JP2024084027A - Screen device mounting structure - Google Patents

Abstract

[Problem] To provide a mounting structure for a roll screen device that can more easily mount the roll screen device to an opening in a building. [Solution] A pair of brackets 73, 73 attached to the inner surface of both side frames 72, 72 support both ends of a winding box 4, thereby mounting the roll screen device 1 in the opening in a building. Each of the pair of brackets has a fixed wall, a lower support wall 76, and a rear support wall 77, and locking mechanisms 76a, 80 are provided between the lower support wall 76 of the brackets and both ends of the winding box, respectively, for detachably locking both ends of the winding box to the brackets, and both ends of the winding box are sandwiched between the lower support wall 76 and the upper horizontal frame 71 in the vertical direction, and are locked to the brackets by the locking mechanism in a state of abutting against the rear support wall 77 in the depth direction. [Selected Figure] Fig. 19

Description

The present invention relates to a mounting structure for a screen device to be attached to an opening in a building.

Screen devices that are attached to building openings for the purpose of shading, privacy, or insect control are already known, as disclosed in Patent Document 1, for example. Patent Document 1 discloses an example of a roll screen device attached to a building opening, in which a bracket for fixing the roll screen device to the building opening is fixed to the upper frame of the building opening, and a case 3 incorporating a winding shaft for winding up the screen is engaged with the bracket. In the device described in Patent Document 1, the roll screen device is attached by engaging the engaging protrusions 21, 22, and 26 of the case 3 with the engaging protrusions of the bracket. However, since the bracket is fixed to the upper frame of the building opening, when the screen device is attached to the building opening, the view of the engaging protrusions of the bracket is blocked by the case 3, so that the task of engaging the engaging protrusions 21, 22, and 26 with the engaging protrusions is not necessarily easy. Therefore, there has been a demand for the development of an attachment structure that allows the roll screen device to be attached to the building opening more easily.

JP 2003-20883 A

The technical objective of the present invention is to provide a mounting structure for a roller blind device that allows for easier installation of the roller blind device to an opening in a building.

In order to solve the above problems, according to the present invention, there is provided a mounting structure for a roller blind device to a building opening, the building opening being formed by an upper horizontal frame that defines the upper end of the building opening, and a pair of side frames that hang down from both ends of the upper horizontal frame and have inner faces facing each other in the width direction, the roller blind device having a winding box with an internal winding shaft that winds up the screen by rotating around an axis, and the roller blind device is mounted within the building opening by supporting both ends of the winding box in the axial direction with a pair of brackets attached to the inner faces of the side frames in the building opening, and the pair of brackets are fixed to a fixed wall fixed to the inner face of the side frames and a pair of brackets extending from the fixed wall inwardly of the building opening. The mounting structure for a roller blind device has a lower support wall that stands upright on the fixed wall and extends in the depth direction, and a rear support wall that stands upright from the fixed wall toward the inside of the building opening and extends in the vertical direction, and between the lower support walls of the brackets and the undersides of both ends of the winding box, a locking mechanism is provided that detachably locks both ends of the winding box to the brackets in the depth direction, and both ends of the winding box are supported from below by the lower support walls of the pair of brackets in the vertical direction and are sandwiched between the lower support walls and the upper horizontal frame of the building opening, and are locked to the brackets by the locking mechanism in the depth direction while abutting against the rear support walls of the pair of brackets.

In the present invention, preferably, the locking mechanism is composed of locking holes provided on both ends of the winding box and on one side of the rear support walls of the pair of brackets, and locking claws provided on both ends of the winding box and on the other side of the rear support walls of the pair of brackets, and the locking claws are configured to elastically lock into the locking holes.

The winding box may also be provided with a fixing member that is fixed to the front end surface of the upper horizontal frame in the depth direction.

The present invention makes it easier to lock the winding box to the bracket, providing a mounting structure for a roller blind device that allows the roller blind device to be more easily attached to an opening in a building.

