JP2010255386A - Slat driving device of horizontal blind - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a slat driving device of a horizontal blind capable of preventing size of a head box from being increased irrespective of the presence of an elevating shaft and a tilt shaft in the head box. <P>SOLUTION: In this slat driving device of the horizontal blind, the tilt shaft 12 is arranged in the direction of diagonal line of the head box 1 for the elevating shaft 8, and a gear device for rotating and driving the tilt shaft 12 and the elevating shaft 8 based on the operation of one operation cord is provided at one end of the head box 1. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  According to the present invention, a lifting shaft for raising and lowering the slat and a tilt shaft for adjusting the angle of the slat are independently provided in the head box, and the slat raising and lowering operation and the slat angle adjusting operation are common operation cords (operation chain). It is related with the slat drive device of the horizontal blind performed by.

  As one type of horizontal blind, the vertical axis and the tilt axis are arranged in parallel in the head box, and the angle of the slat is adjusted by rotating the tilt axis by operating the operating device operated with a single operation code. There is one in which a slat is moved up and down by rotating a lifting shaft (see Patent Document 1).

  In such a horizontal blind, a tilt shaft is disposed above the lifting shaft in the head box. Then, the lifting / lowering cord is spirally wound or unwound by the winding shaft rotated based on the rotation of the lifting / lowering shaft, and the slat is lifted / lowered. Further, the tilt shaft is inserted into the tilt drum, and the slat is rotated via the ladder cord by rotating the tilt drum with the tilt shaft.

  The operation device rotationally drives a pulley with an operation cord, and transmits the rotation of the pulley to a lifting shaft and a tilt shaft. If the output shaft of the pulley is directly connected to the lifting shaft, the operating force required for pulling up the slats is large. Therefore, a planetary gear reduction device is interposed between the pulley output shaft and the lifting shaft to reduce the operating force. I have to.

JP 2000-145328 A

  In the horizontal blind as described above, since the elevating axis and the tilt axis are disposed in the head box at positions spaced apart in the vertical direction, the head box is increased in size in the height direction, which is not preferable from an aesthetic point of view.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a horizontal blind slat drive device that can prevent an increase in size of a head box while having a lift shaft and a tilt shaft in the head box.

  According to the first aspect of the present invention, the lift shaft and the tilt shaft are supported in the head box so as to be rotatable in parallel, the winding shaft of the lift cord is rotated by the lift shaft, and the slats can be lifted and lowered by the tilt shaft. In the horizontal blind that rotates and adjusts the angle of the slat, the tilt shaft is arranged in a diagonal direction of the head box with respect to the lifting shaft, and the head box has one end on the one end based on the operation of a single operation code. A gear device that rotationally drives the tilt shaft and the lifting shaft was provided.

According to a second aspect of the present invention, the gear device includes a spur gear that decelerates the rotation of the pulley and transmits it to the transmission shaft, and a spur gear that decelerates the rotation of the transmission shaft and transmits it to the lifting shaft.
According to a third aspect of the present invention, the tilt shaft is connected to the transmission shaft.

According to a fourth aspect of the present invention, the rotation center of the pulley, the rotation center of the transmission shaft, and the rotation center of the lifting shaft are not arranged linearly.
According to a fifth aspect of the present invention, the tilt axis is provided at the lower corner of the head box.

  According to a sixth aspect of the present invention, the drive shaft is rotatably supported by the support member, the tilt drum is rotatably supported by the support member coaxially with the take-up shaft, and the drive gear is attached to the tilt shaft. The tilt drum was driven to rotate.

  ADVANTAGE OF THE INVENTION According to this invention, the slat drive device of the horizontal blind which can prevent the enlargement of a head box can be provided, providing a raising / lowering axis and a tilt axis in a head box.

It is a front view which shows the horizontal blind of one Embodiment. It is a side view which shows the horizontal blind of one Embodiment. It is a top view which shows the horizontal blind of one Embodiment. It is a front view which shows an operation unit. It is a side view which shows an operation unit. It is a side view which shows meshing | engagement of a gear apparatus. It is a disassembled perspective view which shows a gear apparatus. It is the sectional view on the AA line of FIG. FIG. 6 is a sectional view taken along line B-B in FIG. 5. It is a side view which shows the drive gear and the driven gear supported by the support member. It is a disassembled perspective view which shows the tilt drum and support cap which were attached to the support member.

