JP5214640B2 - Solar shading material lifting device - Google Patents

Description

The present invention, horizontal blinds, tucked up curtains, pleated curtains, the solar radiation shielding device such as a roller blind, relates lifting device and lower supporting hanging the solar radiation shielding material, to allow the lifting operation the蔽材barrier with a single operation code Is.

  In the roll blind clutch unit described in Patent Document 1, when the operation cord is continuously rotated to the screen lowering operation side, the engaging member is engaged with the pipe receiver and the pulley, and the winding pipe is continued. To lower the screen.

Further, if the operation cord is released after the lowering operation, the screen is prevented from being pulled up by the winding spring.
Further, by slightly pulling down the screen raising operation side of the operation cord, the pulley and the rotating cylinder are relatively rotated, and the connection between the rotating cylinder and the pipe receiver is released. Then, the screen can be lifted by the elastic force of the winding spring.

  In order to stop the lifting operation of the screen, the pulley and the rotating cylinder are relatively rotated by slightly lowering the screen lowering operation side, and the rotating cylinder and the pipe receiver are connected. Then, the take-up pipe cannot rotate and the screen lifting operation is stopped.

Patent No. 2860230

  In the roll blind as described above, the engaging member can be engaged with or disengaged from the step portion of the pipe receiver by pushing or pulling the engaging member in the radial direction from the hole of the rotating cylinder by the rotation of the pulley.

However, in such a configuration, when the engaging member is pushed out with the stepped portion of the pipe receiver positioned on the hole of the rotating cylinder, the engaging member comes into contact with the apex of the stepped portion, and the engagement becomes impossible. Become.
Therefore, the screen lowering operation or the lifting operation stop operation may be disabled, and there is a problem that the screen cannot be smoothly lifted or lowered.

  Further, since the engaging member is pushed or pulled in the radial direction, there is a problem that the clutch unit is enlarged and the take-up shaft of the screen that houses the clutch unit is enlarged.

  An object of the present invention is to provide a solar shading material elevating device including a clutch unit that can smoothly perform the elevating operation of the solar shading material.

In claim 1, the solar shading material can be lifted and supported by suspending and supporting the solar shading material, operating a single endless operation cord, and operating the lifting operation unit via the clutch unit. In the solar radiation shielding material elevating device, the clutch unit operates the elevating operation unit by operating one of the operation cords, and does not operate the elevating operation unit by operating the other operation cord. The clutch unit includes: a rotating drum that is rotated based on an operation of the operation code; a transmission drum that drives the lifting / lowering operation unit; a driving engagement tooth provided on the rotating drum; and Hidogakari Tomeha provided to act on the said drive locking teeth and Hidogakari Tomeha, of transmitting the rotation of the rotary drum by the driving engagement teeth and Hidogakari Tomeha the transfer drum That a clutch portion, the clutch portion, with a movably supported guide groove formed in the clutch drum was axially, the clutch protrusive portion which moves the formed on the rotary drum along the guide groove The clutch portion is configured to be movable in the axial direction of the rotary drum and the transmission drum, and the rotation of the rotary drum is transmitted to the transmission drum by the biasing force of the biasing means. The rotating drum can be moved against the urging force of the urging means when the driving engagement teeth , the driven engagement teeth and the clutch portion are engaged.

  As described above in detail, the present invention can provide a solar shading material elevating device including a clutch unit that can smoothly perform the elevating operation of the solar shading material.

It is a partially broken front view which shows the double hoisting curtain of 1st embodiment. It is a right view which shows 1st embodiment. It is a partially broken left view which shows 1st embodiment. It is sectional drawing which shows an operating device. It is a front view which shows the pulley in an operating device. It is a front view which shows the gear mechanism in an operating device. It is a front view which shows a plate. It is a disassembled perspective view which shows a clutch unit. It is a side view which shows a drive drum. It is explanatory drawing which shows operation | movement of a clutch unit. It is an expanded view which shows the guide groove of a transmission drum. It is explanatory drawing which shows operation | movement of a clutch unit. It is explanatory drawing which shows operation | movement of a clutch unit. It is explanatory drawing which shows operation | movement of a clutch unit. It is explanatory drawing which shows operation | movement of a clutch unit. It is explanatory drawing which shows operation | movement of a clutch unit. It is sectional drawing which shows a stopper unit. It is an expanded view which shows a stopper guide groove. It is explanatory drawing which shows operation | movement of a clutch unit. It is explanatory drawing which shows operation | movement of a clutch unit. It is explanatory drawing which shows operation | movement of a clutch unit. It is explanatory drawing which shows operation | movement of a clutch unit. It is explanatory drawing which shows operation | movement of a clutch unit. It is explanatory drawing which shows operation | movement of a clutch unit. It is explanatory drawing which shows operation | movement of a clutch unit. It is sectional drawing which shows 2nd embodiment. It is sectional drawing which shows 2nd embodiment. It is a disassembled perspective view which shows 2nd embodiment. It is sectional drawing which shows 2nd embodiment. It is sectional drawing which shows 2nd embodiment. It is explanatory drawing which shows operation | movement of a clutch unit. It is explanatory drawing which shows operation | movement of a clutch unit.

(First embodiment)
Hereinafter, a first embodiment in which the present invention is embodied in a double-raised curtain as a solar shading device will be described with reference to the drawings.

  As shown in FIGS. 1 and 2, the front fabric 2a of the curtain raised from the front surface of the head box 1 is suspended and supported as a solar shading material, and the rear fabric 2b is also suspended from the rear surface of the head box 1 as a solar shading material. Supported below.

