGS. 4 and 5, the trigger bodies 29 and 30 are provided with a switching recess 67 that is tilted by the switching tools 23 and 24. A receiving surface 68 and a tilting surface 69 that are tilted by the switching tools 23 and 24 are provided on the left and right sides of the recess of the switching recess 67. The trigger bodies 29 and 30 are switched from the standby posture to the operating posture in a state where the tilting surface 69 is tilted by the switching tools 23 and 24, and the receiving surfaces 68 are engaged and held by the switching tools 23 and 24. A clearance hole 71 is formed adjacent to the receiving surface 68. An elastic wall 73 that is elastically deformable toward the inside of the escape hole 71 is formed on the upper surface of the trigger body 29 on the trigger claw 70 side.

  As shown in FIGS. 24 and 25, a switching recess 67 and a cam surface 116 are provided on the upper portions of the trigger bodies 29 and 30. As shown in FIG. 29, a receiving surface 68 and a tilting surface 69 provided on the left and right of the switching recess 67 and a pair of left and right switching pieces 118 and 119 for tilting the cam surface 116 are directed downward on the lower surface of the switching tool 23/24. Projected to Relief notches 120 and 121 are formed in one of the switching pieces 118 and 119 on the side in contact with the cam surface 116. An elastic relief wall 124 is provided on the bottom wall of the casing 20 corresponding to the relief notches 120 and 121. In a state where the cam surface 116 passes through the escape notches 120 and 121, the trigger pawl 70 of the trigger bodies 29 and 30 elastically deforms the elastic relief wall 124 as shown in FIG. 38, and the cam surface 116 and the receiving surface 68 are switched. 23 and 24 are depressed and engaged.

  The trigger bodies 29 and 30 are tilted and biased toward the standby posture by a biasing spring 115 (see FIGS. 24 and 25).

  A swing shaft 28 that pivotally supports the trigger bodies 29 and 30 so as to be swingable left and right is provided integrally with the sliders 26 and 27. Under the trigger bodies 29 and 30, a rocking hole 112 having a dominant arc hole shape that is press-fitted to the rocking shaft 28 is formed.

  As shown in FIGS. 22 and 23, the end blocks 21 and 22 include a spring receiving portion 41 that supports one end of the guide shaft 32, and a connecting portion 42 that is fastened to the casing 20 with a bolt 15. A pair of elastic engagement pieces 101 and leg pieces 102 are integrally provided on the lower surface of the spring receiving portion 41, and engagement grooves 104 are provided on the front and rear sides of the upper surface of the spring receiving portion 41. In the state where the end blocks 21 and 22 are fixed to the casing 20, the elastic engagement piece 101 engages with the engagement hole 105 provided in the bottom wall of the casing 20, and the leg piece 102 catches as shown in FIG. The engagement grooves 104 are engaged with the front and rear walls of the casing 20.

  The sliders 26 and 27 are guided and supported by a guide shaft 32 fixed to the spring receiving portions 41 of the end blocks 21 and 22 so as to be slidable left and right. A guide shaft 32 is disposed inside the energy storage spring 31 so that the guide shaft 32 also serves as a spring shaper that restricts the bending deformation of the energy storage spring 31.

  As shown in FIG. 7, the guide shafts 32 and 32 are arranged in a state of being offset from the front and rear center of the casing 20 to either the front or rear. Thereby, the clearance gap E is formed between the force accumulation springs 31 and 31 arrange | positioned around the guide shafts 32 and 32, and one casing wall. Plate-like trigger bodies 29 and 30 are arranged in the gap E.

  As shown in FIG. 16, the guide shafts 32 and 32 are arranged along the front and rear center of the casing 20, and a gap E is formed between the force accumulation springs 31 and 31 arranged around the casing 20 and the front and rear casing walls. To do. A pair of plate-like trigger bodies 29 and 30 are arranged in the gap E.

  Guide grooves 37 and 37 are formed on the front and rear casing walls of the casing 20 to guide the swing shafts 28 and 28 so as to be slidable left and right. Slide portions 59 guided by the guide shafts 32 and 32 are provided on the spring receiving portions 57 and 57 of the sliders 26 and 27, respectively. The sliders 26 and 27 are guided by the guide grooves 37 and 37 and the guide shafts 32 and 32 so as to be slidable left and right.

  The sliding door assist device of the present invention includes a casing 20, an end block 21, and a switching tool 23 that is fixed to the guide rail 2 side. Inside the casing 20, a cylinder-type damper 25, a slider 26, The trigger body 29 and the accumulator spring 31 are arranged. Further, the trigger body 29 is switched by the switching tool 23 in the vicinity of the stroke end of the door panel 1 so as to switch between the standby posture and the operating posture. In the state where the trigger body 29 is switched to the standby posture by the switching tool 23, the trigger claw 70 is engaged with the catch portion 47 so that the power storage spring 31 can be held in a stored state. Further, in a state where the trigger body 29 is switched to the operating posture by the switching tool 23, the trigger claw 70 is detached from the catch portion 47 and the door panel 1 is stroked by the elastic force of the accumulating spring 31 acting on the end block 21. Made it possible to move towards the edge. In such an assist device, the accumulating spring 31 is formed by a compression coil spring disposed between the opposing surfaces of the slider 26 and the end block 21, and the accumulating spring 31 is provided with a spring shaper 32 provided facing the expansion / contraction stroke of the accumulating spring 31. The force spring 31 can be held so as not to bend and deform.

  As described above, in the assist device of the present invention, the end blocks 21 and 22, the damper 25, the slider 26, the trigger body 29, the accumulating spring 31, and the like are incorporated in the casing 20 to constitute the main part of the assist device. I made it. According to such an assist device, the number of components of the assist device can be reduced and the cost can be reduced as compared with the assist device of Patent Document 1. In addition, the assist device can be made smaller and more compact as much as the overall structure can be simplified.

Further, since the accumulator spring 31 of the assist device is formed of a compression coil spring, the spring constant can be reduced as compared with the accumulator spring formed of a tension spring, and it is not necessary to provide a connecting structure such as a hook portion. The cost can be reduced while improving the durability of the force spring 31. Furthermore, since the effective length of the spring portion can be increased by the amount that the connecting structure such as the hook portion can be omitted, the extension stroke of the accumulating spring 31 when the elastic force is constant is reduced, and the assist device is made compact. Can contribute. Incidentally, the accumulating spring 31 formed of a compression coil spring tends to tend to bend and deform the coil portion near the center radially outward in a state of being compressed and deformed. However, since the spring shaper 32 is provided facing the expansion / contraction stroke of the energy storage spring 31 and the energy storage spring 31 is held by the spring shaper 32 so as not to be deformed by bending, it is ensured that the energy storage spring 31 is curvedly deformed. Thus, the door panel 1 can be moved and operated with a constant operating force by making the elastic force of the accumulator spring 31 proportional to the amount of compressive deflection.

  Inside the casing 20, a pair of end blocks 21, 22, a pair of sliders 26, 27, a pair of trigger bodies 29, 30, a pair of accumulating springs 31, 31, and a pair of spring retainers 32, 32. Arranged. Further, the switching tools 23 and 24 are fixed in the vicinity of the stroke ends at both ends of the guide rail 2. Thus, according to the assist device provided with the structure for closing assist and the structure for opening assist inside the casing 20, the vicinity of the stroke end on the closed end side of the door panel 1, and the open end of the door panel In the vicinity of the stroke end on the side, the door panel 1 can be moved and operated toward the stroke end.

  The catch part should just be provided in any one of the casing 20 and the end blocks 21 and 22 which accompany. However, if the catch part is formed by the catch openings 47 and 77 that are opened in the bottom wall of the casing 20, the structure of the catch part is significantly simplified as compared with the case where the catch part is provided in the end blocks 21 and 22. The manufacturing cost of the assist device can be reduced accordingly.

  If the catch portion is formed of catch shaft bodies 47 and 77 that cross the gap E back and forth, the catch function of the trigger pawl 70 can be recovered simply by replacing the catch shaft 47 when the catch shaft 47 is worn. Therefore, compared with the case where the end block 21 is replaced, the labor and cost of replacement can be reduced.

  According to the assist device in which the damper 25A that brakes the door panel 1 that moves to close and the damper 25B that brakes the door panel 1 that moves to open is disposed inside the casing 20, the braking strokes and braking of the individual dampers 25A and 25B are arranged. The characteristics can be different. Therefore, the assist device can be optimized by freely selecting the damper 25A for closing braking and the damper 25B for opening braking having characteristics according to the open / close state of the door panel 1.

  A switching recess 67 is provided in the trigger bodies 29 and 30, and a receiving surface 68 and a tilting surface 69 that are tilted by the switching tools 23 and 24 are provided on the left and right sides of the recess of the switching recess 67. Further, a relief hole 71 is formed adjacent to the receiving surface 68, and an elastic wall 73 that is elastically deformable toward the inside of the relief hole 71 is formed on the upper surface of the trigger body 29 on the trigger claw 70 side. Originally, in the state where the door panel 1 is opened to the open middle position, the trigger bodies 29 and 30 are switched to the operating positions as shown in FIG. 6, and the trigger claws 70 are engaged with the catch portions 47 and 77. doing. However, the trigger bodies 29 and 30 may be switched to the standby posture in rare cases when a mistake is made during construction or when the door panel 1 is opened and closed roughly. If the door panel 1 is closed in this state, the upper surfaces of the trigger bodies 29 and 30 may collide with the switching protrusions 93 of the switching tools 23 and 24 and be damaged. An elastic wall 73 is provided on the upper side of the escape hole 71 in order to eliminate the breakage of the trigger bodies 29 and 30 and to simplify the reset operation of the trigger bodies 29 and 30 to the standby posture.

  The trigger body 29/30 is provided with a switching recess 67 and a cam surface 116. A receiving surface 68 and a tilting surface 69 on the lower surface of the switching tool 23/24 and a pair of left and right switching pieces 118/119 for tilting the cam surface 116 are provided. Projected downward. Also, relief cutouts 120 and 121 are formed in one of the switching pieces 118 and 119 on the side in contact with the cam surface 116, and an elastic relief wall 124 is provided on the bottom wall of the casing 20 corresponding to the relief cutouts 120 and 121. did. According to such an assist structure, the elastic relief wall 124 is elastically deformed by the trigger claw 70 during the reset operation in which the cam surface 116 passes through the relief notch 120, so that the receiving surface 68 of the trigger bodies 29 and 30 and the cam surface 116 are switched. It was made to drop and engage with 23.24. Therefore, the structural strength of the trigger bodies 29 and 30 is increased and the durability is enhanced as compared with the case where the receiving surface 68 is dropped into the switching tools 23 and 24 while elastically deforming a part of the trigger bodies 29 and 30. Can be improved. Furthermore, it is possible to eliminate the breakage of the trigger bodies 29 and 30 during use and to improve the reliability of operation over a long period. Further, the trigger body 29 can be prevented from being tilted by the amount corresponding to the relief notch 120, and the elastic relief wall 124 can be prevented from being unnecessarily elastically deformed.