  Hereinafter, an embodiment embodying the present invention will be described with reference to the drawings. In the horizontal blind shown in FIGS. 1 to 3, a multi-stage slat 3 is supported by a ladder tape 2 that is supported suspended from a head box 1, and a bottom rail 4 is attached to the lower end of the ladder tape 2.

  An elevating cord 5 is inserted into the slat 3 in the vicinity of the support position of the ladder tape 2, and the bottom rail 4 is suspended and supported at the lower end of the elevating cord 5. An upper end of the lifting / lowering cord 5 is wound around a winding shaft 7 rotatably supported by a support member 6 disposed in the head box 1.

  A hexagonal bar-shaped lifting shaft 8 is inserted into the winding shaft 7 so as not to be relatively rotatable. When the lifting / lowering shaft 8 is rotated, the winding shaft 7 is rotated. When the winding shaft 7 is rotated in the winding direction of the lifting / lowering cord 5, the lifting / lowering cord 5 is spirally wound around the winding shaft 7. Then, the bottom rail 4 and the slat 3 are pulled up. When the winding shaft 7 is rotated in the rewinding direction of the lifting / lowering cord 5, the lifting / lowering cord 5 is rewound and the bottom rail 4 and the slat 3 are lowered.

  An upper end of the ladder tape 2 is attached to the tilt drum 9 via a hook 18, and the tilt drum 9 is rotatably supported at one end of the support member 6. A spur gear 10 is integrally formed on one side of the tilt drum 9.

On the side of the support member 6, a support cap (bearing member) 11 is fixed to the head box 1, and the elevating shaft 8 is inserted through the support cap 11.
As shown in FIG. 10, a hexagonal bar-shaped tilt shaft 12 is rotatably supported by the support cap 11 at an obliquely lower position of the lifting shaft 8, that is, at a lower corner in the head box 1. A drive gear 13 that meshes with the driven gear 10 is fitted so as not to be relatively rotatable. When the tilt shaft 12 is rotated, the tilt drum 9 is rotated via the drive gear 13 and the driven gear 10.

  One end of the elevating shaft 8 is connected to a first output shaft 47 of the operation unit 14 attached to one end of the head box 1, and one end of the tilt shaft 12 is connected to an output shaft of the tilt unit 15. Yes. The input shaft of the tilt unit 15 is connected to a transmission shaft 39 that is the second output shaft of the operation unit 14.

  A pulley 16 is rotatably supported at the end of the operation unit 14, and an operation chain 17 is hooked on the pulley 16. When the operation chain 17 is operated to rotate the pulley 16 in the forward and reverse directions, the elevating shaft 8 and the tilt shaft 12 can be driven to rotate.

  The operation unit 14 selects a function of decelerating the rotation of the pulley 16 and transmitting it to the elevating shaft 8 and the tilt unit 15, and a state in which the slat 3 and the bottom rail 4 are prevented from falling by their own weight and a state in which the operation is allowed. A function and a function of not rotating the elevating shaft 8 when the tilt shaft 12 is rotated via the tilt unit 15.

  The tilt unit 15 rotates the tilt shaft 12 based on the rotation of the transmission shaft 39 of the operation unit 14, and when the tilt shaft 12 is rotated by a predetermined angle, that is, until the slat 3 is fully closed or reverse fully closed. A function of preventing the rotation of the second output shaft from being transmitted to the tilt shaft 12 when it is rotated is provided.

  The operation of the horizontal blind provided with such an operation unit 14 and tilt unit 15 will be described. As shown in FIG. 2, when the operation chain 17 suspended downward is lowered (in the direction of arrow A), the tilt shaft 12 is rotated via the operation unit 14 and the tilt unit 15.

  Then, the tilt drum 9 is rotated with the rotation of the tilt shaft 12, and the slat 3 is rotated via the ladder tape 2. At this time, the slat 3 is rotated so that the convex surface is on the indoor side.