A plurality of ring tapes 3 are attached to the rear surfaces of the front fabric 2a and the rear fabric 2b in the vertical direction, and a plurality of rings 4 are attached to the ring tape 3 at equal intervals.
An elevating cord 5a is inserted into the ring 4 attached to the front fabric 2a. As shown in FIG. 3, the upper end of the lifting / lowering cord 5 a is wound from the front side of the head box 1 on a winding shaft 7 a that is rotatably supported by a support member 6 in the head box 1.

  A hook 8a is attached to the lower end of the lifting / lowering cord 5a, and the ring 4 located at the lowermost portion of the plurality of rings 4 is suspended and supported by the hook 8a. Therefore, when the lifting / lowering cord 5a is wound around the winding shaft 7a, the front fabric 2a is pulled up while being folded in order from the lower end as shown in FIG.

When the lifting / lowering cord 5a is rewound, the front fabric 2a returns to the state where it is suspended from the head box 1 in order from the top.
An elevating cord 5b is inserted through the ring 4 of the rear fabric 2b. As shown in FIG. 3, the upper end portion of the lifting / lowering cord 5b is wound from the rear side of the head box 1 around the winding shaft 7b rotatably supported by the support member 6 behind the winding shaft 7a. It is worn.

  A hook 8b is attached to the lower end of the lifting / lowering cord 5b, and the ring 4 located at the lowermost portion of the plurality of rings 4 is suspended and supported by the hook 8b. Accordingly, when the lifting / lowering cord 5b is wound around the winding shaft 7b, the rear fabric 2b is pulled up while being folded in order from the lower end.

When the lifting / lowering cord 5b is rewound, the rear fabric 2b returns to a state where it is suspended from the head box 1 in order from the top.
Drive shafts 9a and 9b made of hexagonal shafts are inserted in the center of the winding shafts 7a and 7b, and the winding shafts 7a and 7b are rotated based on the rotation of the drive shafts 9a and 9b.

The lifting / lowering cord 5a, the winding shaft 7a, and the drive shaft 9a constitute a first lifting / lowering operation portion, and the lifting / lowering cord 5b, the winding shaft 7b, and the driving shaft 9b constitute a second lifting / lowering operation portion. .
Next, an operation device for rotationally driving the drive shafts 9a and 9b will be described.

  As shown in FIG. 4, in the operating device 10 provided at one end of the head box 1, the base end portion of the case 11 is fitted and fixed to the end portion of the head box 1. The tip of the case 11 extends downward from the lower edge of the head box 1 and a cap 13 having the same shape as the tip is screwed through the plate 12 shown in FIG.

  As shown in FIGS. 5 and 6, a support shaft 14 a is formed at the tip of the case 11, and a support shaft 14 b is formed below the cap 13 so as to face the support shaft 14 a. In the front end portion of the case 11, a drive gear 15 is rotatably supported on the support shafts 14a and 14b.

  The drive gear 15 has a hexagonal shaft portion 16 projecting toward the cap 13, and a pulley 17 is fitted to the shaft portion 16. An endless ball chain 18 is hung on the pulley 17 as an operation cord.

  When the pulley 17 is rotated by the operation of the ball chain 18, the drive gear 15 is rotated integrally with the pulley 17. The plate 12 is interposed between the drive gear 15 and the pulley 17.

  Above the drive gear 15 and the pulley 17, two first and second shafts 19 a and 19 b are disposed at positions equidistant from the rotation center of the drive gear 15. The first and second shafts 19 a and 19 b have a tip portion formed in a hexagonal shaft shape, and the tip portions are fitted into hexagon holes 20 a and 20 b formed in the plate 12 and the cap 13.

Accordingly, the first and second shafts 19 a and 19 b are supported by the head box 1 through the cap 13 and the plate 12 so as not to rotate.
As shown in FIG. 6, transmission gears 21a and 21b that mesh with the drive gear 15 are rotatably supported on the first and second shafts 19a and 19b. When the drive gear 15 is rotated in the direction of arrow A shown in FIG. 6, the transmission gears 21a and 21b are rotated in the direction of arrow b. When the drive gear 15 is rotated in the direction of arrow B, the transmission gears 21a and 21b are rotated. Is rotated in the direction of arrow a.

  As shown in FIG. 8, a disk part 22 having a diameter larger than that of the gear part is formed on the front end side of the transmission gears 21a and 21b, and the outer peripheral part of the disk part protrudes toward the front end side. Two convex portions 23 are formed in line symmetry with respect to the center.

  Then, the rotation of the transmission gears 21a and 21b is transmitted to the first and second clutch units 24a and 24b supported by the first and second shafts 19a and 19b via the convex portion 23.

  Next, the configuration of the first clutch unit 24a will be described. As shown in FIGS. 8 and 15, the first clutch unit 24a includes a rotary drum 25, a clutch drum 26 as a transmission portion, a transmission drum 27, a stop spring 28, a slip spring 29, and the first shaft 19a. It consists of.

  The rotary drum 25 is formed in a cylindrical shape, and the first shaft 19a is passed through the through hole 30 formed at the tip, and the first drum 19a is rotatable and moved in the axial direction. It is supported impossible.

  A cutout portion 31 that can be engaged with the convex portion 23 of the transmission gear 21a is formed in the outer peripheral portion of the front end surface of the rotary drum 25 in a range of 90 ° with respect to the center. Therefore, the transmission gear 21a can rotate relative to the rotary drum 25 within a range of 90 °, and after the convex portion 23 comes into contact with the edge of the cutout portion 31, the rotary drum 25 is integrated with the transmission gear 21a. It is designed to be rotated.

A semi-oval concave portion 32 is formed in the front end edge of the rotary drum 25 in the axial direction of the first shaft 19a.
The clutch drum 26 is supported so as to be rotatable and axially movable with respect to the first shaft 19a, and an engagement piece 33 protruding into the rotary drum 25 is formed on one of the clutch drums.