1 is a front view showing an embodiment of a roller screen device according to the present invention. FIG. 2 is a front view showing the roller blind device with a part cut away; FIG. 2 is a horizontal cross-sectional view of the winding box. FIG. 1A is a partially enlarged cross-sectional view showing one end of the winding box, and FIG. 1B is a cross-sectional view taken along line II in FIG. FIG. 4 is an exploded perspective view showing a coupled state of an end cap and a pulley box in the winding box. FIG. 2 is an exploded perspective view showing an operating mechanism and a winding force adjusting mechanism of the roller screen device. FIG. 4 is a side cross-sectional view of the roller screen device, showing a schematic diagram of an operating mechanism in a pulley box. FIG. 2 is a side cross-sectional view of the above-mentioned roller screen device, and shows a schematic diagram of a state in which the screen is fully wound around the winding shaft in the winding box. FIG. 2 is an exploded perspective view of the winding force adjustment mechanism. 13 is a perspective view showing a state in which the winding force adjustment mechanism is housed in the gear cover. FIG. 4 is an enlarged view of a main portion showing the relative positions of a rotor, a brake spring, and a biasing force adjusting piece in the winding force adjusting mechanism. FIG. FIG. 2 is a perspective view showing the outer surface side of the pulley box. 10 is a side view showing a state in which a gear cover is attached to the outer surface side of the pulley box. FIG. A front view showing the bracket attached to the side frame of a building opening. FIG. 16 is an enlarged cross-sectional side view of a main portion of FIG. 15 . 16 is an enlarged horizontal cross-sectional view of a main part of FIG. 15 as seen from the bottom side. FIG. 11 is an enlarged cross-sectional side view showing a schematic diagram of a state in which the winding box is being attached to the bracket. 4 is an enlarged cross-sectional side view showing a schematic diagram of a state in which a winding box is attached to a bracket. FIG. FIG. 20 is an enlarged view of a main portion of FIG. 19 . FIG. 11 is a side cross-sectional view showing a first modified example of the operating mechanism in the roller blind device, and is a schematic view of the operating mechanism in the pulley box. FIG. 13 is an exploded perspective view of the operation mechanism in the first modified example. FIG. 13 is a side cross-sectional view showing a second modified example of the operating mechanism in the roller screen device, and is a schematic view of the operating mechanism in the pulley box. FIG. 13 is a side sectional view showing a third modified example of the roller screen device, and is a schematic view showing an operating mechanism in the pulley box. FIG. 13 is a perspective view showing a fourth modified example of the above-mentioned roller blind device, illustrating a state in which the operating cord, which has been pulled out from the storage space of the vertical frame member to the indoor side, is stored again in the storage space. FIG. 26 is a cross-sectional view of a main part of FIG. 25 . 13 is a plan view showing the state in which the guide member is attached to the opening of the vertical frame member. FIG. 13 is an exploded perspective view showing a cord retaining member that accommodates the operating cord pulled out into the interior of the vehicle into the accommodating space. FIG.

The following describes an embodiment of a roller blind device according to the present invention with reference to Figures 1 to 20. The roller blind device 1 of this embodiment is a vertical-opening type screen device, and includes a winding box 4 as a horizontal frame member for mounting to the upper end of a building opening, a frame body 100 having vertical frame members 5, 5 hanging downward from the left and right longitudinal ends of the winding box 4, the winding shaft 3 supported within the winding box 4 so as to be rotatable about a horizontal axis L1, and a screen 2 having one end fixed to the winding shaft 3 and the other end led out from the winding box 4 to the outside, which can be wound up and unwound from the winding shaft 3 by the rotation of the winding shaft 3.

Engagements such as slide fasteners are attached to the left and right side edges of the screen 2, and the engagement elements are slidably engaged in slits 7a of guide rails 7 held by the vertical frame members 5, 5, so that when opening and closing, the screen 2 can move up and down along the vertical frame members 5, 5. As described above, the one end (upper end) of the screen 2 is attached to the winding shaft 3, while the other end (lower end) of the screen 2 is attached to a movable crosspiece 8 that functions as a weight and as an opening and closing operation.

As shown in FIG. 4, the vertical frame member 5 has a first frame portion 5a that holds the guide rail 7 and a hollow second frame portion 5b that has a storage space S inside, and the first frame portion 5a and the second frame portion 5b are joined to form an L shape. The second frame portion 5b has an opening portion 5c that extends in the vertical direction and opens to the indoor side in the depth direction, and the indoor space and the storage space S are connected through the opening portion 5c.