  When the tilt shaft 12 is rotated by a predetermined angle, that is, when the slat 3 is rotated to the fully closed state in the substantially vertical direction, the operation chain 17 is continuously operated in the same direction by the operation of the tilt unit 15. Also, the rotation of the tilt shaft 12 is stopped.

Further, the elevating shaft 8 is not rotated by the operation of the operation unit 14 until the slat 3 is fully closed.
After the slat 3 is rotated to the fully closed state, when the operation chain 17 is further operated in the arrow A direction, the lifting shaft 8 is rotated and the winding shaft 7 is rotated in the winding direction of the lifting cord 5. . And the raising / lowering cord 5 is wound up by the winding shaft 7, the bottom rail 4 is pulled up, and the slat 3 is pulled up by the bottom rail 4 one by one.

  When the operation chain 17 is released in a state where the bottom rail 4 and the slat 3 are pulled up to a desired height, the operation unit 14 moves to prevent the lifting shaft 8 from rotating in the lifting / lowering cord rewinding direction. Descent is prevented and held at the desired height.

  As shown in FIG. 2, when the operation chain 17 hanging downward is pulled downward (in the direction of arrow B), the tilt shaft 12 is rotated via the operation unit 14 and the tilt unit 15.

  Then, the tilt drum 9 is rotated with the rotation of the tilt shaft 12, and the slat 3 is rotated via the ladder tape 2. At this time, the slat 3 is rotated so that the convex surface becomes the outdoor side.

  When the tilt shaft 12 is rotated by a predetermined angle, that is, when the slat 3 is rotated to the reverse fully closed state in a substantially vertical direction, the operation chain 17 is continuously operated in the same direction by the operation of the tilt unit 15. However, the rotation of the tilt shaft 12 is stopped.

At this time, the elevating shaft 8 is not rotated by the operation of the operation unit 14 until the slat 3 is in the reverse fully closed state.
After the slat 3 is turned to the reverse fully closed state, when the operation chain 17 is further pulled in the direction of arrow B, the operation unit 14 is allowed to rotate in the lifting / lowering cord rewinding direction by the operation of the operation unit 14. 4 and the slat 3 are lowered by their own weight.

  Then, when the bottom rail 4 and the slat 3 are lowered to the desired height, the operation chain 17 is pulled in the direction of arrow A to bring the slat 3 into the fully closed state. 14 is in a state of preventing the lifting shaft 8 from rotating in the lifting / lowering cord rewinding direction, and the bottom rail 4 and the slat 3 are held at a desired height.

Next, detailed configurations of the support member 6 and the support cap 11 will be described with reference to FIGS.
The tilt drum 9 is formed of a synthetic resin into a cylindrical shape, and is rotatably supported by a cylindrical shaft portion 19 provided on one side of the support member 6. Flange 20a, 20b is formed on both sides of the outer peripheral surface of the tilt drum 9, and the driven gear 10 is integrally formed on the outer side of one flange 20b.

  Further, a rotation restricting piece 21 is formed on the side surface of the driven gear 10 in a range of approximately 90 degrees with respect to the rotation center of the driven gear 10. Then, the rotation restricting piece 21 is engaged with the rotation restricting piece 22 formed on the support cap 11 so that the rotation range of the tilt drum 9 is approximately 180 degrees, that is, the slat 3 is set in the horizontal direction. It can be rotated only within a range of 90 degrees in the fully closed direction and the reverse fully closed direction from the state.

  On the outer peripheral surface of the tilt drum 9, a mounting portion 24 for attaching the two hooks 18 facing each other is formed. The ladder tape 2 is suspended and supported from the tilt drum 9 via a hook 18.

  The support cap 11 is formed on one side surface of a rectangular parallelepiped main body portion 25 with a connecting shaft 26 that can be inserted into the shaft portion 19 of the support member 6, and the main body at the center of the connecting shaft 26. A through-hole 27 that continues to the portion 25 is formed. As shown in FIG. 6, the lifting shaft 8 is inserted through the through hole 27.

  Positions equidistant from the center of the through hole 27 on both sides of the lower portion of the main body 25, that is, positions that are line-symmetric with respect to a perpendicular L including the center of the lifting shaft 8 as shown in FIG. The support holes 28a and 28b are formed in the first support hole 28a, and the shaft portion 29 of the drive gear 13 is rotatably supported by the first support hole 28a.