  The engaging piece 33 is formed in a range of 60 ° with respect to the center, and a step portion 34 is formed in the rotary drum 25 in a range of 180 ° on the rotation locus of the engaging piece 33 as shown in FIG. Is formed.

Therefore, the clutch drum 26 can rotate relative to the rotary drum 25 in a range of approximately 120 ° until the end edge of the engagement piece 33 contacts the end edge of the stepped portion 34.
The stop spring 28 is wound around the first shaft 19 a between the clutch drum 26 and the rotary drum 25. As shown in FIG. 10, the stop spring 28 is bent so that both end portions 35 a and 35 b protrude on the rotation locus of the step portion 34 of the rotary drum 25 on both sides of the engagement piece 33.

When the engagement piece 33 comes into contact with one of the end portions 35a and 35b, the friction between the stop spring 28 and the first shaft 19a increases, and the rotation of the clutch drum 26 is prevented.
Further, when the step portion 34 of the rotary drum 25 contacts either one of the end portions 35a and 35b, the friction between the stop spring 28 and the first shaft 19a is reduced, and the clutch drum 26 and the stop spring 28 are moved to the rotary drum. Rotate integrally with 25.

  A guide groove 36 having a semicircular cross section is formed on the outer peripheral surface of the clutch drum 26 in the circumferential direction. As shown in FIG. 11, the guide groove 36 is formed continuously with respect to the engagement groove 37 at the center so that the release grooves 38 at both ends are offset toward the rotary drum 25.

  A clutch ball 39 formed of a steel ball is accommodated in the guide groove 36 so as to be movable in the guide groove 36. Further, when the clutch ball 39 moves in the guide groove 36, the clutch ball 39 is projected and retracted with respect to the concave portion 32 of the rotary drum 25 as shown in FIGS.

  As shown in FIG. 15, the slip spring 29 is disposed between the clutch drum 26 and the first shaft 19a. The clutch drum 26 is urged toward the transmission drum 27 by the urging force of the slip spring 29 with the first shaft 19a as a fulcrum.

Such clutch drum 26, clutch ball 39 and slip spring 29 constitute a clutch portion.
The transmission drum 27 is supported so as to be rotatable with respect to the first shaft 19a and not movable in the axial direction. The front end portion of the transmission drum 27 is formed to be rotatable on the outer periphery of the clutch drum 26, and three locking projections 40 protruding toward the rotary drum 25 are formed on the front end surface at equal intervals.

  As shown in FIG. 14, when the clutch ball 39 moves into the engagement groove 37, the clutch ball 39 moves to a position where it engages with any one of the locking projections 40.

  A pair of connecting pieces 41 is formed at the base end portion of the transmission drum 27, and the connecting pieces 41 are fitted to the joint cap 42. A hexagonal hole is formed at the center of the joint cap 42, and the drive shaft 9a is fitted into the hexagonal hole.

Therefore, the drive shaft 9 a rotates integrally with the transmission drum 27 via the joint cap 42.
As shown in FIGS. 15 and 16, the second clutch unit 24b has the same configuration as that of the first clutch unit 24a except that the clutch ball 39 is located on the opposite side of the locking projection 40. is there.

  As shown in FIG. 1, first and second stopper units 43 a and 43 b are disposed adjacent to the joint cap 42. Since the first and second stopper units 43a and 43b have the same configuration except that they operate in the same manner based on the rotation in the reverse direction, only the first stopper unit 43a will be described.

  The first stopper unit 43a has the same configuration as the stopper described in, for example, Japanese Patent Application Laid-Open No. 11-1871973. As shown in FIG. 17, the stopper drum 44 rotates integrally with the drive shaft 9a, with the drive shaft 9a being inserted into the center.

  The stopper case 45 is disposed around the stopper drum 44 and is supported so as not to rotate with respect to the head box 1. The stopper ball 46 is disposed between the stopper drum 44 and the stopper case 45.

  A slide groove 47 having a semicircular cross section is formed on the inner peripheral surface of the stopper case 45 to support the stopper ball 46 so as to be movable in the direction along the drive shaft 9a. A guide groove 48 having a semicircular cross section is formed on the outer peripheral surface of the stopper drum 44 so as to circulate on the outer peripheral surface.

  The stopper ball 46 is movable along the slide groove 47 and the stopper guide groove 48. Therefore, when the stopper drum 44 is rotated, the stopper ball 46 moves along the slide groove 47 while relatively rotating on the outer peripheral surface of the stopper drum 44 along the stopper guide groove 48.

  The structure of the stopper guide groove 48 will be described with reference to a development view shown in FIG. In FIG. 18, when the stopper drum 44 is rotated in the pulling-up direction of the front fabric 2 a, the stopper ball 46 relatively moves on the stopper guide groove 48 in the arrow C direction.

Further, when the stopper drum 44 is rotated in the pulling-down direction of the front fabric 2a, the stopper ball 46 relatively moves in the arrow D direction on the stopper guide groove 48.
A pull-down groove 49 is formed on one side of the outer peripheral surface of the stopper drum 44. The pull-down groove 49 communicates with a first return groove 50 that branches in the direction of arrow C, and the first return groove 50 joins the pull-up groove 51 in the direction of arrow C.

  The pulling groove 51 communicates with a stop groove 52 that branches in the direction of arrow D. The stop groove 52 stops at a locking portion 53 in the direction of arrow D, and passes through a second return groove 54 that extends in the direction of arrow C. , And merges with the pull-down groove 49.

  In the first stopper unit 43a configured as described above, when the drive shaft 9a is rotated in the pulling-up direction of the front fabric 2a via the first clutch unit 24a based on the operation of the ball chain 18, the stopper The ball 46 moves in the direction of the arrow C in the pulling groove 51.