  The trigger bodies 29 and 30 are tilted and biased toward the standby posture by the biasing spring 115, so that the trigger pawl 70 can be reliably caught even when the door panel 1 is rapidly opened and closed. 77 can be engaged.

  Since the swing shaft 28 for pivotally supporting the trigger bodies 29 and 30 is provided integrally with the sliders 26 and 27, compared with the case where the trigger bodies 29 and 30 are supported by the pin-shaped swing shaft 28, The number of parts can be reduced. In addition, the trigger bodies 29 and 30 can be integrated with the sliders 26 and 27 simply by press-fitting and mounting the rocking holes 112 formed in the trigger bodies 29 and 30 on the rocking shaft 28. There is also an advantage that can save the trouble.

  A pair of elastic engagement pieces 101 and leg pieces 102 are integrally provided in the spring receiving portions 41 of the end blocks 21 and 22, and both the engagement holes 105 and the catch openings 47 are provided in the bottom wall of the casing 20. -Engage with 77. Further, the engagement grooves 104 provided on the front and rear surfaces of the spring receiving portion 41 are engaged with the front and rear walls of the casing 20, and the end blocks 21 and 22 are fastened and fixed to the casing 20 with the bolts 15 in this state. . According to such a connecting structure, the end block 21 can be fixed to the casing 20 more firmly than the end block 21 in which the connecting portions 42 of the end blocks 21 and 22 are merely fastened by the bolts 15. Can be reliably prevented from wobbling back and forth.

  The sliders 26 and 27 are slidably guided and supported by the guide shaft 32 fixed to the spring receiving portions 41 of the end blocks 21 and 22. In addition, a guide shaft 32 is arranged inside the energy storage spring 31 so that the guide shaft 32 also serves as a spring shaper that restricts the bending deformation of the energy storage spring 31. As described above, when the force accumulation spring 31 is supported from the inner surface by the guide shaft 32, the coil portion near the center tends to bend and deform radially outward from the center axis of the spring in a state where the force accumulation spring 31 is compressed and deformed. Can be surely prevented. Therefore, the door panel 1 can be closed or opened with a constant operating force by making the elastic force of the accumulator spring 31 proportional to the amount of compression deflection. In addition, the guide shaft 32 serves as a slide guide for the sliders 26 and 27 and a spring shaper that restricts the curved deformation of the accumulator spring 31, so that the spring shaper is provided separately. Thus, the structure of the assist device can be simplified. Further, even when the middle portion of the accumulator spring 31 is broken due to fatigue failure or the like, since the divided accumulator spring 31 is supported by the guide shaft 32 and the elastic force of the spring can be output, the spring output is somewhat weakened. However, it is excellent in reliability in that the assist function for opening and closing the door panel 1 is not completely impaired.

  The guide shafts 32 and 32 are arranged in a state of being offset from the front and rear center of the casing 20 to either the front or rear, and a plate-like shape is formed in the gap E formed between the accumulating springs 31 and 31 and one casing wall. Trigger bodies 29 and 30 are arranged. According to such an assist device, since the trigger bodies 29 and 30 can be arranged adjacent to either one of the front and rear of the accumulator spring 31, the increase in the front-rear width of the assist device is eliminated, Compared to a door closing device, a smaller and more compact assist device can be provided.

  A pair of plate-like trigger bodies are arranged in a gap E formed between the accumulating springs 31 and 31 disposed around the guide shafts 32 and 32 along the front and rear centers of the casing 20 and the front and rear casing walls. 29.30 was arranged. As described above, when the pair of trigger bodies 29 are provided before and after the accumulating springs 31 and 31, the front and rear trigger bodies 29 are in a state where the impact acting on the receiving surface 68 is dispersed when the standby posture is switched to the operating posture. Since it can bear, the durability of the trigger body 29 can be improved and the reliability of the assist device can be improved.

  Guide grooves 37 and 37 are formed on the casing walls before and after the casing 20 to guide the swing shafts 28 and 28 so as to be slidable in the left and right directions. Guided freely. According to such an assist structure, the sliders 26 and 27 can be slid and guided along the casing 20 in a more stable state, so that the sliders 26 and 27 can be reliably prevented from meandering when sliding left and right. Smooth assist operation.

It is a vertical front view of the principal part which shows the assist apparatus which concerns on Example 1 of this invention. 1 is a front view of a sliding door showing an application example of an assist device according to Embodiment 1. FIG. 1 is an exploded perspective view of an assist device according to Embodiment 1. FIG. 1 is an exploded perspective view of a closing assist structure according to Embodiment 1. FIG. 1 is an exploded perspective view of an opening assist structure according to Embodiment 1. FIG. 1 is a longitudinal front view of an assist device according to Embodiment 1. FIG. It is the sectional view on the AA line in FIG. 1 is a cross-sectional plan view of a main part of an assist device according to Embodiment 1. FIG. It is operation | movement explanatory drawing when a door panel is open-operated from a closed position. It is operation | movement explanatory drawing when a door panel is closed to the closed position side. It is a vertical front view of the assist device in the middle of opening. It is operation | movement explanatory drawing when a door panel is open-operated to the full open position side. It is operation | movement explanatory drawing when a door panel is closed from an open position. It is a vertical front view of the principal part of the assist apparatus which concerns on Example 2. FIG. It is a disassembled perspective view of the principal part of the assist apparatus which concerns on Example 2. FIG. It is a vertical side view of the principal part of the assist apparatus which concerns on Example 3. FIG. FIG. 9 is a cross-sectional plan view of an assist device according to a third embodiment. It is a vertical front view of the principal part of the assist apparatus which concerns on Example 4. FIG. It is a vertical front view of the principal part of the assist apparatus which concerns on Example 5. FIG. It is a vertical side view of the principal part of the assist apparatus which concerns on Example 6. FIG. FIG. 10 is an exploded front view of an assist structure according to a seventh embodiment. FIG. 9 is a perspective view of a closed end side end block according to a seventh embodiment. FIG. 10 is a perspective view of an end block on the open end side according to a seventh embodiment. It is a disassembled perspective view of the trigger body and slider on the closed end side according to Embodiment 7. It is a disassembled perspective view of the trigger body and slider of the open end side which concern on Example 7. FIG. It is the BB sectional view taken on the line in FIG. It is CC sectional view taken on the line in FIG. FIG. 10 is an exploded plan view in which a part of an assist structure according to a seventh embodiment is broken. It is a perspective view of the switching tool which concerns on Example 7. FIG. It is a vertical front view which shows the principal part of the assist apparatus which concerns on Example 7. FIG. It is a vertical front view which shows the open state of the assistance apparatus which concerns on Example 7. FIG. It is operation | movement explanatory drawing when a door panel is open-operated from a closed position. It is operation | movement explanatory drawing when a door panel is closed to the closed position side. It is operation | movement explanatory drawing when a door panel is open-operated to the full open position side. It is operation | movement explanatory drawing when a door panel is closed from an open position. It is a vertical front view of the assist device in a state where a pair of trigger bodies are separated from a switching tool. It is explanatory drawing which shows the procedure of reset operation. It is explanatory drawing which shows the next procedure of reset operation. It is explanatory drawing which shows the further next procedure of reset operation.

(Example 1) FIG. 1 thru | or FIG. 13 shows Example 1 of the assist apparatus of the sliding door which concerns on this invention. The sliding door shown in FIG. 2 shows the case where the doorway of the storage room provided facing the walk-in closet or the room is opened and closed by the door panel 1 having a single structure. In the present invention, front / rear, left / right, and upper / lower refer to the cross arrows shown in FIG. 2 and FIG.

  In FIG. 2, a guide rail 2 for opening and closing the door panel 1 is fixed to the upper part of the opening frame provided at the doorway, a pair of left and right runners 3 for suspending the door panel 1 therein, and an assist device. Is housed. The runner 3 is connected to a runner base 5 attached to the upper corner of the door panel 1 through a vertical runner shaft 4. In order to prevent wobbling of the door panel 1 in the front-rear direction, a slide groove 6 is provided on the lower surface of the door panel 1 and the guide 6 is guided by a guide roller 7 that is fixed to the floor surface. Reference numeral 8 denotes a handle.

  As shown in FIG. 7, the guide rail 2 is made of an aluminum strip having a C-shaped cross section that opens downward, and a rail wall 2 a that guides the runner 3 is provided at the front and back of the lower end thereof. The guide rail 2 in this embodiment uses an existing guide rail provided for a sliding door runner without an assist device as it is, and the vertical dimension of the rail inner surface is smaller than that of a general guide rail. As shown in FIG. 1, the runner 3 includes a runner block 11 that is long to the left and right, four rollers 12 that are arranged on the left and right of the front and rear surfaces of the block 11, a roller shaft 13, and the like. A connection seat 14 for connecting the assist device protrudes from one side upper portion of the runner block 11, and a plate nut 16 for screwing the bolt 15 into the inside of the wall is mounted. Further, four positioning pins 17 project downward from the lower surface of the coupling seat 14. The runner 3 suspends the closed end side and the open end side of the door panel 1, and an end block 21 of the assist device is connected to the connecting seat 14 of the runner 3 on the closed end side by a bolt 15.

  In FIG. 3, the assist device includes a casing 20 that opens upward, a pair of end blocks 21 and 22 that are fixed to both ends of the casing 20, and a pair of switching tools 23 and 24 that are fixed to the ceiling wall of the guide rail 2. 2). Inside the casing 20, a cylinder-type damper 25, a pair of sliders 26 and 27 joined to one end and the other end of the damper 25, and a swing shaft 28 provided on each slider 26 and 27 can be swung left and right. A pair of trigger bodies 29 and 30 pivotally supported by each other, a pair of force accumulation springs 31, a guide shaft (spring shaper) 32 for slidingly guiding the sliders 26 and 27, and the like are arranged. The accumulator spring 31 is formed of a compression coil spring and is disposed between the opposing surfaces of the sliders 26 and 27 and the end blocks 21 and 22 to urge the end blocks 21 and 22 and the sliders 26 and 27 away from each other. To do. The guide shaft 32 is formed of a round shaft made of stainless steel, and also serves as a spring shaper that restricts the coil portion near the center of the compressed energy storage spring 31 from being bent and deformed. For this purpose, the guide shaft 32 is arranged inside the accumulator spring 31 by setting the diameter of the guide shaft 32 to be slightly smaller than the inner diameter of the accumulator spring 31.