  A hexagonal hole 30 is formed in the central portion of the shaft portion 29, and the tilt shaft 12 is inserted into the hexagonal hole 30 so as not to be relatively rotatable. When the tilt shaft 12 is rotated, the tilt drum 9 is rotated via the drive gear 13 and the driven gear 10, and the slat 3 is rotated via the ladder tape 2.

  On the lower side of the main body portion 25, a ridge 32 that can be fitted into a positioning groove 31 provided on one lower side of the support member 6 is formed. In a state where the ridge 32 is fitted into the positioning groove 31, The main body 25 is held by the support member 6.

  Further, on both sides of the upper side of the main body 25, locking projections 33a and 33b are respectively formed at positions equidistant from the center of the through hole 27, that is, at positions symmetrical with respect to the perpendicular L. Yes. As shown in FIG. 10, when the protrusion 32 is fitted in the positioning groove 31, either one of the locking protrusions 33 a and 33 b is engaged with the rib 34 on the upper edge of the head box 1. It has become. Therefore, the support cap 11 is fixed to the head box 1 so as not to move by the protrusion 32 fitted in the positioning groove 31 and the locking protrusion 33a or 33b engaged with the rib 34.

  Next, the configuration of the operation unit 14 will be described with reference to FIGS. As shown in FIGS. 4 and 5, the operation unit 14 has a pulley case 36 attached to one side of the clutch case 35, and the pulley 16 is rotatably supported in the pulley case 36. The operation chain 17 is hung on the pulley 16, and the pulley 16 is rotated by the operation of the operation chain 17.

  As shown in FIG. 7, a spur gear 37 is integrally provided on the pulley 16, and the drive gear 37 is rotated in an inner case 38 supported in the clutch case 35 and the pulley case 36. .

  A transmission shaft (second output shaft) 39 is rotatably supported by the inner case 38, and first and second transmission gears 40 and 41 of a spur gear are integrally formed at the base end portion of the transmission shaft 39. Is formed. As shown in FIGS. 6 and 9, the first transmission gear 40 meshes with the drive gear 37.

The number of teeth of the first transmission gear 40 is greater than the number of teeth of the drive gear 37. Accordingly, the rotational speed of the pulley 16 is reduced and transmitted to the transmission shaft 39.
As shown in FIG. 6, the transmission shaft 39 is positioned obliquely below the pulley 16 and is positioned on the extension of the tilt shaft 12. A hexagonal hole 42 is formed in the center of the distal end side of the transmission shaft 39 to constitute the second output shaft, and the hexagonal hole 42 is connected to the input shaft of the tilt unit 15.

The second transmission gear 41 is formed adjacent to the first transmission gear 40 and has a smaller number of teeth than the first transmission gear 40.
A spur elevating gear 43 that meshes with the second transmission gear 41 is rotatably supported in the inner case 38. As shown in FIG. 6, the elevating gear 43 is rotatably supported at a position obliquely above the transmission shaft 39, and as shown in FIG. 8, the fixed shaft 45 that supports the first clutch device 44 is used as the center of rotation. It is rotated. Further, the number of teeth is greater than the number of teeth of the second transmission gear 41, and the rotation of the transmission shaft 39 is decelerated and transmitted to the lifting gear 43.

  The first clutch device 44 transmits the rotation of the elevating gear 43 to the second clutch device 46, and the second clutch device 46 transmits the rotation to the first output shaft 47. The rotation center of the first output shaft 47 is the same as the rotation center of the elevating gear 43 and the same as the rotation center of the elevating shaft 8. The end of the elevating shaft 8 is fitted into a hexagonal hole 48 provided at the tip of the first output shaft 47.

  The first clutch device 44 rotates when the transmission shaft 39 is rotated and the tilt shaft 12 is rotated via the tilt unit 15, that is, until the slat 3 is fully closed or reverse fully closed. It has a function of not rotating the elevating shaft 8 until it is moved.