  When the ball chain 18 is released after the front fabric 2a is pulled up to a desired position, the lifting / lowering cord 5a is rewound by the weight of the front fabric 2a, and the stopper drum 44 is rotated via the drive shaft 9a. Moves in the direction of the arrow D in the pulling groove 51.

Then, the stopper ball 46 engages with the locking portion 53, and further rotation of the stopper drum 44 is prevented. Therefore, in this state, the weight drop of the front fabric 2a is prevented.
Next, when lowering the front fabric 2a, if the ball chain 18 is operated and the front fabric 2a is slightly pulled up, the stopper ball 46 is pulled down from the locking portion 53 through the second return groove 54 to the pull-down groove 49. Be guided in.

As a result, the stopper ball 46 can go around in the pull-down groove 49 in the direction of arrow D. Therefore, if the ball chain 18 is released, the lowering operation can be performed by the weight of the front fabric 2a.
Further, when the front fabric 2a is further pulled up from the state where the stopper ball 46 is engaged with the locking portion 53, the ball chain 18 is operated in the pulling direction of the front fabric 2a.

  Then, the stopper ball 46 is guided from the locking portion 53 through the second return groove 54 into the pull-down groove 49, and further guided through the first return groove 50 into the pull-up groove 51. Therefore, the pull-up operation of the front fabric 2a by the ball chain 18 becomes possible.

The stopper unit 43b operates in the same manner as the first stopper unit 43a based on the rotation of the drive shaft 9b in the opposite direction to the drive shaft 9a of the stopper drum 44.
Next, the operation of the double hoisting curtain configured as described above will be described.

[Pulling up the front fabric 2a]
In order to pull up the front fabric 2a, the ball chain 18 suspended from the pulley 17 to the indoor side is pulled downward. Then, the drive gear 15 is rotated in the direction of arrow A shown in FIG. 6, and accordingly, the transmission gears 21a and 21b are rotated in the direction of arrow a.

  As the transmission gear 21a rotates, the rotary drum 25 of the first clutch unit 24a rotates in the same direction. Then, the rotating drum 25 rotates relative to the clutch drum 26, and the clutch ball 39 moves from the release groove 38 into the engagement groove 37 as shown in FIGS. Then, the clutch ball 39 is engaged with the recess 32 of the rotary drum 25 and the locking protrusion 40 of the clutch drum 26.

  Further, as shown in FIG. 10B, the step portion 34 of the rotary drum 25 abuts on the end portion 35 a of the stop spring 28. Then, the friction between the stop spring 28 and the first shaft 19a is reduced, and the rotary drum 25, the stop spring 28, and the clutch drum 26 are rotated together. Accordingly, the rotation of the rotary drum 25 is transmitted to the clutch drum 26.

  When the clutch drum 26 is rotated, the drive shaft 9 a is rotated via the joint cap 42. Then, the winding shaft 7a is rotated, the lifting / lowering cord 5a is wound up, and the front fabric 2a is pulled up.

  At this time, in the first stopper unit 43a, the stopper drum 44 rotates as the drive shaft 9a rotates. Then, the stopper ball 46 moves relative to the locking portion 53 in the direction of arrow C, moves in the pull-down groove 49, moves into the pull-up groove 51 through the first return groove 50, and circulates in the pull-up groove 51. It becomes a state to do.

Accordingly, the front fabric 2a is pulled up by pulling the ball chain 18 hanging down indoors downward.
During such a pulling operation of the front fabric 2a, the rear fabric 2b is not lifted or lowered. That is, the drive gear 15 is rotated in the direction of arrow A, and the transmission gear 21b is rotated in the direction of arrow b. Then, as shown in FIGS. 15 and 16, the clutch ball 39 is engaged with the engagement groove based on the rotation of the rotary drum 25 of the second clutch unit 24b in a state where the rotation of the clutch drum 26 is blocked by the stop spring 28. It moves from 37 into the release groove 38.

  In this state, since the clutch ball 39 moves into the recess 32, it does not engage with the locking protrusion 40 of the transmission drum 27. Accordingly, the rotation of the rotary drum 25 is not transmitted to the transmission drum 27.

  Further, after the clutch ball 39 moves into the recess 32, when the step 34 of the rotary drum 25 comes into contact with the end 35a of the stop spring 28, the rotary drum 25, the stop spring 28 and the clutch drum 26 rotate together. To do.

  In the stopper unit 43b, the stopper ball 46 is engaged with the locking portion 53, and the weight of the rear fabric 2b is prevented from dropping. Accordingly, the rear fabric 2b does not move up and down during the pulling operation of the front fabric 2a.

[Operation to stop pulling up front fabric 2a]
When the ball chain 18 is released after the front fabric 2a is pulled up to a desired position, the drive shaft 9a tends to rotate in the rewinding direction of the lifting / lowering cord 5a due to the weight of the front fabric 2a.

  Then, in the first stopper unit 43 a, the stopper ball 46 moves in the pulling groove 51 in the arrow D direction and engages with the locking portion 53. Then, the further rotation of the drive shaft 9a is prevented, and the weight drop of the front fabric 2a is prevented.

  At this time, the transmission drum 27 is rotated with the rotation of the drive shaft 9a, and the rotary drum 25 is rotated with the rotation of the transmission drum 27. Then, the clutch ball 39 moves from the engagement groove 37 to the release groove 38 as shown in FIGS. Further, since the rotary drum 25 can rotate relative to the transmission gear 21a within the range of the notch 31, the rotation of the rotary drum 25 is not transmitted to the transmission gear 21a.

Accordingly, since the drive gear 15 is not rotated, the second clutch unit 24b does not operate and the rear fabric 2b is not pulled up.
[Descent operation of front fabric 2a]
When lowering the front fabric 2a, the ball chain 18 hanging down indoors is slightly pulled downward. Then, the rotary drum 25 of the first clutch unit 24a is rotated via the drive gear 15 and the transmission gear 21a, and the transmission drum 27 is rotated based on the rotation of the rotary drum 25.