  The casing 20 is formed by bending a stainless steel plate into a U-shaped cross section, and mounting portions 35 for the end blocks 21 and 22 are cut out at both ends thereof. In addition, a regulating wall 36 that regulates the upward movement of the sliders 26 and 27 is folded on each of the upper end of the front wall of the casing 20 on the left half side and the upper end of the rear wall of the casing 20 on the right half side as viewed in FIG. It is bent. Further, a guide groove 37 is formed on each of the rear wall of the left half casing 20 and the front wall of the right half casing 20 as shown in FIG. . The guide groove 37 is a laterally long straight groove formed by projecting a casing wall outward, and is formed by burring. Reference numeral 39 denotes a reinforcing wall, which is formed by bending the front and rear walls facing the restriction wall 36 (see FIG. 7). By providing the reinforcing wall 39, the structural strength of the casing 20 can be improved. The trigger bodies 29 and 30 are captured and engaged with the bottom wall of the casing 20 facing the moving area of the trigger body 29 on the closed end side and the bottom wall of the casing 20 facing the moving area of the trigger body 30 on the open end side, respectively. Catch openings (catch portions) 47 and 77 are formed.

  In FIG. 4, the end block 21 on the closed end side is integrally formed with a spring receiving portion 41 protruding upward and a connecting portion 42 protruding laterally from the lower portion of the spring receiving portion 41. Consists of molded products. A shaft support hole 44 that supports the closed end of the guide shaft 32 is formed in the spring receiving portion 41, and a pin groove 45 that engages the previous positioning pin 17 is formed before and after the connecting portion 42. . In addition, an insertion hole 46 for the bolt 15 is formed in the connecting portion 42 so as to penetrate vertically. The front and rear widths of the spring receiving portion 41 and the connecting portion 42 are set slightly smaller than the facing distance between the front and rear walls of the casing 20. A recess 48 is formed on the rear surface of the spring receiving portion 41 to allow the end of the trigger body 29 on the closed end side to enter and exit.

  The cylinder-type damper 25 includes a cylinder body 51 connected to the slider 27 on the open end side and a piston rod 52 connected to the slider 26 on the closed end side, and the piston rod 52 retracts into the cylinder body 51. The door panel 1 is braked by absorbing the kinetic energy when entering. Therefore, oil is sealed inside the cylinder body 51. The damper 25 brakes the door panel 1 near the closed end and the open end, and slowly moves it to the closed end or the open end. In order to smoothly move the piston rod 52 to follow the slider 26, a compression coil-shaped rod spring 53 is disposed around the piston rod 52, and the piston rod 52 is urged to advance by the spring 53. The urging force of the rod spring 53 is set sufficiently smaller than the elastic force of the accumulating spring 31.

  The slider 26 on the closed end side has a rectangular bar-like main body portion 55 that is long on the left and right sides, a support arm 56 that projects from the rear surface of the main body portion 55 toward the open end side, and a cube shape that is provided at the projecting end of the support arm 56. This is made of a plastic molded product integrally provided with the spring receiving portion 57. A connecting hole 58 for the piston rod 52 is formed in the open end of the main body portion 55, and a slide hole (slide portion) 59 guided by the guide shaft 32 is provided in the spring receiving portion 57 so as to penetrate left and right. It is. When the main body 55 and the slide hole 59 are slid and guided by the casing 20 and the guide shaft 32, and the swing shaft 28 fixed to the main body 55 is slid and guided by the guide groove 37 of the casing 20, the left and right sliding operation of the slider 26 is smooth. Moreover, the operation can be performed in a stable state, and it is possible to reliably prevent the slider 26 from meandering when sliding left and right, and to smoothly perform the assist operation of the door panel 1.

  The trigger body 29 is disposed on the rear surface side of the main body 55, and the trigger body 29 is supported by the swing shaft 28 press-fitted to the main body 55 so as to be able to swing left and right. As shown in FIG. 7, a press-fitting groove 61 is formed in a circular shape on the swing shaft 28, and the press-fitting groove 61 is engaged with a protruding rib 63 provided in the pin hole 62 of the main body 55. The swinging shaft 28 is held out. The piston rod 52 is joined to the slider 26 by press-fitting a round shaft-like connecting piece 64 fixed to the protruding end of the piston rod 52 into the connecting hole 58 (see FIG. 1).

  The trigger body 29 on the closed end side is formed of a plate-like plastic molded product provided with a switching recess 67 that is tilted by the switching tool 23. The trigger body 29 has a catch opening 47 on the lower surface side of the closed end. A trigger claw 70 to be engaged and disengaged is provided. A receiving surface 68 that is received by the switching tool 23 and a tilting surface 69 that is tilted by the switching tool 23 are provided on the left and right sides of the recess of the switching recess 67, and a relief hole 71 is formed adjacent to the receiving surface 68. It is. By providing the escape hole 71, an elastic wall 73 that can be elastically deformed toward the inside of the escape hole 71 is formed on the upper surface of the trigger body 29. The function of the elastic wall 73 will be described later. A sliding portion 72 that is received by the bottom wall of the casing 20 in a state where the trigger claw 70 is detached from the catch opening 47 is formed on the lower surface of the trigger body 29 on the open end side.

  A partial arc-shaped restriction groove 99 is formed on the plate surface on the tilting surface 69 side of the trigger body 29, and the groove end of the restriction groove 99 is received by the pin 100 fixed to the slider 26. According to such a trigger body 29, when the trigger body 29 switches from the standby position to the operating position, the impact acting on the receiving surface 68 can be distributed to the pin 100, so that the receiving surface 68 is prevented from deteriorating early. Thus, the durability of the trigger body 29 can be improved.

  As described above, by supporting the trigger body 29 by the swing shaft 28 so as to be able to swing left and right, the trigger body 29 can swing back and forth between the standby posture and the operating posture. The trigger body 29 in the standby posture holds the force accumulation spring 31 in a state where the trigger claw 70 is engaged with the catch opening 47. The trigger body 29 can be switched from the standby posture to the operating posture by tilting the tilting surface 69 in this state with the switching tool 23. Further, the trigger body 29 can be switched from the operating position to the standby position by tilting the receiving surface 68 of the trigger body 29 in the operating position with the switching tool 23. In the state where the trigger body 29 is switched from the standby posture to the operating posture, the trigger pawl 70 is detached from the catch opening 47, so that the stored force of the stored force spring 31 can be released.

  In FIG. 5, the end block 22 on the open end side is basically configured in the same manner as the end block 21 on the closed end side, and is formed of a plastic molded product integrally provided with a spring receiving portion 41 and a connecting portion 42. . A shaft support hole 44 that supports the open end of the guide shaft 32 is formed in the spring receiving portion 41, and an insertion hole 46 for a bolt 75 (see FIG. 6) is formed in a vertically penetrating manner in the connecting portion 42. The point is also the same as the end block 21 on the closed end side. The end block 22 on the open end side is different from the end block 21 on the closed end side in that a support frame 79 is formed continuously to the connecting portion 42, and the pair of front and rear rollers 80 and the vertical axis around the frame 79. It is the point which is supporting the roller 81 which rotates in the direction. The end block 22 is mounted on the mounting portion 35 on the open end side of the casing 20 and is fixed with pins 82 that penetrate the casing 20 in the front-rear direction. Furthermore, the bolt 75 inserted from the lower surface side of the casing 20 is screwed into a plate nut 83 provided in the connecting portion 42, thereby being integrated with the casing 20 (see FIG. 6).

  Since the slider 27 on the open end side is the same as the slider 26 on the close end side, and the slider 26 on the close end side is used in a state of being reversed left and right, the same members are denoted by the same reference numerals and description thereof is omitted. Similarly to the slider 26 on the closed end side, the slider 27 on the open end side slides and guides the main body portion 55 and the slide hole 59 with the casing 20 and the guide shaft 32, and further, the swing shaft 28 fixed to the main body portion 55 has the casing. Slide guides are provided by 20 guide grooves 37. Therefore, the left / right sliding operation of the slider 27 can be performed smoothly and stably, and the slider 26 can be reliably prevented from meandering during the left / right sliding, and the door panel 1 can be smoothly assisted. A connecting hole 58 for the cylinder body 51 is formed in the closed end of the body portion 55 of the slider 27 on the open end side. The trigger body 30 is disposed on the front surface side of the main body portion 55, and the trigger body 30 is supported by the swing shaft 28 press-fitted to the main body portion 55 so as to be able to swing left and right. The press-fitting structure of the swing shaft 28 is the same as that of the slider 26 on the closed end side. The cylinder body 51 is joined to the slider 27 by press-fitting a round shaft-like connecting piece 84 fixed to the protruding end thereof into the connecting hole 58 (see FIG. 6).

  A bracket 87 is fixed to the front and rear casing walls with pins 88 at the left and right centers of the casing 20, and the shaft support holes 89 provided on the left and right of the bracket 87 and the shaft support holes 44 of the left and right end blocks 21 and 22. 44 supports the left and right guide shafts 32 individually. In order to arrange the trigger bodies 29 and 30 between the accumulator spring 31 and the front and rear casing walls, the guide shaft 32 is arranged so as to be offset from the front and rear center of the casing 20 to either the front or rear. Specifically, as shown in FIGS. 7 and 8, the guide shaft 32 on the closed end side is disposed in a state in which the central axis is offset from the front and rear center of the casing 20 to the front side, and the accumulating spring 31 and the casing rear A gap E for arranging the trigger body 29 is provided between the wall and the wall. Further, the guide shaft 32 on the open end side is disposed with its central axis being offset from the front and rear center of the casing 20 to the rear side, and the trigger body 30 is disposed between the accumulator spring 31 and the casing front wall. A gap E is provided.

  As described above, in the first embodiment, the guide shaft 32 is offset from one of the front and rear sides of the casing 20 to form the gap E between the accumulator spring 31 and one casing wall. The trigger bodies 29 and 30 are arranged by using. According to such an assist device, since the trigger bodies 29 and 30 can be arranged adjacent to either one of the front and rear of the accumulator spring 31, the increase in the front-rear width of the assist device is eliminated, Compared to a door closing device, a smaller and more compact assist device can be provided.

  The trigger body 30 on the open end side is the same as the trigger body 29 on the closed end side, and the trigger body 29 on the closed end side is used in a state where it is reversed left and right. Omitted. Like the trigger body 29 on the open end side, the trigger body 30 on the open end side can swing back and forth between the standby posture and the operating posture. The trigger body 30 in the standby posture holds the accumulating spring 31 in a state where the trigger claw 70 is engaged with the catch opening 77 and the accumulating spring 31 is accumulated. The trigger body 30 can be switched from the standby posture to the operating posture by tilting the tilting surface 69 in this state with the switching tool 24. Further, the trigger body 30 can be switched from the operating position to the standby position by tilting the receiving surface 68 of the trigger body 30 in the operating position with the switching tool 24. In the state where the trigger body 30 is switched from the standby posture to the operating posture, the trigger pawl 70 is detached from the catch opening 77, so that the accumulated force of the accumulation spring 31 can be released.