As shown in FIG. 5, the winding shaft 3 has a winding shaft body 3a formed in a hollow cylindrical shape to which one end of the screen 2 is fixed, and a winding cap 3b fixedly attached to both ends of the winding shaft body 3a at least around the axis L1. The winding cap 3b has a circular tubular portion 3c fixedly fitted from the tip to the winding shaft body 3a, a circular flange portion 3d connected to the base end of the tubular portion 3c and extending outward in the axis L1 direction, with the tip side protruding radially outward, and an elongated rectangular tubular portion 3e connected to the base end of the circular tubular portion 3c radially inward from the flange portion 3d and extending outward in the axis L1 direction. The rectangular tubular portion 3e has a rectangular cross-sectional outer shape and a support hole 3f penetrating in the axis L direction at its center. A winding mechanism is connected to both ends of the winding shaft 3, which accumulates a rotational biasing force that rotates the winding shaft 3 in the direction in which the screen 2 is wound up by the rotation of the winding shaft 3 about the axis L1 accompanying the unwinding of the screen 2.

The winding mechanism includes a winding spring 9 made of a coil spring arranged on the axis L1, a spring receiver 6 fixedly fitted around the axis L1 to the winding shaft body 3a in the center of the axis L1 direction of the winding shaft body 3a, and a spring shaft 10 whose tip end is rotatably inserted into the support hole 3f of the winding cap 3b at the end of the axis L1 direction of the winding shaft body 3a from inside the winding shaft body 3a toward the outside. In the winding shaft body 3a, one end of the spring material of the winding spring 9 is fixed to the spring receiver 6, and the other end of the spring material of the winding spring 9 is fixed to the base end side of the spring shaft 10. Furthermore, the tip of the spring shaft 10 led out to the outside of the winding shaft body 3a through the support hole 3f of the winding cap 3b is supported by a rotor 52 in a winding force adjustment mechanism described later.

The winding box 4 has a hollow box body 11 that has a rectangular cross-sectional shape and extends horizontally, and end caps 12 provided at both ends of the box body 11. As shown in Figures 5 and 6, fixing pieces 12a for fixing to the box body 11 are provided at the four corners of the end cap 12, and the box body 11 and the end cap 12 are fixed by inserting the fixing pieces 12a into the ends of the box body 11 and screwing them in place.

As shown in FIG. 9, a screen outlet 13 extending horizontally is provided on the underside of the box body 11 along axis L1, and when the winding shaft 3 housed in the winding box 4 rotates about axis L1, the screen 2 wound around the winding shaft 3 is unwound from the screen outlet 13 or wound around the winding shaft 3. At this time, the screen outlet 13 is disposed at the indoor end of the winding box 4, and accordingly, the guide rail 7 held by the vertical frame member 5 is disposed at the indoor end of the underside of the winding box 4.

As shown in Figs. 2, 3 and 9, a turning member 24 extending along the longitudinal direction of the winding box 4 is provided inside the box body 11 of the winding box 4. The turning member 24 is composed of a turning roller 24a around which the screen 2 unwound from the winding shaft 3 is wound to guide the screen 2 downward, and a support base 24b that supports the turning roller 24a from below to prevent the turning roller 24a from bending, and the turning roller 24a is located directly above the screen outlet 13. By providing the turning member 24, the screen 2 turned downward by the turning roller 24a is prevented from sliding against the opening edge of the screen outlet 13, and as shown in Fig. 9, the guide rail 7 is extended to the inside of the winding box 3 through the screen outlet 13, making the lead-in and lead-out of the screen 2 from the winding box 4 more stable.

At both ends of the winding box 4 (outside the axis L1 direction of the end cap 12), an operating mechanism for introducing and withdrawing the screen 2 into and from the winding box 4 is provided. As shown in Figs. 7 and 8, the operating mechanism has a pulley 14 as a rotation transmission body connected to the winding shaft 3, and an endless loop-shaped flexible operating cord 15 wound around the pulley 14, and these pulleys 14 and operating cord 15 are held in a pulley box 16 described later. The pulley box 16 is attached to the end cap 12 by tightening together with an end plate 17 that closes its inner side. The square cylindrical part 3e of the winding cap 3b and the spring shaft 10 inserted into the support hole 3f are extended into the pulley box 16 through the cylindrical part 12b formed in the end cap 12 and the through hole 17a that penetrates the plate thickness direction of the end plate 17. At this time, the square cylindrical part 3e. It is inserted into the cylindrical portion 12b so that it can rotate freely around the axis L1.