  Based on the rotation of the transmission drum 27, the stopper drum 44 of the first stopper unit 43a is rotated, the stopper drum 44 is rotated, and the stopper ball 46 moves in the direction of arrow C shown in FIG. To the lower groove 49 through the second return groove 54.

  When the ball chain 18 is released in this state, the stopper ball 46 can rotate in the direction of the arrow D relatively in the pulling groove 49, and the stopper drum 44 can rotate.

  Then, the drive shaft 9a and the take-up shaft 7a become rotatable, and the lifting cord 5a is rewound from the take-up shaft 7a by the weight of the front fabric 2a, so that the front fabric 2a can be lowered to the lower limit.

  At the start of such a lowering operation, the transmission drum 27 and the rotary drum 25 are rotated with the rotation of the drive shaft 9a, but the rotation of the clutch drum 26 is blocked by a stop spring 28.

  Then, the stopper ball 46 moves from the engagement groove 37 toward the release groove 38 in the guide groove 36 as shown in FIGS. 19 to 21, and moves into the release groove 38 as shown in FIG.

Therefore, after the rotating drum 25 has slightly rotated, the rotation of the transmission drum 27 is not transmitted to the rotating drum 25.
During the lowering operation of the front fabric 2a, the transmission gear 21b is slightly rotated through the drive gear 15 by the operation of the ball chain 18. At this time, in the second clutch unit 24b, as shown in FIGS. 15 and 16, the clutch ball 39 moves in a direction away from the locking projection 40 of the transmission drum 27, so that the transmission drum 27 is not rotated. .

Therefore, when the ball chain 18 is operated to lower the front fabric 2a, the rear fabric 2b does not operate.
Further, when the front fabric 2a starts to descend, the rotary drum 25 is slightly rotated. However, since the rotary drum 25 is rotated relative to the transmission gear 21a by the notch 31, the rotation of the rotary drum 25 is transmitted. There is no transmission to the gear 21a. Accordingly, the rear fabric 2b is not operated by the lowering operation of the front fabric 2a.

[Descent stop operation of front fabric 2a]
When the lowering operation of the front fabric 2a is stopped halfway, the ball chain 18 hanging down indoors is pulled slightly downward. Then, the drive gear 15 is rotated, and the rotary drum 25 of the first clutch unit 24a is rotated via the transmission gear 21a.

  Based on the rotation of the rotary drum 25, the rotary drum 25 rotates relative to the clutch drum 26, and the clutch ball 39 moves from the release groove 38 into the engagement groove 37 as shown in FIGS. Move to.

  Then, the locking protrusion 40 of the transmission drum 27 is engaged with the clutch ball 39, and the rotation of the transmission drum 27 is prevented. As a result, the rotation of the drive shaft 9a is prevented, the rotation of the stopper drum 44 is stopped, and the lowering operation of the front fabric 2a is stopped.

  When the rotating drum 25 is further rotated from this state, in the first stopper unit 43a, the stopper ball 46 moves in the pull-down groove 49 in the direction of arrow C, passes through the first return groove 50, and enters the pull-up groove 51. Move to.

  When the ball chain 18 is released in this state, the drive shaft 9a is rotated by the weight of the front fabric 2a, the stopper drum 44 is rotated, and the stopper ball 46 is relatively moved in the pulling groove 51 in the direction of arrow D.

  Then, since the stopper ball 46 is locked to the locking portion 53 and further relative movement is blocked, the rotation of the drive shaft 9a is blocked. Accordingly, the lowering operation of the front fabric 2a is stopped.

Even during such a descent stop operation, the rear fabric 2b is not operated by the operation of the ball chain 18 as in the case of the lifting operation and the descending operation of the front fabric 2a.
[Pulling up the rear fabric 2b]
In order to pull up the rear fabric 2b, the ball chain 18 suspended downward from the pulley 17 is pulled downward. Then, the drive gear 15 is rotated in the direction of arrow B shown in FIG. 6, and accordingly, the transmission gears 21a and 21b are rotated in the direction of arrow a.

  As the transmission gear 21b rotates, the rotary drum 25 of the second clutch unit 24b rotates in the same direction. And the 2nd clutch unit 24b and the stopper unit 43b operate | move similarly to the 1st clutch unit 24a and the 1st stopper unit 43a accompanying the raising operation | movement of the said front side cloth | dough 2a except the rotation direction.

As a result, the drive shaft 9b is rotated, the elevating cord 5b is wound up, and the rear fabric 2b is pulled up.
The front fabric 2a is not lifted or lowered during the pulling operation of the rear fabric 2b. That is, the drive gear 15 is rotated in the arrow B direction, and the transmission gear 21a is rotated in the arrow b direction. Then, in the first clutch unit 24a, as shown in FIGS. 15 and 16, the clutch ball 39 is engaged based on the rotation of the rotary drum 25 in a state where the rotation of the clutch drum 26 is blocked by the stop spring 28. It moves from the groove 37 into the release groove 38.

  In this state, the clutch ball 39 moves into the recess 32, so that it does not engage with the locking projection 40 of the rotating drum. Accordingly, the rotation of the rotary drum 25 is not transmitted to the transmission drum 27.

  Further, after the clutch ball 39 moves into the recess 32, when the step 34 of the rotary drum 25 comes into contact with the end 35a of the stop spring 28, the rotary drum 25, the stop spring 28 and the clutch drum 26 rotate together. To do.

  In the first stopper unit 43a, the stopper ball 46 is engaged with the locking portion 53 and is in a state of preventing the front fabric 2a from dropping its own weight. Therefore, the front fabric 2a does not operate during the pulling operation of the rear fabric 2b.