  The switching tool 23 on the closed end side and the switching tool 24 on the open end side are made of the same parts, and are integrally provided with a pair of left and right fastening seats 92 and a switching protrusion 93 at the center of the lower surface (see FIG. 9). The switching tool 23 on the closed end side is disposed near the closed end of the guide rail 2 and is fastened and fixed to the rail ceiling wall with two screws 94 inserted through the fastening seats 92. Similarly, the switching tool 24 on the open end side is disposed near the open end of the guide rail 2 and is fastened and fixed to the rail ceiling wall with two screws 94 inserted through the fastening seat 92 (see FIG. 12). .

  The assist device configured as described above houses the damper 25 in the casing 20, fixes the bracket 87, and temporarily fixes the cylinder body 51. Next, the trigger bodies 29 and 30 are assembled to the sliders 26 and 27, and the accumulating spring 31 is mounted around the guide shaft 32 while inserting the guide shaft 32 into the slide holes 59 of the sliders 26 and 27. Is inserted into the shaft support holes 44 of the left and right end blocks 21 and 22, and the end blocks 21 and 22, the guide shaft 32, and the accumulating spring 31 are temporarily assembled. The temporary assembly in this state is inserted into the casing from both ends of the casing 20, the trigger bodies 29 and 30 are assembled to the sliders 26 and 27, the guide shafts 32 are engaged with the shaft support holes 89 of the bracket 87, and the casing By fixing the end blocks 21 and 22 to both ends of the 20, the assist device is unitized.

  Next, after fixing the switching tools 23 and 24 to a predetermined position of the guide rail 2, the assist device and the runner 3 as unit parts are accommodated in the guide rail 2, and the runner 3 on the closed end side and the runner 3 on the closed end side are accommodated. The end block 21 is fastened with the bolt 15 and integrated. The door panel 1 can be suspended and supported by the guide rail 2 by engaging and mounting the runner bases 5 of the left and right runners 3 in this state to the door panel 1.

  Hereinafter, the operation of the assist device will be described. As shown in FIG. 1, when the door panel 1 is in the closed position, the trigger body 29 on the closed end side is held in a state where the corresponding switching tool 23 enters the switching recess 67 and is separated from the end block 21. The operating posture is The trigger claw 70 and the sliding portion 72 of the trigger body 29 in this state are supported by the bottom wall of the casing 20, and the swing shaft 28 is located near the open end of the guide groove 37. Further, the accumulating spring 31 on the closed end side extends to press the door panel 1 against the opening frame, and the spring receiving portion 57 of the slider 26 is located in the vicinity of the bracket 87. Further, the piston rod 52 retreats into the cylinder body 51 and fully compresses the rod spring 53. As shown in FIG. 6, the trigger pawl 70 of the trigger body 30 on the open end side is engaged with the corresponding catch opening 47 to hold the accumulator spring 31 in the accumulated state.

(When the door panel is opened from the closed position)
When the door panel 1 is opened from the above state, the end block 21 moves along with the runner 3, but the receiving surface 68 of the switching recess 67 is received by the switching tool 23 as shown in FIG. Therefore, the slider 26 is stopped together with the trigger body 29. As the door panel 1 further opens and moves away from the opening frame, the end block 21 approaches the trigger body 29 as shown in FIG. Then, as shown in FIG. 9A, the guide groove 37 slides relative to the swing shaft 28, and the edge on the open end side of the catch opening 47 enters the lower surface side of the trigger claw 70. Further, as shown in FIG. 9B, when the closed end of the guide groove 37 approaches the swing shaft 28 and the edge on the open end side of the catch opening 47 passes through the trigger claw 70 of the trigger body 29, the trigger The lower end of the claw 70 starts to catch on the catch opening 47.

  Finally, as shown in FIG. 9 (c), the trigger body 29 swings counterclockwise and switches to the standby posture, and the trigger claw 70 engages with the catch opening 47, and the trigger claw 70 The lower surface is exposed below the catch opening 47. At this time, the trigger pawl 70 suddenly falls into and engages with the catch opening 47, but since the drop distance is small, no annoying tapping sound is generated. As described above, the accumulation spring 31 is compressed and deformed by the opening operation of the door panel 1 until the end block 21 moves along with the runner 3 and the trigger pawl 70 engages with the catch opening 47. Is accumulated. Since the switching tool 23 in this state is separated from the switching recess 67 as shown in FIG. 6, the door panel 1 can be easily opened thereafter.

(When the door panel is closed from the middle position to the closed position)
When the door panel 1 that has been opened halfway is closed, the tilting surface 69 of the switching recess 67 of the trigger body 29 on the closed end side is received by the switching tool 23 as shown in FIG. The body 29 swings in the clockwise direction around the swing shaft 28. Accordingly, as shown in FIG. 10B, the trigger claw 70 starts to be detached from the catch opening 47. At the same time as the trigger claw 70 rides on the bottom wall of the casing 20 and separates from the catch opening 47, as shown in FIG. 10 (c), the slider 26 that receives the elastic force of the accumulating spring 31 opens the open end side. And the receiving surface 68 of the switching recess 67 is received by the switching tool 23. At this time, the receiving surface 68 collides with the switching tool 23. However, since the relief hole 71 is formed adjacent to the receiving surface 68, the receiving surface 68 is elastically deformed toward the closed end side to absorb the impact shock. To do. Therefore, a hitting sound is not generated when the trigger body 29 is switched from the standby posture to the operating posture, and the quietness of the assist device can be improved as compared with the conventional device of this type.

  Since the slider 26 in the above state is held by the switching tool 23 together with the trigger body 29, the elastic force of the accumulator spring 31 acts on the end block 21. Therefore, the casing 20 and the door panel 1 move toward the closed end by the stroke S shown in FIG. At the same time, the cylinder body 51 is moved along with the casing 20, the piston rod 52 is retracted into the cylinder body 51, and a braking action is exerted during that time. As shown in FIG. 1, the door panel 1 is slowly moved to the closed position. Move.

(When the door panel is opened from the open position to the fully open position)
When the door panel 1 that has been opened halfway is opened to the fully opened position, as shown in FIG. 12 (a), the tilting surface 69 of the switching recess 67 is closer to the open end side as shown in FIG. 24, the trigger body 30 swings in the counterclockwise direction about the swing shaft 28. Along with this, the trigger claw 70 starts to be detached from the catch opening 77 as shown in FIG. At the same time as the trigger pawl 70 rides on the edge of the catch opening 77 on the closed end side, the trigger body 30 on the open end side switches to the operating posture as shown in FIG. The slider 27 receiving the elastic force is forcibly slid to the closed end side, and the receiving surface 68 of the switching recess 67 is received by the switching tool 24. At this time, the receiving surface 68 collides with the switching tool 24. However, since the relief hole 71 is formed adjacent to the receiving surface 68, the receiving surface 68 is elastically deformed toward the closed end side to absorb the impact shock. To do. Therefore, when the trigger body 30 is switched from the standby posture to the operating posture, no hitting sound is generated, and the quietness of the assist device can be improved as compared with the conventional device of this type.

  Since the slider 27 in the above state is held by the switching tool 24 together with the trigger body 30, the elastic force of the accumulator spring 31 acts on the end block 22. Therefore, the casing 20 and the door panel 1 move toward the open end. At the same time, the piston rod 52 retreats into the cylinder body 51, and exerts a braking action during that time to move the door panel 1 slowly to the open position. Note that the stroke at the time of the opening movement is the same as the stroke S at the time of the closing movement described above.

  When the door panel 1 is in the fully open position, the trigger body 30 on the open end side is held in a state where the switching tool 24 enters the switching recess 67, and the trigger claw 70 is detached from the catch opening 77. The trigger claw 70 and the sliding portion 72 are supported by the bottom wall of the casing 20, and the swing shaft 28 is located near the closed end of the guide groove 37. Further, the accumulator spring 31 is fully extended, and the spring receiving portion 57 of the slider 27 is located in the vicinity of the bracket 87. Further, the piston rod 52 retreats into the cylinder body 51 and fully compresses the rod spring 53. Note that the trigger body 29 on the closed end side engages with the catch opening 47 of the corresponding end block 21 to maintain the standby posture and hold the corresponding power storage spring 31 in the power storage state.

(When the door panel is closed from the fully open position)
When the door panel 1 is closed from the fully open position, the end block 22 moves along with the casing 20, but the receiving surface 68 of the switching recess 67 is received by the switching tool 24, so that the slider 27 is triggered. Stops with the body 30. When the end block 22 further closes and moves, the guide groove 37 slides relative to the swing shaft 28 as shown in FIG. 13A, and the edge of the catch opening 77 on the closed end side approaches the lower surface of the trigger claw 70. When the edge on the closed end side of the catch opening 77 passes through the lower surface of the trigger claw 70, the lower end of the trigger claw 70 starts to fall into the catch opening 77 as shown in FIG.

  Finally, as shown in FIG. 13C, the trigger body 30 swings in the clockwise direction to switch to the standby position, and the trigger claw 70 engages with the catch opening 77, and the lower surface of the trigger claw 70 Is exposed below the catch opening 77. At this time, the trigger pawl 70 suddenly falls and engages with the catch opening 77, but since the drop distance is small, an unpleasant tapping sound does not occur. As described above, the accumulating spring 31 is compressed and deformed by the closing operation of the door panel 1 until the end block 22 moves along with the runner 3 and the trigger pawl 70 engages with the catch opening 77. Is accumulated. Since the switching tool 24 in this state is separated from the switching recess 67, the door panel 1 can be easily closed thereafter.

  In the state in which the door panel 1 is opened to the middle of opening, the trigger body 29 on the closed side is engaged with the catch opening 47 as shown in FIG. . However, the trigger body 29 may be switched to the operating posture in rare cases when a misunderstanding at the time of construction or when the door panel 1 is opened and closed roughly. If the door panel 1 is closed in this state, the upper surface of the trigger body 29 may collide with the switching protrusion 93 of the switching tool 23 and be damaged. An elastic wall 73 is provided on the upper side of the escape hole 71 in order to eliminate the breakage of the trigger body 29 and to easily reset the trigger body 29. When resetting the trigger body 29 that has been switched to the operating posture in the state where the door panel 1 is opened to the middle position, the door panel 1 is closed from the middle position to the closed position. The elastic wall 73 of the trigger body 29 is brought into contact with the switching tool 23 on the closed end side. The elastic wall 73 in contact with the switching tool 23 passes through the lower surface of the switching tool 23 while being elastically deformed toward the escape hole 71, so that the switching tool 23 can be dropped into the switching recess 67 and returned to the standby position. it can. The opening-side trigger body 30 can be reset in the same manner.