The pulley 14 has a rectangular hole 14a formed in the center with a rectangular cross section, and the tip of the square cylindrical portion 3e is fitted into the rectangular hole 14a, so that the winding shaft 3 and the pulley 14 are integrally connected around the axis L1. That is, when the pulley 14 rotates, the winding cap 3b, the winding shaft body 3a, and the spring receiver 6 simultaneously rotate around the axis L1 with respect to the spring shaft 10, which is fixed to the winding box 4. The pulley 14 is integrally formed with a pair of flange portions 14b, 14c arranged at both ends in the direction of the axis L1, and an engagement gear 14d sandwiched between the flange portions 14b, 14c and formed with a smaller diameter than the flange portions 14b, 14c. The operating cord 15 is then wound around the engagement gear 14d.

5 and 7, the operating cord 15 is made of an endless ball chain in which a number of balls 15a formed in a substantially spherical shape (in this embodiment, the long side cross section is elliptical and the short side cross section is circular) are connected to each other at equal intervals by connecting strips 15b, and is configured to have flexibility as a whole. When the operating cord 15 is suspended from the winding box 4, if one of the two string-like parts formed between the upper and lower folds is pulled against the elastic spring force (i.e., the rotational biasing force) around the axis L1 of the winding spring 9, the engagement between the engagement gear 14d and the balls 15a of the operating cord 15 rotates the pulley 14 to one side in the circumferential direction, and together with the weight of the movable crosspiece 8, the screen 2 is unwound from the winding shaft 3. On the other hand, when the other of the two string-like members of the operating cord 15 is pulled, the pulley 14 rotates in the other circumferential direction in the same manner, and in combination with the rotational biasing force accumulated in the winding spring 9, the screen 2 is wound up on the winding shaft 3. The roll screen device 1 can also be equipped with a known locking means for holding the screen 2 in a desired stretched state.

As shown in Figures 5, 7 and 8, the pulley box 16 has a base 18 formed in a plate shape with a rectangular appearance in a plan view, a storage section 19 for the pulley 14 formed by an outer peripheral wall 22 rising from the base 18 toward the winding shaft 3 side so as to surround the axis L1 on the inner side of the pulley box 16, a pair of outlets 20 opening on the front surface facing the indoor side of the pulley box 16, and a pair of connecting paths 21 connecting the storage section 19 and the pair of outlets 20. The operating cord 15 looped around the engagement gear 14d of the pulley 14 in the storage section 19 is led out from the pair of outlets 20 to the indoor side through the pair of connecting paths 21.

The storage section 19 is for rotatably storing the pulley 14 as described above, and has an outer peripheral wall 22 that is erected in an annular shape about the axis L1, and an annular inner peripheral wall 23 that is erected concentrically with the outer peripheral wall 22. The height of the inner peripheral wall 23 from the base 18 is lower than the height of the outer peripheral wall 22 from the base 18. The shaft portion on one side (the winding shaft 3 side) of the pulley 14 is rotatably supported by the through hole 17a of the end plate 17, and the shaft portion on the other side (the pulley box 16 side) is rotatably supported by the inner peripheral wall 23.

According to the roller blind device 1, the guide rail 7 held by the vertical frame member 5 is positioned at the end on the indoor side in the depth direction, and an outlet 20 for leading the operating cord 15 to the indoor side is opened on the front surface of the winding box 4 facing the indoor side. Therefore, even if a fitting such as a window or door has a handle protruding into the indoor side, the winding box 4 can be attached close to the fitting, without impairing the operability of the operating cord 15.

The winding force adjusting mechanism will now be described.
10 to 12, the winding force adjustment mechanism is disposed on the outer surface side of the pulley box 16, and includes a brake fitting portion 50 fixedly attached to the winding box 4, a brake spring 51 formed of a coil spring made of a spring material having a first end 51a and a second end 51b on the opposite side thereof, and fitted to the brake fitting portion 50 with a fitting force that prevents rotation in the circumferential direction, and a rotor 52 that engages with the first end 51a of the spring material forming the brake spring 51 or the second end 51b of the spring material in the circumferential direction of the brake spring 51 in a direction to reduce the diameter of the brake spring 51. The brake fitting portion 50, the brake spring 51, the rotor 52, and an outer ring member 56 described later are aligned on the axis L1.