[Descent operation of rear fabric 2b]
When lowering the rear fabric 2b, the ball chain 18 hanging outward is pulled slightly downward. Then, the rotary drum 25 of the second clutch unit 24b is rotated via the drive gear 15 and the transmission gear 21b, and the transmission drum 27 is rotated based on the rotation of the rotary drum 25.

  Based on the rotation of the transmission drum 27, the stopper drum 44 of the stopper unit 43b is rotated, the stopper drum 44 is rotated, and the stopper ball 46 moves in the direction of arrow C shown in FIG. It moves into the pull-down groove 49 via the return groove 54.

  When the ball chain 18 is released in this state, the stopper ball 46 can rotate in the direction of the arrow D relatively in the pulling groove 49, and the stopper drum 44 can rotate.

  Then, the drive shaft 9b and the take-up shaft 7b become rotatable, the lifting cord 5b is rewound from the take-up shaft 7b by the weight of the rear dough 2b, and the rear dough 2b can be lowered to the lower limit.

  At the start of such a lowering operation, the transmission drum 27 and the rotary drum 25 of the second clutch unit 24b are rotated along with the rotation of the drive shaft 9b, but the clutch drum 26 is prevented from rotating by a stop spring 28. ing.

  Then, the clutch ball 39 moves from the engagement groove 37 toward the release groove 38 in the guide groove 36 as shown in FIGS. 19 and 20, and moves into the release groove 38 as shown in FIG.

Therefore, after the rotating drum 25 has slightly rotated, the rotation of the transmission drum 27 is not transmitted to the rotating drum 25.
During the lowering operation of the rear fabric 2b, the transmission gear 21a is slightly rotated by the operation of the ball chain 18 through the drive gear 15. However, in the first clutch unit 24a, the clutch ball 39 is connected to the transmission drum. The transfer drum 27 is not rotated because it moves in a direction away from the 27 locking projections 40.

Accordingly, when the ball chain 18 is operated to lower the rear fabric 2b, the front fabric 2a does not operate.
Further, when the rear fabric 2b starts to descend, the rotary drum 25 of the second clutch unit 24b is slightly rotated, but the rotary drum 25 rotates relative to the transmission gear 21b by the notch 31. Therefore, the rotation of the rotating drum 25 is not transmitted to the transmission gear 21b. Therefore, the front fabric 2a is not operated by the lowering operation of the rear fabric 2b.

[Descent stop operation of rear fabric 2b]
When the lowering operation of the rear fabric 2b is stopped halfway, the ball chain 18 that is suspended outside the room is pulled slightly downward. Then, the drive gear 15 is rotated, and the rotary drum 25 of the second clutch unit 24b is rotated via the transmission gear 21b.

  Then, the second clutch unit 24b and the stopper unit 43b operate in the same manner as the operation of the first clutch unit 24a and the first stopper unit 43a during the lowering stop operation of the front fabric 2a, and the lowering of the rear fabric 2b occurs. The operation is stopped.

Even during such a descent stop operation, the front fabric 2a is not operated by the operation of the ball chain 18 as in the lifting operation and the descending operation of the rear fabric 2b.
[Operation error prevention operation of clutch units 24a and 24b]
An operation error preventing operation in the case where the ball chain 18 hanging down indoors is pulled downward to rotate the rotating drum 25 of the first clutch unit 24a in order to pull up the front fabric 2a will be described.

  As shown in FIGS. 22 and 23, when the clutch ball 39 is about to move from the release groove 38 to the engagement groove 37 based on the rotation of the rotary drum 25, the clutch ball 39 contacts the top of the locking protrusion 40. You may touch.

  In this case, since the clutch drum 26 is movable in the axial direction, the clutch drum 26 moves toward the driving drum against the urging force of the slip spring 29 as shown in FIG. Then, as shown in FIG. 24, the clutch ball 39 moves into the engagement groove 37.

  When the rotating drum 25 is further rotated from this state and the locking projection 40 gets over the clutch ball 39, the clutch drum 26 returns to the original position by the biasing force of the slip spring 29 as shown in FIG. Then, the clutch ball 39 can be engaged with the locking protrusion 40 and the recess 32.

  Therefore, when the rotary drum 25 is rotated to the pull-down operation side of the front fabric 2a, the clutch ball 39 moves from the release groove 38 into the engagement groove 37 even if the clutch ball 39 comes into contact with the top of the locking projection 40. Thus, the rotation of the rotary drum 25 is transmitted to the transmission drum 27.