  In the assist device having the above configuration, the end block 21 and 22, the damper 25, the sliders 26 and 27, the trigger bodies 29 and 30, the accumulator spring 31, and the like are incorporated in the casing 20 to constitute the main part of the assist device. . According to such an assist device, the number of components of the assist device can be reduced and the cost can be reduced as compared with the assist device of Patent Document 1. In addition, the assist device can be made smaller and more compact as much as the overall structure can be simplified. Furthermore, since the drop distance of the trigger claw 70 is small, it is possible to eliminate an annoying tapping sound when the trigger claw 70 engages with the catch openings 47 and 77. In addition, when the trigger bodies 29 and 30 are switched from the standby posture to the operating posture, the receiving surface 68 is elastically deformed to absorb the impact shock, so that the trigger bodies 29 and 30 are switched from the standby posture to the operating posture. The tapping sound at the time can be reduced, and the quietness of the assist device can be improved as a whole. Since it has an assist structure that closes the door panel 1 to the closed end and an assist structure that opens the door panel 1 to the open end, the door panel 1 moves slowly toward the stroke end at each of the closed end and the open end. Can be operated.

  Since the accumulator spring 31 is formed of a compression coil spring, the spring constant can be reduced as compared with the case where the accumulator spring is formed of a tension spring, and there is no stress concentration point such as a hook portion. The durability of can be improved. By the way, when the initial elastic force of the accumulator spring is 8N when the wire diameter, coil diameter, and expansion / contraction stroke are the same, and when the operating load is 20N when the tension spring is extended to a certain length The operating load when the compression coil spring is compressed and deformed to a certain length can be reduced to 12N. Further, unlike the tension spring, it is not necessary to form hook portions at both ends of the spring, so that it can be manufactured at a low cost by the simple structure. Furthermore, since the effective length of the spring portion can be increased by omitting the hook portions at both ends, the expansion / contraction stroke of the accumulator spring 31 when the elastic force is constant is reduced, contributing to the compactness of the assist device. it can.

  In the above embodiment, the guide shaft 32 provided facing the expansion / contraction stroke of the energy storage spring 31 also serves as a spring shape holder. Specifically, the guide shaft 32 is disposed inside the accumulator spring 31 so that the inner surface of the coil portion is supported by the guide shaft 32. As described above, when the force accumulation spring 31 is supported from the inner surface by the guide shaft 32, the coil portion near the center tends to bend and deform radially outward from the center axis of the spring in a state where the force accumulation spring 31 is compressed and deformed. Can be surely prevented. Therefore, the door panel 1 can be closed or opened with a constant operating force by making the elastic force of the accumulator spring 31 proportional to the amount of compression deflection. As described above, the guide shaft 32 serves both as a slide guide for the sliders 26 and 27 and a spring shaper for restricting the deformation of the accumulator spring 31. Therefore, a spring shaper is provided separately. Compared to the case, the structure of the assist device can be simplified. Even when the middle portion of the accumulator spring 31 is broken due to fatigue failure or the like, the divided accumulator spring 31 is supported by the guide shaft 32 and can output an elastic force. The assist function for opening and closing 1 is not completely impaired.

(Example 2) FIG. 14 and FIG. 15 show Example 2 in which catch portions 47 and 77 are provided on the end blocks 21 and 222 side. There, the catch shaft (catch part) 47 was fixed to the casing 20 and the spring receiving part 41 in a front-rear penetrating manner in a state where the recessed part 48 formed in the spring receiving part 41 crossed back and forth. For this purpose, an insertion hole 98 for inserting the catch shaft 47 is formed in the front and rear walls of the casing 20 and the spring receiving portion 41 so as to penetrate in the front-rear direction. Further, a trigger claw 70 is provided at the end of the trigger body 29 on the closed end side so that the claw 70 engages and disengages from the catch shaft 47. Further, the sliding portions 72 are formed on the left and right sides of the lower surface of the trigger body 29 so that the sliding portion 72 on the closed end side falls into the escape groove 38 formed on the bottom wall of the casing 20 in the standby posture. The catch shaft 47 is formed in a round shaft shape, and a slit 50 that allows elastic deformation of the catch shaft 47 is formed at the end of the shaft. The catch shaft 47 also serves as the pin 49 in the first embodiment. When the catch shaft 47 is worn, the capture function of the trigger claw 70 can be recovered simply by replacing the catch shaft 47. Therefore, compared with the case where the end block 21 is replaced, the labor and cost of replacement can be reduced.

  In the second embodiment, the restriction wall 36 is omitted, and the reinforcing wall 39 is formed on the front and rear casing walls. Since others are the same as the assist device of the first embodiment, the same reference numerals are given to the same members, and descriptions thereof are omitted. The same applies to the following embodiments. As described above, if the restriction wall 36 is omitted, temporary assemblies such as the damper 25, the end block 21, the guide shaft 32, and the accumulating spring 31 can be assembled into the casing from the upper surface side of the casing 20. The time and effort of assembling the assist device can be reduced. Since the end block 22 and the trigger body 30 on the open end side are configured in the same manner as the end block 21 and the trigger body 29 on the closed end side, description thereof will be omitted.

(Third Embodiment) FIGS. 16 and 17 show a third embodiment of the assist device in which two trigger bodies 29 and 30 are provided. There, the guide shafts 32 and 32 are arranged along the front and rear centers of the casing 20, and gaps E are formed between the accumulating springs 31 and 31 arranged around the casing shafts and the front and rear casing walls, respectively. A pair of plate-like trigger bodies 29 are arranged in the front and rear gaps E. In this way, when the pair of trigger bodies 29 are provided, the trigger body 29 can be borne by the front and rear trigger bodies 29 in a state where the impact acting on the receiving surface 68 is dispersed when the trigger body 29 switches from the standby position to the operating position. The durability of the body 29 can be increased and the reliability of the assist device can be improved. The two trigger bodies 30 on the open end side are provided in a pair of gaps E between the accumulator springs 31 and 31 and the front and rear casing walls, like the trigger body 29 on the closed end side. The pair of trigger bodies 29 according to the third embodiment can be configured such that the upper surfaces of both trigger bodies 29 are integrated with each other by a bridging wall so that the longitudinal section becomes a U-shape. Similarly, the two trigger bodies 30 on the open end side can also be formed in a U-shaped cross section by integrating the upper surfaces with a bridging wall. The trigger claws 70 of the trigger bodies 29 and 30 in this embodiment are engaged with and disengaged from catch openings 47 and 77 provided in the casing 20.

(Example 4) FIG. 18 shows Example 4 of the assist device provided with the damper 25A for closing braking and the damper 25B for releasing braking. Specifically, a damper 25A that brakes the door panel 1 that closes and moves toward the stroke end and a damper 25B that brakes the door panel 1 that moves open toward the stroke end are disposed inside the casing 20. Further, when the braking stroke of the former damper 25A is set to 50 mm, the braking stroke of the latter damper 25B is set to 10 mm so that the braking distance of the door panel 1 that moves to close toward the stroke end is increased. Further, the rod spring 53 is accommodated in the cylinder body 51. Thus, if the damper 25A for closing braking and the damper 25B for opening braking are provided, the braking strokes and braking characteristics of the individual dampers 25A and 25B can be made different. It is possible to select a damper 25A for closing braking and a damper 25B for releasing braking having characteristics.

(Fifth Embodiment) FIG. 19 shows a fifth embodiment of a single-function assist device. In this case, the opening assist structure provided on the open end side of the casing 20 in the first embodiment is omitted, and the door panel 1 is braked toward the stroke end by the assist device only when the door panel 1 is closed. Enabled to move while. The assist device according to the fifth embodiment includes a casing 20, an end block 21 fixed to the closed end of the casing 20, and a switching tool 23 fixed in the vicinity of the stroke end of the guide rail 2. Inside the casing 20 is a cylinder type damper 25, a slider 26 joined to one end of the damper 25, and a trigger body 29 that is pivotally supported by a swing shaft 28 provided on the slider 26 so as to be swingable left and right. A single accumulator spring 31 is arranged. The end of the cylinder body 51 of the damper 25 is joined to the slider 26, and the end of the piston rod 52 is joined to the end block 22 on the open end side.

  The trigger body 29 is switched by the switching tool 23 in the vicinity of the stroke end on the closing side of the door panel 1 and can swing back and forth between the standby posture and the operating posture. The trigger body 29 in the standby posture holds the force accumulation spring 31 in a state where the trigger claw 70 is engaged with the catch opening 47. Further, the trigger body 29 in the operating posture is engaged and held by the switching tool 23 in a state where the trigger claw 70 is detached from the catch opening 47. In a state where the trigger body 29 is switched from the standby posture to the operating posture by the switching tool 23, the door panel 1 can be moved toward the stroke end by the elastic force of the accumulating spring 31 acting on the end block 21. The accumulator spring 31 is formed of a compression coil spring disposed between the opposed surfaces of the slider 26 and the end block 21, and is held inseparable by a guide shaft (spring shaper) 32 fixed to the end block 21. It is.

  In addition to the assist device described in the fifth embodiment, the assist device is configured as an open braking type assist device that moves and operates the door panel 1 while braking toward the stroke end with the assist device only when the opening operation is performed. can do. In that case, the closing assist structure provided on the closed end side of the casing 20 in the first embodiment may be omitted, and the protruding end of the piston rod 52 may be joined to the closed end block 21.

  As described above, according to the assist device having a single function, the casing 20 can be shortened by an amount corresponding to the omission of the opening assist structure or the closing assist structure, thereby further reducing the size of the assist device. Further, the entire structure of the assist device can be simplified by the amount that the opening assist structure or the closing assist structure is omitted, and the manufacturing cost can be reduced.

Example 6 FIG. 20 shows Example 6 of the assist device. There, the spring shaper is composed of the following members facing the expansion / contraction stroke of the energy storage spring 31, and the coil portion near the center of the energy storage spring 31 tends to bend and deform radially outward from the center axis of the spring. I was able to prevent. Specifically, the front and rear walls of the casing 20, the upper wall 55 </ b> A of the main body 55 of the sliders 26 and 27, the support arm 56 and the trigger bodies 29 and 30, and the regulation wall 36 that is greatly extended compared to the first embodiment. Thus, the members around the accumulator spring 31 are formed so that these members constitute a spring shape retainer. In this embodiment, the outer diameter of the guide shaft 32 is sufficiently smaller than the inner diameter of the energy storage spring 31 and the gap between the guide shaft 32 and the energy storage spring 31 is large, so that the guide shaft 32 is prevented from being bent and deformed. There is almost no specialization in the function of guiding the sliders 26 and 27. If necessary, the spring shape retainer in this embodiment can be used in combination with the guide shaft 32 described in the first embodiment.