  In addition, the first and second clutch devices 44 and 46, when the elevating gear 43 is rotated in the pulling direction of the slat 3 after the slat 3 is rotated to the fully closed state, 43.

  The second clutch device 46 also includes the slat 3 and the bottom rail 4 even when the operating chain 17 is released when the elevating gear 43 is rotated in the slat pulling direction after the slat 3 is rotated to the fully closed state. Rotation of the lifting shaft 8 due to the weight of.

  Further, the second clutch device 46 is configured such that when the elevating gear 43 is rotated in the slat lowering direction after the slat 3 is rotated in the reverse fully closed state, the elevating shaft 8 is moved by the weight of the slat 3 and the bottom rail 4. Allow rotation.

In the horizontal blind slat drive device configured as described above, the following operational effects can be obtained.
(1) Since the tilt shaft 12 is disposed in the lower corner portion of the head box 1 while the lift shaft 8 and the tilt shaft 12 are provided in the head box 1, the size of the head box 1 can be suppressed.
(2) Since the tilt drum 9 that rotates coaxially with the take-up shaft 7 is rotated by the drive gear 13 attached to the tilt shaft 12, an increase in the size of the head box 1 can be suppressed.
(3) The rotation of the pulley 16 is transmitted to the transmission shaft 39 by a spur gear, and is transmitted from the transmission shaft 39 to the lifting shaft 8 via the spur gear. And since the rotation center of the pulley 16, the rotation center of the transmission shaft 39, and the rotation center of the elevating shaft 8 are not arranged linearly, the case of the operation unit 14 that accommodates them can be miniaturized.
(4) Since the rotation of the pulley 16 is decelerated by the spur gear and transmitted to the transmission shaft 39, and the rotation of the transmission shaft 39 is decelerated by the spur gear and transmitted to the elevating shaft 8, the rotation of the pulley 16 is sufficiently decelerated. In addition, the rotational torque can be transmitted to the lifting shaft 8 more efficiently than the planetary gear. Therefore, the case can be reduced in size as compared with the operation unit provided with the planetary gear as a reduction gear while reducing the operation force during the slat pulling operation.

You may implement the said embodiment in the following aspects.
The tilt shaft 12 may be disposed at the upper corner of the head box 1.
The driving gear 13 and the driven gear 10 may be connected by a timing belt.

  DESCRIPTION OF SYMBOLS 1 ... Head box, 3 ... Slat, 5 ... Lifting cord, 7 ... Winding shaft, 8 ... Lifting shaft, 9 ... Tilt drum, 12 ... Tilt shaft, 13 ... Drive gear, 16 ... Pulley, 17 ... Operation code (operation Chain), 37... Gear device (drive gear), 40, 41... Gear device (transmission gear), 43.

Claims (6)

A lift shaft and a tilt shaft are supported in the head box so as to be rotatable in parallel. The winding shaft of the lift cord is rotated by the lift shaft so that the slat can be lifted and the tilt drum is rotated by the tilt shaft. In the horizontal blind that adjusts the angle,
The tilt shaft is disposed in a diagonal direction of the head box with respect to the lift shaft, and a gear device that rotationally drives the tilt shaft and the lift shaft based on the operation of a single operation cord is provided at one end of the head box. A horizontal blind slat drive device characterized by that. The gear device is
A spur gear that decelerates the rotation of the pulley and transmits it to the transmission shaft;
2. The slat drive device for a horizontal blind according to claim 1, further comprising a spur gear that decelerates the rotation of the transmission shaft and transmits it to the lifting shaft.   3. The horizontal blind slat drive device according to claim 2, wherein the tilt shaft is connected to the transmission shaft.   4. The horizontal blind slat drive device according to claim 2, wherein the rotation center of the pulley, the rotation center of the transmission shaft, and the rotation center of the elevating shaft are not arranged linearly.   The horizontal blind slat drive device according to any one of claims 1 to 4, wherein the tilt shaft is provided at a lower corner of the head box.   The winding shaft is rotatably supported by a support member, the tilt drum is rotatably supported by the support member coaxially with the winding shaft, and the tilt drum is rotated by a drive gear attached to the tilt shaft. The horizontal blind slat drive device according to any one of claims 1 to 5, wherein the drive device is driven.

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