Further, the second clutch unit corresponding to the rear fabric 2b operates in the same manner.
With the double-raised curtain as described above, the following effects can be obtained.
(1) By operating one ball chain 18, the lifting operation of the front fabric 2 a and the lifting operation of the rear fabric 2 b can be performed independently.
(2) Since the lower fabric 2a and the rear fabric 2b can be lowered by their own weight, the lowering operation can be easily performed.
(3) Since the raising / lowering operation of the front fabric 2a and the rear fabric 2b can be performed by the single ball chain 18, the lifting operation can be easily and quickly performed.
(4) The rear fabric 2b is not lifted or lowered during the lifting operation of the front fabric 2a, and the front fabric 2a is not lifted or lowered during the lifting operation of the rear fabric 2b.
(5) When pulling up the front fabric 2a, an operation of pulling the ball chain 18 hanging down indoors downward may be performed. If the ball chain 18 is released after the front fabric 2a is pulled up to a desired position, the front fabric 2a is prevented from falling by its own weight, and the front fabric 2a is suspended and supported at the desired position. When lowering the front fabric 2a, if the ball chain 18 hanging down indoors is slightly lowered and then released, the front fabric 2a can be lowered by its own weight. Further, when stopping the lowering operation of the front fabric 2a, the ball chain 18 hanging down indoors may be pulled slightly downward. Therefore, the raising / lowering operation of the front fabric 2a can be performed by operating the ball chain 18 hanging down indoors, so that the raising / lowering operation can be performed quickly and easily.
(6) When pulling up the rear fabric 2b, an operation of pulling the ball chain 18 hanging down to the outdoor side downward may be performed. Further, if the ball chain 18 is released after the rear side fabric 2b is pulled up to a desired position, the lower weight of the rear side fabric 2b is prevented and the rear side fabric 2b is suspended and supported at the desired position. When lowering the rear fabric 2b, if the ball chain 18 hung outward is slightly lowered and released, the lower fabric 2b can be lowered by its own weight. In addition, when stopping the lowering operation of the rear fabric 2b, the ball chain 18 suspended from the outdoor side may be pulled slightly downward. Therefore, since the raising / lowering operation of the back side fabric 2b can be performed by operating the ball chain 18 that hangs down the outdoor side, the raising / lowering operation can be performed quickly and easily.
(7) When the rotary drum 25 is rotated to the lifting operation side of the front fabric 2a or the rear fabric 2b, the clutch ball 39 is engaged with the release groove 38 even if the clutch ball 39 contacts the top of the locking projection 40. The rotation of the rotary drum 25 can be reliably transmitted to the transmission drum 27 by being moved into the joint groove 37. Therefore, the raising / lowering operation of the front fabric 2a or the rear fabric 2b can be performed smoothly.
(8) Since the clutch drum 26 is moved in the axial direction and unnecessary engagement between the clutch ball 39 and the top of the locking projection 40 can be avoided, the first and second clutch units 24a and 24b can be There is no increase in size in the radial direction.
(9) Since the clutch ball 39 is moved in the direction of the rotation axis of the rotary drum 25, the first and second clutch units 24a and 24b are not enlarged in the radial direction.

(Second embodiment)
FIG. 26 shows a second embodiment. This embodiment shows another embodiment for the first and second clutch units 24a, 24b of the first embodiment. The configuration other than the clutch unit is the same as that of the first or second embodiment.

  The third shaft 71 is supported in a non-rotatable manner with respect to the head box via a cap, as in the above embodiment. The driving drum 72 is supported so as to be rotatable and non-movable in the axial direction with respect to the third shaft 71. Similarly to the above embodiment, the driving drum 72 and the transmission gear 89 shown in FIG. Is rotated through.

  The transmission gear 89 is rotatably supported with respect to the third shaft 71, and an engaging portion 90 is formed in a range of 60 ° with respect to the center. The engaging part 72a of the drive drum 72 shown in FIG. 26 is located on the same rotation locus as the engaging part 90 of the transmission gear 89, and is formed in a range of 60 ° with respect to the center.

  Accordingly, the transmission gear 89 and the drive drum 72 rotate together when the engaging portions 90 and 72a abut against each other, and therefore, between the transmission gear 89 and the drive drum 72, as in the first embodiment. Has an idle region of a predetermined angle.

  A clutch drum 73 is supported adjacent to the drive drum 72 so as to be rotatable with respect to the third shaft 71 and movable in the axial direction. As shown in FIG. 28, the clutch drum 73 has a guide groove 74 formed on the outer peripheral surface thereof so as to be symmetrical with respect to the center, and the guide groove 74 has an engaging groove 75 and a release groove 76 offset in the axial direction. Has been formed.

  A slip spring 77 is disposed between the drive drum 72 and the clutch drum 73. The clutch drum 73 is biased in the direction away from the drive drum 72, that is, in the direction of arrow E shown in FIG. 26, by the biasing force of the slip spring 77 with the drive drum 72 as a fulcrum.

  A collar 78 is non-rotatably fitted to the third shaft 71 adjacent to the clutch drum 73, and a stop spring 79 is wound around the outer peripheral surface of the collar 78. As shown in FIG. 27, both end portions 80a and 80b of the stop spring 79 are bent in the radial direction, and the engaging portion 73a of the clutch drum 73 protrudes between the both end portions 80a and 80b.

  When the engaging portion 73a comes into contact with one of the end portions 80a and 80b of the stop spring 79, the friction between the stop spring 79 and the collar 78 increases, and the rotation of the clutch drum 73 is prevented. ing.

  A rotary drum 81 is supported around the clutch drum 73 so as to be rotatable and movable in the axial direction. The rotating drum 81 is formed with an engaging recess 82 that opens toward the drive drum 72, and the engaging recess 82 is engaged with an engaging protrusion 83 formed on the drive drum 72. Accordingly, the rotating drum 81 is rotated integrally with the driving drum 72.

  A hemispherical clutch protrusion 84 that engages with the guide groove 74 of the clutch drum 73 is formed on the inner peripheral surface of the rotary drum 81. When the rotating drum 81 rotates, the clutch convex portion 84 is guided by the guide groove 74, and the rotating drum 81 moves in the axial direction.

  On the inner peripheral surface of the rotating drum 81, an engaging portion 85 that abuts against the end portions 80a and 80b of the stop spring 79 is formed. When the engaging portion 85 is engaged with one of the end portions 80a and 80b, the friction between the stop spring 79 and the collar 78 is reduced, and the stop spring 79 and the clutch drum 73 are rotated together with the rotary drum 81. The

  A transmission drum 86 is supported at the tip of the third shaft 71 so as to be rotatable and immovable in the axial direction. A pair of sawtooth driven locking teeth 87 are formed on the end surface on the proximal end side of the transmission drum 86, that is, on the end surface facing the rotating drum 81.

  A pair of sawtooth drive locking teeth 88 are formed on the end surface of the rotating drum 81, that is, the end surface facing the transmission drum 86. Then, when the rotary drum 81 is rotated and moved to the transmission drum 86 side, the drive locking teeth 88 are engaged with the driven locking teeth 87, and the rotary drum 81 and the transmission drum 86 are rotated together.