(Embodiment 7) Embodiment 7 of the improved assist device is shown in FIGS. In the seventh embodiment, the components of the assist device such as the first embodiment are reviewed to improve the operation reliability while simplifying the structure. In addition, the recovery operation in the case of misunderstanding at the time of construction or when the trigger panel 29 is switched to the operating posture due to the door panel 1 being opened and closed wildly can be performed more reliably. In the following description, structures and functions different from those of the assist device described in the first embodiment will be mainly described.

  In FIG. 21, the casing 20 is basically the same as the casing described in the first embodiment, but differs in the following points. In the first embodiment, the upper end of the front wall of the left half casing 20 and the restriction wall 36 provided on each of the upper ends of the rear walls of the right half casing 20 are omitted. A guide groove 37 is formed in each of the rear wall of the left half casing 20 and the front wall of the right half casing 20, and the groove 37 is notched so that the lower half side of the casing wall reaches the bottom wall. The upper edge side is turned upward to form a guide edge. The reinforcing wall 39 is formed continuously except for both side ends of the front and rear walls of the casing 20. As will be described later, the end blocks 21 and 22 are engaged and mounted on the upper edges of the front and rear walls where the reinforcing wall 39 is not formed.

  21 and 22, the end block 21 on the closed end side includes a pair of front and rear elastic engagement pieces 101 projecting on the lower surface of the spring receiving portion 41 and the catch opening 47 in addition to the spring receiving portion 41 and the connecting portion 42. The engaging leg piece 102 and the guide protrusion 103 are integrally provided. In addition, engaging grooves 104 that engage with the front and rear walls of the casing 20 are formed in the front and rear ends of the spring receiving portion 41. The bottom wall of the casing 20 facing the front and rear guide grooves 37 is formed with a slit 107 that promotes deflection deformation in the downward direction of the bottom wall (see FIG. 28), and is elastic between the slit 107 and the guide groove 37. A relief wall 124 is provided. The elastic relief wall 124 is positioned directly below the switching tool 23. In the state where the end block 21 is assembled to the casing 20, as shown in FIG. 27, the elastic engagement piece 101 engages with the engagement hole 105 provided in the bottom wall of the casing 20, and the leg piece 102 corresponds to the catch opening 47. Engaging with the side end, the engaging groove 104 engages with the upper edges of the front and rear walls of the casing 20. Therefore, the end block 21 can be more firmly fixed to the casing 20 and the end block 21 can be reliably prevented from wobbling back and forth as compared with the end block 21 of the first embodiment that is only fastened by the bolt 15. The recess 48 and the pin 49 in the first embodiment are omitted.

  In FIG. 23, the end block 22 on the open end side basically has a spring receiving portion 41 and a connecting portion 42, a pair of front and rear elastic engagement pieces 101, and a catch opening 47 in the same manner as the end block 21 on the closed end side. The engaging leg piece 102 and the guide protrusion 103 are integrally provided. In addition, engaging grooves 104 that engage with the front and rear walls of the casing 20 are formed in the front and rear ends of the spring receiving portion 41. A pair of front and rear slide pieces 106 are integrally provided in front of and behind the side edge of the support frame 79 on the open end side of the end block 22 instead of the roller 80. The roller 81 and the pin 82 in the first embodiment are omitted.

  The cylinder-type damper 25 includes a cylinder main body 51 and a piston rod 52, except that a compression coil-shaped rod spring 53 is accommodated in the cylinder main body 51 as in the fourth embodiment. The protruding end of the piston rod 52 is inserted and connected to a connecting hole 58 provided at the side end of the main body 55 of the slider 26. The connecting piece 64 in the first embodiment is omitted.

  In FIG. 24, the slider 26 on the closed end side is integrally provided with a square bar-shaped main body portion 55, a support arm 56 projecting toward the open end side, and a cube-shaped spring receiving portion 57. Reference numeral 56 a is a reinforcing wall of the support arm 56. The point that the connecting hole 58 is recessed in the main body part 55 and the point that the slide hole 59 is formed in the spring receiving part 57 are the same as the slider 26 of the first embodiment. In this embodiment, the swing shaft 28 and the slide shaft 109 are integrally formed on the rear surface of the main body portion 55, and both the shafts 28 and 109 are reciprocated along the guide groove 37. In addition, a restriction recess 110 for the trigger body 29 is formed at the base of the support arm 56 on the closed end side. The main body 55 is slid and guided by the casing 20 and the slide hole 59 is guided by the guide shaft 32, and the swing shaft 28 and the slide shaft 109 are slid and guided by the guide groove 37. Moreover, it can be performed in a stable state. Furthermore, it is possible to reliably prevent the slider 26 from meandering when sliding left and right, and to smoothly perform the assist operation of the door panel 1. Since the swing shaft 28 and the slide shaft 109 are formed integrally with the main body portion 55, the number of members can be reduced by that amount.

  The trigger body 29 on the closed end side includes a switching recess 67 that is tilted by the switching tool 23 and a trigger claw 70 that is engaged with and disengaged from the catch opening 47, and the receiving surface 68 is tilted to the left and right of the recess of the switching recess 67. A surface 69 is provided. A receiving wall 111 that reinforces the tilting surface 69 is formed on the front and rear of the upper edge of the trigger body 29 facing the tilting surface 69. On the lower surface of the trigger body 29, there are formed an arcuate hole-like rocking hole 112 that engages with the rocking shaft 28 and a spring seat 113, and the inner surface of the restriction recess 110 is formed on the peripheral surface on the open end side. A restricting protrusion 114 that reciprocally swings is contacted. In addition, a cam surface 116 that is inclined downward toward the closed end is formed on the upper surface of the trigger body 29 on the closed end side. By press-fitting and engaging the swing hole 112 with the swing shaft 28, the trigger body 29 is integrated with the slider 26, and a compression coil-type biasing spring is provided between the slide shaft 109 and the spring seat 113 in this state. By arranging 115, the trigger body 29 is oscillated and biased toward the standby posture. In the state where the trigger body 29 is switched to the standby posture, the upper end surface of the restricting protrusion 114 is opposed to the upper end of the restricting recess 110 of the slider 26. In order to improve the structural strength of the trigger body 29, the escape hole 71 in the first embodiment is omitted, and the sliding portion 72 is also omitted. As described above, the trigger body 29 is oscillated and biased by the biasing spring 115, so that the tilting operation when the trigger body 29 is tilted from the operating posture to the standby posture by the switching tool 23 is clear and reliable. It can be.

  As described above, by supporting the trigger body 29 by the swing shaft 28 integral with the slider 26 so as to be able to swing left and right, the trigger body 29 can swing back and forth between the standby posture and the operating posture. The trigger body 29 in the standby posture holds the accumulator spring 31 in a state where the trigger pawl 70 is engaged with the catch opening 47 (see FIG. 32C). Moreover, since the trigger nail | claw 70 detaches | leaves from the catch opening 47, the trigger body 29 in the operating posture can release the accumulated force of the accumulation spring 31 (see FIG. 33 (c)).

  Since the slider 27 on the open end side is the same as the slider 26 on the close end side, and the slider 26 on the close end side is used in a state of being reversed left and right, the same members are denoted by the same reference numerals and description thereof is omitted. The slider 27 on the open end side, like the slider 26 on the closed end side, slide-guides the main body 55 and the slide hole 59 with the casing 20 and the guide shaft 32, and further, the swing shaft 28 provided on the main body 55 and the slide. The shaft 109 is slidably guided in the guide groove 37 of the casing 20. Accordingly, the left / right sliding operation of the slider 27 can be performed more smoothly and stably, and the slider 26 can be reliably prevented from meandering during the left / right sliding, and the door panel 1 can be smoothly assisted. The trigger body 30 is disposed on the front surface side of the main body portion 55, and the trigger body 30 is supported by the swing shaft 28 provided on the main body portion 55 so as to be able to swing left and right.

  A bracket 87 is fixed to the front and rear casing walls at the center of the left and right of the casing 20, and is supported by shaft support holes 89 provided on the left and right sides of the bracket 87 and shaft support holes 44 and 44 of the left and right end blocks 21 and 22. The left and right guide shafts 32 are individually supported. The pin 88 is formed integrally with the bracket 87 and is formed in a square shaft shape. The front and rear guide shafts 32 are arranged so as to be offset from the front and rear center of the casing 20 to either the front or rear.

  The trigger body 30 on the open end side is the same as the trigger body 29 on the closed end side, and the trigger body 29 on the closed end side is used in a state where it is reversed left and right. Omitted.

  FIG. 29 shows the switching tools 23 and 24 used in the seventh embodiment. The switching tools 23 and 24 are shared by the closed end side and the open end side, and a pair of left and right switching pieces 118 for the closed end side and a left and right side for the open end side are disposed on the front and rear surfaces of the pair of left and right fastening seats 92. A pair of switching pieces 119 protrudes downward. Further, in the switching piece 118 for the closed end side, a relief notch 120 is provided at the lower end of the switching piece 118 on the open end side, and in the switching piece 119 for the open end side, on the lower end of the switching piece 119 on the closed end side. A relief notch 121 is provided. The meaning of providing the relief notches 120 and 121 will be described later. The switching tools 23 and 24 are arranged near the closed end and the open end of the guide rail 2 and are fastened and fixed to the rail ceiling wall by two screws 94 inserted through the fastening seats 92 respectively. Only the switching piece 118 functions, and only the switching piece 119 functions near the open end. For example, only the switching piece 118 is provided on the lower surface of the fastening seat 92, and the switching tools 23 and 24 are fixed in a state of being reversed left and right near the closed end and the open end of the guide rail 2. Can do.

  The assist device configured as described above temporarily assembles the end block 21, 22, guide shaft 32, and accumulator spring 31 according to the same assembling procedure as in the first embodiment, and further to the casing 20. By fixing the temporary assembly, the trigger bodies 29 and 30, the sliders 26 and 27, the guide shaft 32, the bracket 87, and the end blocks 21 and 22, the assist device is unitized. Further, the switching tools 23 and 24 are fixed at predetermined positions on the guide rail 2, the assist device and the runner 3 are accommodated in the guide rail 2, and the runner 3 on the closed end side and the end block 21 are fastened by the bolt 15 to be integrated. Turn into. The door panel 1 can be suspended and supported by the guide rail 2 by engaging and mounting the runner bases 5 of the left and right runners 3 in this state to the door panel 1.

  Hereinafter, the operation of the assist device will be described. As shown in FIG. 30, when the door panel 1 is in the closed position, the trigger body 29 on the closed end side is held in a state where the switching piece 118 of the corresponding switching tool 23 enters the switching recess 67, The nail | claw 70 has become the action | operation posture which moves away from the end block 21. The trigger claw 70 of the trigger body 29 in this state is supported by the bottom wall of the casing 20, and the swing shaft 28 is located in the middle of the guide groove 37. Further, the accumulating spring 31 on the closed end side extends to press the door panel 1 against the opening frame, and the spring receiving portion 57 of the slider 26 is located in the vicinity of the bracket 87. Further, the piston rod 52 retreats into the cylinder body 51 and fully compresses the rod spring 53. In addition, as shown in FIG. 31, the trigger pawl 70 of the trigger body 30 on the open end side is engaged with the corresponding catch opening 77 to hold the force accumulation spring 31 in the force accumulation state.