  Further, as shown in FIGS. 29 and 30, when the rotary drum 81 moves to the drive drum 72 side, the engagement between the drive locking teeth 88 and the driven locking teeth 87 is released, and the transmission drum 86 can be freely moved. It can be rotated.

  The transmission drum 86 is coupled to rotate integrally with a drive shaft similar to the drive shafts 9a and 9b of the first embodiment, for example. The rotation operation of the drive shaft is controlled by a stopper unit similar to that of the first embodiment.

  In the double hoisting curtain provided with the clutch unit configured as described above, when the driving drum 72 is rotated in the fabric pulling direction by the operation of the ball chain, the rotation of the clutch drum 73 is blocked by the stop spring 79. In this state, the rotary drum 81 is rotated.

Then, the clutch convex portion 84 is guided into the engagement groove 75, the rotary drum 81 moves toward the transmission drum 86, and the driving locking teeth 88 engage with the driven locking teeth 87.
Then, the rotation of the drive drum 72 is transmitted to the transmission drum 86 via the rotation drum 81, and the dough is pulled up based on the rotation of the transmission drum 86.

  At this time, after the drive locking teeth 88 are engaged with the driven locking teeth 87, the engaging portion of the rotary drum 81 contacts the end 80a of the stop spring 79, so that the clutch drum 73 and the stop spring 79 are driven. It is rotated integrally with the drum 72.

When the ball chain is released after the dough is pulled up to a desired position, the weight of the dough is prevented from dropping due to the operation of the stopper unit.
If the ball chain is slightly operated in the same direction as the pulling operation from the state in which the dough is suspended and supported at a desired position to allow the weight to be lowered by the stopper unit, the drive shaft and the transmission drum 86 are used. Thus, the rotating drum 81 is rotated in the lowering direction of the dough.

  Then, the rotating drum 81 is rotated in a state where the rotation of the clutch drum 73 is blocked, and the rotating drum 81 moves to the driving drum 72 side based on the rotation. As a result, the engagement between the driving locking teeth 88 of the rotary drum 81 and the driven locking teeth 87 of the transmission drum 86 is released, and the transmission drum 86 is freely rotatable. Accordingly, the dough descends due to its own weight.

  To stop the lowering operation of the dough, when the ball chain is further pulled in the same direction, the driving drum 72 is rotated and the rotating drum 81 is engaged with the transmission drum 86. As in the first embodiment, the operation of the stopper unit prevents the weight of the fabric from falling.

With such an operation, the scooping curtain provided with the clutch unit of this embodiment can obtain the same effects as those of the first embodiment.
In this embodiment, since the pair of clutch protrusions 84 of the rotating drum 81 are engaged with the pair of guide grooves 74 of the clutch drum 73, the rotating drum 81 can be smoothly moved in the axial direction.

  Further, when the driving drum 72 is rotated and the driving locking teeth 88 are engaged with the driven locking teeth 87 in order to pull up the curtain fabric, as shown in FIG. The tip of the driven locking tooth 87 may come into contact.

  In such a case, the rotating drum 81 and the clutch drum 73 move in the axial direction against the urging force of the slip spring 77 as shown in FIG. As a result, the drive locking teeth 88 get over the driven locking teeth 87 and engage with each other as shown in FIG.

Accordingly, the driving engagement teeth 88 and the driven engagement teeth 87 can be reliably engaged, and the curtain fabric can be raised and lowered smoothly.
The above embodiment can be modified as follows.
The number of the locking protrusions 40 of the transmission drum 27 may be only one.
The first and second stopper units 43a and 43b may be provided at arbitrary positions in the head box 1 as long as they can pass through the drive shafts 9a and 9b.
-It may be applied to an elevating device for a pleated curtain or a horizontal blind, instead of a curtain for raising and a roll blind.
The guide groove 36 of the clutch drum 26 may be provided with a release groove 38 only on one side of the engagement groove 37.

1 Head box 2a, 2b Shield 18 Operation code (ball chain)
7a, 7b Elevating part (winding shaft)
24a, 24b Clutch unit 25, 81 Rotating drum 27, 86 Transmission drum 32, 88 First engaging means (concave, drive locking tooth)
40,87 Second engaging means (locking protrusion, driven locking tooth)
26, 73 Clutch part (clutch drum)
39,84 Clutch part (clutch ball, clutch convex part)
29,77 Biasing means (slip spring)

Claims (1)

The solar shading material elevating device that supports the solar shading material in a suspended manner, operates a single endless operation cord, and operates the elevating operation unit via the clutch unit, thereby raising and lowering the solar shading material. In
The clutch unit operates the lifting / lowering unit by operating one of the operation codes, and does not operate the lifting / lowering unit by operating the other of the operation cords.
The clutch unit is
A rotating drum that is rotated based on the operation of the operation code;
A transmission drum for driving the elevating unit;
A driving locking tooth provided on the rotating drum and a driven locking tooth provided on the transmission drum engaged with the driving locking tooth;
It acts on the drive engaging Tomeha and Hidogakari Tomeha, and a clutch portion for transmitting the rotation of the rotary drum to the transfer drum by the drive locking teeth and Hidogakari Tomeha,
The clutch portion is composed of a guide groove formed in a clutch drum supported so as to be movable in the axial direction, and a clutch convex portion formed in the rotating drum and moving along the guide groove. Is provided so as to be movable in the axial direction of the rotary drum and the transmission drum, and the clutch portion is elastically held at a position where the rotation of the rotary drum is transmitted to the transmission drum by the biasing force of the biasing means. The solar shading material lifting / lowering device characterized in that the rotating drum can be moved against the urging force of the urging means when the driving engagement tooth and the driven engagement tooth and the clutch portion are engaged.

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