(When the door panel is opened from the closed position)
When the door panel 1 is opened from the above state, the end block 21 accompanies the runner 3 and moves open. However, as shown in FIG. 30, the receiving surface 68 of the switching recess 67 is the switching piece 118 of the switching tool 23. Therefore, the slider 26 is stopped together with the trigger body 29. As the door panel 1 further moves open and moves away from the opening frame, the end block 21 approaches the trigger body 29 as shown in FIG. Then, as shown in FIG. 32A, the guide groove 37 slides relative to the swing shaft 28 and the edge of the catch opening 47 on the open end side enters the lower surface side of the trigger claw 70. Furthermore, as shown in FIG. 32B, when the closed end of the guide groove 37 approaches the swing shaft 28 and the edge of the catch opening 47 on the open end side passes through the trigger claw 70 of the trigger body 29, the trigger The lower end of the claw 70 starts to catch on the catch opening 47.

  Finally, as shown in FIG. 32 (c), the trigger body 29 swings counterclockwise and switches to the standby position, and the trigger claw 70 engages with the catch opening 47, and the trigger claw 70 The lower surface is exposed below the catch opening 47. At this time, the trigger pawl 70 receives the urging force of the urging spring 115, falls into the catch opening 47, and is held in the standby posture. Therefore, even when the door panel 1 is rapidly opened, the trigger pawl 70 can be reliably engaged with the catch opening 47. Since the upper end of the receiving surface 68 of the trigger claw 70 in this state is located below the lower end of the switching piece 118 of the switching tool 23, the door panel 1 can be easily opened thereafter.

(When the door panel is closed from the middle position to the closed position)
When the door panel 1 that has been opened halfway is closed, the tilting surface 69 of the switching recess 67 of the trigger body 29 on the closed end side is received by the switching tool 23 as shown in FIG. The body 29 swings in the clockwise direction around the swing shaft 28 while resisting the biasing force of the biasing spring 115. Along with this, the trigger claw 70 starts to be detached from the catch opening 47 as shown in FIG. As the trigger claw 70 rides on the bottom wall of the casing 20 and separates from the catch opening 47, as shown in FIG. 33 (c), the slider 26 that receives the elastic force of the accumulating spring 31 opens the open end side. And the receiving surface 68 of the switching recess 67 is received by the switching tool 23.

  Since the slider 26 in the above state is held by the switching tool 23 together with the trigger body 29, the elastic force of the accumulator spring 31 acts on the end block 21. Therefore, the casing 20 and the door panel 1 move toward the closed end by the stroke S shown in FIG. At the same time, the cylinder body 51 accompanies the casing 20, and the piston rod 52 is retracted into the cylinder body 51 and exerts a braking action during that time. As shown in FIG. 30, the door panel 1 is slowly moved to the closed position. Move.

(When the door panel is opened from the open position to the fully open position)
When the door panel 1 that has been operated to be opened halfway is opened to the fully opened position, as shown in FIG. 34 (a), after the trigger body 30 passes the lower surface of the switching tool 24 on the open end side, Since the tilting surface 69 of the switching recess 67 is received by the switching piece 119 of the switching tool 24 on the open end side, the trigger body 30 is counteracted against the biasing force of the biasing spring 115 around the swing shaft 28. Swings in the clockwise direction. Along with this, the trigger claw 70 starts to be detached from the catch opening 77 as shown in FIG. At the same time as the trigger claw 70 rides on the edge of the catch opening 77 on the closed end side, the trigger body 30 on the open end side switches to the operating posture as shown in FIG. The slider 27 receiving the elastic force is forcibly slid to the closed end side, and the receiving surface 68 of the switching recess 67 is received by the switching piece 119 of the switching tool 24.

  Since the slider 27 in the above state is held by the switching piece 119 of the switching tool 24 together with the trigger body 30, the elastic force of the accumulator spring 31 acts on the end block 22. Therefore, the casing 20 and the door panel 1 move toward the open end. At the same time, the piston rod 52 retreats into the cylinder body 51, and exerts a braking action during that time to move the door panel 1 slowly to the open position. Note that the stroke at the time of the opening movement is the same as the stroke S at the time of the closing movement described above.

  When the door panel 1 is in the fully open position, the trigger body 30 on the open end side is held in a state where the switching piece 119 of the switching tool 24 enters the switching recess 67, and the trigger claw 70 is detached from the catch opening 77. doing. The trigger claw 70 is supported by the bottom wall of the casing 20, and the swing shaft 28 is positioned near the closed end of the guide groove 37. Further, the accumulator spring 31 is fully extended, and the spring receiving portion 57 of the slider 27 is located in the vicinity of the bracket 87. Further, the piston rod 52 retreats into the cylinder body 51 and fully compresses the rod spring 53. Note that the trigger body 29 on the closed end side engages with the catch opening 47 of the corresponding end block 21 to maintain the standby posture and hold the corresponding power storage spring 31 in the power storage state.

(When the door panel is closed from the fully open position)
When the door panel 1 is closed from the fully open position, the end block 22 moves along with the casing 20, but the receiving surface 68 of the switching recess 67 is received by the switching piece 119 of the switching tool 24. The slider 27 is stopped together with the trigger body 30. When the end block 22 further closes and moves, the guide groove 37 slides relative to the swing shaft 28 as shown in FIG. 35A, and the edge of the catch opening 77 on the closed end side approaches the lower surface of the trigger claw 70. Then, when the edge on the closed end side of the catch opening 77 passes through the lower surface of the trigger claw 70, the lower end of the trigger claw 70 starts to fall into the catch opening 77 as shown in FIG.

  Finally, as shown in FIG. 35 (c), the trigger body 30 swings in the clockwise direction to switch to the standby position, and the trigger pawl 70 engages with the catch opening 77, and the lower surface of the trigger pawl 70. Is exposed below the catch opening 77. At this time, the trigger pawl 70 receives the urging force of the urging spring 115 and falls into the catch opening 77 and is held in the standby posture. Therefore, even when the door panel 1 is rapidly closed, the trigger pawl 70 can be reliably engaged with the catch opening 77. Since the upper end of the receiving surface 68 of the trigger claw 70 in this state is located below the lower end of the switching piece 119 of the switching tool 23, the door panel 1 can be easily closed and operated thereafter.

(Assist device reset operation)
In the state in which the door panel 1 is opened to the open middle position, the trigger body 29 on the closed end side and the trigger body 30 on the open end side have the respective trigger claws 70 in the catch openings 47 and 77 as shown in FIG. Is held in a standby posture. However, in the case of misunderstanding during construction or when the door panel 1 is opened and closed roughly, the left and right trigger bodies 29 and 30 may be switched to the operating posture as shown in FIG. Thus, in order to perform the reset operation of the trigger body 29 that has been switched to the operating posture easily and without damaging the trigger body 29, the slit 107 and the bottom wall of the casing 20 facing the guide groove 37 are provided. An elastic relief wall 124 divided by the guide groove 37 is provided.

  When performing the resetting operation, for example, as shown in FIG. 37 (b), the door panel 1 is closed from the midway position toward the closed position, and the cam surface 116 of the trigger body 29 is switched to the closed end side. The tool 23 is moved toward the switching piece 118 of the tool 23. This movement causes the catch opening 77 of the casing 20 to move closer to the trigger body 30 on the open end side and pass through the lower surface of the trigger claw 70, so that the trigger claw 70 of the trigger body 30 on the open end side of the biasing spring 115. Upon receiving the urging force, the trigger body 30 is dropped and engaged with the catch opening 77 to hold the trigger body 30 in the standby posture. At this time, the cam surface 116 of the trigger body 29 on the closed end side comes into contact with the relief notch 120 provided on the switching piece 118, so that the trigger body 29 receives a reaction force moment in the counterclockwise direction from the relief notch 120. . Further, as shown in FIG. 38A, the trigger claw 70 of the trigger body 29 that has received the reaction force moment causes the cam surface 116 to pass through the escape notch 120 while elastically deforming the elastic relief wall 124 downward. Then, it falls into the recess between the pair of switching pieces 118, and the receiving surface 68 of the switching recess 67 is received by the switching piece 118 on the escape notch 120 side (see FIG. 38B). The elastic relief wall 124 in this state is flush with the bottom wall of the casing 20, and the door panel 1 has moved to the closed end of the opening frame. That the trigger body 29 has been captured and engaged by the switching tool 23 can be confirmed by an engagement sound (click) when the receiving surface 68 falls into the recess between the pair of switching pieces 118 and engages.

  When the door panel 1 is opened in the above state as shown in FIG. 39 (a), the casing 20 and the end block 21 are opened while the slider 26 and the trigger body 29 are held in position by the switching tool 23. Move in the direction. By this movement, the catch opening 47 of the casing 20 moves closer to the trigger body 29 on the closed end side and passes through the lower surface of the trigger claw 70, so that the trigger body 29 on the closed end side is moved as shown in FIG. The trigger claw 70 receives the urging force of the urging spring 115 and falls into the catch opening 47 to be engaged, thereby holding the trigger body 29 in the standby posture. In the resetting operation, the door panel 1 is opened from the state shown in FIG. 37A toward the open position, and the trigger pawl 70 of the trigger body 29 on the closed end side is first dropped into the catch opening 47. May be combined. Thereafter, the trigger body 30 on the open end side is held in position by the switching tool 24 on the open end side, and then the door panel 1 is closed to drop the trigger claw 70 of the trigger body 30 on the open end side into the catch opening 77. By engaging, a series of reset operations can be completed.

  As described above, in the assist device according to the seventh embodiment, the elastic relief wall 124 corresponding to the switching tools 23 and 24 is provided on the bottom wall of the casing 20, and the elastic relief escape is performed during the reset operation in which the cam surface 116 passes through the relief notch 120. The wall 124 is elastically deformed by the trigger claw 70 so that the receiving surfaces 68 and the cam surfaces 116 of the trigger bodies 29 and 30 are dropped and engaged with the switching devices 23 and 24. According to such an assist structure, the structural strength of the trigger bodies 29 and 30 is increased and durability compared with the case where the trigger bodies 29 and 30 are partly elastically deformed and dropped into the switching tools 23 and 24. Can be improved. Therefore, it is possible to eliminate the breakage of the trigger bodies 29 and 30 during use, and to improve the long-term operation reliability. Further, the trigger body 29 can be prevented from being tilted by the amount corresponding to the relief notch 120, and the elastic relief wall 124 can be prevented from being unnecessarily elastically deformed.

  Further, in the assist device of the seventh embodiment, the trigger bodies 29 and 30 are tilted and biased toward the standby posture by the biasing spring 115, so that even when the door panel 1 is rapidly opened and closed, The trigger claw 70 can be reliably engaged with the catch openings 47 and 77. Further, since the swing shaft 28 is formed integrally with the sliders 26 and 27, the number of parts can be reduced as compared with the case where the trigger bodies 29 and 30 are supported by the pin-shaped swing shaft 28. In addition, the trigger bodies 29 and 30 can be integrated with the sliders 26 and 27 simply by press-fitting and mounting the rocking holes 112 formed in the trigger bodies 29 and 30 on the rocking shaft 28. There is also an advantage that can save the trouble.

  A pair of elastic engagement pieces 101 and leg pieces 102 are integrally provided in the spring receiving portions 41 of the end blocks 21 and 22, and both the engagement holes 105 and the catch openings 47 are provided in the bottom wall of the casing 20. -Engage with 77. Further, the engagement grooves 104 provided on the front and rear surfaces of the spring receiving portion 41 are engaged with the front and rear walls of the casing 20, and the end blocks 21 and 22 are fastened and fixed to the casing 20 with the bolts 15 in this state. . According to such a connecting structure, the end block 21 can be fixed to the casing 20 more firmly than the end block 21 in which the connecting portions 42 of the end blocks 21 and 22 are merely fastened by the bolts 15. Can be reliably prevented from wobbling back and forth.

  In the first embodiment, the guide shaft 32 is fixedly supported by the end blocks 21 and 22 and the bracket 87. However, the guide shaft 32 may be cantilevered by the end blocks 21 and 22 or the bracket 87. . Further, a lid-shaped spring shape retainer 32 that closes the upper opening of the casing 20 may be provided to prevent the compression spring 31 that has been compressed and deformed from falling off. In that case, it is preferable to use together with the spring receiving part 41 and the bracket 87 the pin which engages and hold | maintains the inner surface edge part of the force accumulation spring 31. FIG. The guide shaft 32 does not need to be a round shaft, and may be formed by a square axis or an elliptical axis. Similarly, the slide portion 59 does not need to be formed with a slide hole penetrating the spring receiving portion 57 to the left and right, but may be formed with a U-shaped groove or a square hole. Any structure that can slide is acceptable.

  The assist device according to the present invention can be applied to a sliding door having a two-sheet structure, in addition to being applied to a sliding door having a one-sheet structure. Further, the assist device according to the present invention can be applied to a door panel 1 supported by a door wheel and a sliding window having a sash structure in addition to the door panel 1 supported by a suspended wheel runner 3. The accumulator spring 31 can be composed of a plurality of springs. In this case, it is advantageous in that it can be dealt with by changing the number of springs used according to the difference in the weight of the door panel 1. Further, when the accumulator spring 31 is constituted by a plurality of springs, there is an advantage that the manufacturing cost of each spring can be reduced as compared with the case where the accumulator spring 31 is constituted by a single spring having a long overall length. . The spring constants and elastic forces of the plurality of springs are preferably the same. However, if necessary, the energy storage spring 31 may be composed of a plurality of springs having different characteristics.

DESCRIPTION OF SYMBOLS 1 Door panel 2 Guide rail 3 Runner 20 Casing 21 * 22 End block 23 * 24 Switching tool 25 Damper 26 * 27 Slider 28 Oscillating shaft 29 * 30 Trigger body 31 Accumulated spring 32 Guide shaft 41 Spring receiving part 47 * 77 Catch Opening / Catch shaft (Catch part)
51 Cylinder body 52 Piston rod 53 Rod spring 67 Switching recess 68 Receiving surface 69 Tilt surface 70 Trigger claw 71 Relief hole 101 Elastic engagement piece 102 Leg piece 104 Engagement groove 105 Engagement hole 112 Vibration hole 115 Energizing spring 116 Cam surface 118/119 switching piece 120/121 relief notch 124 elastic relief wall

Claims (14)

A sliding door assist device that moves the door panel (1) that opens and closes along the guide rail (2) toward the stroke end in the vicinity of the opening and closing stroke end.
The assist device includes a casing (20), an end block (21) fixed to at least one end of the casing (20), and a switching tool (23) fixed near the stroke end of the guide rail (2). And
The casing (20) includes at least one cylinder-type damper (25), a slider (26) joined to at least one end of the damper (25), and a swing shaft (28) provided on the slider (26). And a trigger body (29) that is pivotally supported so as to be swingable left and right, and at least one accumulator spring (31).
In the vicinity of the stroke end of the door panel (1), the trigger body (29) is reciprocally swung between a standby posture and an operating posture by being switched by a switching tool (23,
The trigger body (29) in the standby posture has its trigger pawl (70) engaged with a catch portion (47) provided on the casing (20) or the end block (21) to store the power storage spring (31). Held in a state,
The trigger body (29) in the operating posture is engaged and held by the switching tool (23) in a state in which the trigger claw (70) is detached from the catch portion (47).
When the trigger body (29) is switched from the standby position to the operating position by the switching tool (23), the door panel (1) is moved to the stroke end by the elastic force of the accumulating spring (31) acting on the end block (21). Move towards
The accumulator spring (31) is a compression coil spring that is disposed between the opposing surfaces of the slider (26) and the end block (21) and biases the slider (26) and the end block (21) away from each other. A sliding door assist device, which is formed and held by a spring shaper (32) provided facing the expansion / contraction stroke of the accumulator spring (31) so as not to bend and deform. Inside the casing (20), a pair of end blocks (21, 22), a pair of sliders (26, 27), a pair of trigger bodies (29, 30), and a pair of accumulating springs (31, 31) , A pair of spring retainers (32, 32) are arranged,
The sliding door assist device according to claim 1, wherein a switching tool (23, 24) is fixed in the vicinity of the stroke ends of both ends of the guide rail (2).   The catch portion for catching and engaging the trigger claw (70) is formed by a catch opening (47, 77) opened in the bottom wall of the casing (20) facing the movement region of the trigger body (29, 30). 3. The sliding door assist device according to 1 or 2. A clearance (E) that allows the trigger claws (70, 70) to enter and exit is secured between the end blocks (21, 22) and the front and rear walls of the casing (20).
A catch portion that captures and engages the trigger pawl (70) is formed by a catch shaft (47/77) that is fixed to the casing (20) and the end block (21/22) and crosses the gap (E) back and forth. The assisting device for a sliding door according to claim 1 or 2.   Inside the casing (20), a damper (25A) that brakes the door panel (1) that closes and moves toward the stroke end, and a damper (25B) that brakes the door panel (1) that moves open toward the stroke end. The sliding door assist device according to any one of claims 2 to 4, wherein: The trigger body (29, 30) is provided with a switching recess (67) that is tilted by a switching tool (23, 24).
A receiving surface (68) and a tilting surface (69) that are tilted by the switching tool (23, 24) are provided on the left and right of the recess of the switching recess (67).
The trigger body (29, 30) is switched from the standby position to the operating position while the tilting surface (69) is tilted by the switching tool (23, 24), and the receiving surface (68) is switched to the switching tool (23. 24) is engaged and held,
An escape hole (71) is formed adjacent to the receiving surface (68), and an elasticity that can be elastically deformed toward the inside of the escape hole (71) on the upper surface of the trigger body (29) on the trigger claw (70) side. The sliding door assist device according to any one of claims 2 to 5, wherein a wall (73) is formed. A switching recess (67) and a cam surface (116) are provided on the top of the trigger body (29, 30),
A pair of left and right switching pieces (118) for tilting the receiving surface (68) and the tilting surface (69) provided on the left and right of the switching recess (67) and the cam surface (116) on the lower surface of the switching tool (23, 24). 119) is projected downward,
A relief notch (120, 121) is formed in one of the switching pieces (118, 119) on the side in contact with the cam surface (116),
An elastic relief wall (124) is provided on the bottom wall of the casing (20) corresponding to the relief notch (120 121),
In a state where the cam surface (116) passes through the escape notch (120, 121), the trigger claw (70) of the trigger body (29, 30) elastically deforms the elastic relief wall (124), and the cam surface (116) and The sliding door assist device according to any one of claims 2 to 5, wherein the receiving surface (68) is lowered and engaged with the switching tool (23, 24).   The sliding door assist device according to claim 6 or 7, wherein the trigger body (29, 30) is biased and biased toward the standby posture by the biasing spring (115). A swing shaft (28) for pivotally supporting the trigger body (29, 30) so as to swing left and right is provided integrally with the slider (26, 27).
9. The swing hole (112) in the form of a dominant arc hole that is press-fitted to the swing shaft (28) is formed in the lower part of the trigger body (29, 30). Sliding door assist device. The end block (21, 22) is provided with a spring receiving portion (41) for supporting one end of the guide shaft (32) and a connecting portion (42) fastened to the casing (20) with a bolt (15). And
A pair of elastic engaging pieces (101) and leg pieces (102) are integrally provided on the lower surface of the spring receiving portion (41), and engaging grooves (104) are provided on the front and rear sides of the upper surface of the spring receiving portion (41). Provided,
In a state where the end blocks (21, 22) are fixed to the casing (20), the elastic engagement piece (101) engages with the engagement hole (105) provided in the bottom wall of the casing (20), and the leg piece ( The sliding door assist according to any one of claims 3 to 9, wherein 102) engages with the catch opening (47, 77), and the engaging groove (104) engages with the front and rear walls of the casing (20). apparatus. The sliders (26, 27) are guided and supported by a guide shaft (32) fixed to the spring receiving portion (41) of the end block (21, 22) so as to be slidable left and right.
The guide shaft (32) is arranged inside the accumulator spring (31), and the guide shaft (32) also serves as a spring shaper for regulating the bending deformation of the accumulator spring (31). The sliding door assist device according to any one of the above. An accumulator spring (31, 31) and one casing wall disposed around the guide shaft (32, 32) in a state where the guide shaft (32, 32) is offset from the front-rear center of the casing (20) to either the front or rear. A gap (E) is formed between
The sliding door assist device according to claim 11, wherein a plate-like trigger body (29, 30) is disposed in the gap (E). The guide shafts (32, 32) are arranged along the longitudinal center of the casing (20), and a gap (E) is formed between the accumulating springs (31, 31) arranged around the casing (20) and the front and rear casing walls. Formed,
The sliding door assist device according to claim 11, wherein a pair of plate-like trigger bodies (29, 30) are arranged in the gap (E). Guide grooves (37, 37) for guiding the swing shafts (28, 28) to be slidable to the left and right are formed in the casing walls before and after the casing (20),
The spring receiving portions (57, 57) of the slider (26, 27) are provided with slide portions (59) guided by the guide shafts (32, 32).
The sliding door assist device according to claim 5 or 6, wherein the slider (26, 27) is slidably guided by the guide groove (37, 37) and the guide shaft (32, 32).

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