The brake fitting portion 50 is formed in a cylindrical shape, and is provided integrally with a gear cover 60 for covering the winding force adjustment mechanism from the outside on the outer surface side of the pulley box 16. As shown in Fig. 13, a cover mounting groove 16a for positioning and fixing the gear cover 60 is provided on the outer surface side of the base 18 of the pulley box 16, and the gear cover 60 is fixed by screws while being engaged with the cover mounting groove 16a.
In an initial state where the brake spring 51 is not elastically deformed, the inner diameter of the brake spring 51 is smaller than the outer diameter of the brake fitting portion 50. Therefore, the brake spring 51 is fitted onto the brake fitting portion with its wound diameter expanded, and is fixed to the brake fitting portion 50 by an elastic restoring force that tries to reduce the diameter to its original diameter.

The rotor 52 has a circular small diameter protrusion 52a arranged at one end in the direction of the axis L1 and a large diameter protrusion 52b arranged at the other end and having a larger diameter than the small diameter protrusion 52a. As shown in FIG. 5, the small diameter protrusion 52a is inserted into the brake fitting portion 50 and supported so as to be freely rotatable, and the large diameter protrusion 52b is inserted into a rotor opening 16b opened in the cover mounting groove 16a of the pulley box 16 and supported so as to be freely rotatable. In addition, the large diameter protrusion 52b has a groove 52c into which the shaft end 10a at the tip of the spring shaft 10 is fixedly fitted around the axis L1. In other words, the rotor 52 rotates together with the spring shaft 10.

The rotor 52 has a convex portion 52d extending in a circumferential direction within a predetermined angle range on the outer periphery of the large diameter convex portion 52b in the middle portion in the axis L1 direction, and a notch portion 53 is formed between both ends of the convex portion 52d in the circumferential direction. A first surface 53a and a second surface 53b facing each other are formed at both circumferential ends of the notch portion 53, i.e., at both circumferential ends of the convex portion 52d. The first end 51a and the second end 51b of the brake spring 51 are arranged between the first surface 53a and the second surface 53b. In this embodiment, the rotor 52 is constantly engaged with the first end 51a of the brake spring 51 by the rotational biasing force of the winding spring 9 as shown in FIG. 12, and biases the brake spring 51 in the diameter contracting direction, i.e., in the direction of winding up the brake spring 51.

Furthermore, the winding force adjustment mechanism has a biasing force adjustment piece 54 that is rotatable in the circumferential direction relative to the brake spring 51 and the rotor 52 and can be selectively engaged with the first end 51a or the second end 51b in the circumferential direction of the brake spring 51, and an operating part 55 for rotating the biasing force adjustment piece 54. The biasing force adjustment piece 54 is disposed on the outside of the rotor 52 and is provided on the inner surface of the annular outer ring member 56 that surrounds the rotor 52 and is connected to the operating part 55. The biasing force adjustment piece 54 is disposed between the first end 51a and the second end 51b of the brake spring 51 in the notch 53. Then, by rotating the outer ring member 56 accompanying the operation of the operating part 55, it can be selectively engaged with the first end 51a or the second end 51b to bias the brake spring 51 in the radial expansion direction, i.e., in the direction to unwind the brake spring 51.

By such an operation, as described later in detail, the fitting force of the brake spring 51 with respect to the brake fitting portion 50 is reduced, and the brake spring 51 is allowed to rotate with respect to the brake fitting portion 50. Then, the brake spring 51 rotates around the axis L1 together with the biasing force adjustment piece 54, and the biasing force adjustment piece 54 presses the first surface 53a of the rotor 52 together with the first end 51a of the brake spring 51 in the direction A in FIG. 12 around the axis L1, or presses the second surface 53b of the rotor 52 together with the second end 51b of the brake spring 51 in the direction B, thereby allowing the rotor 52 and the spring shaft 10 to rotate around the axis L1. As a result, the magnitude of the rotational biasing force in the winding direction of the screen 2 by the winding spring 9 acting on the winding shaft 3 can be appropriately adjusted according to the unwinding length of the screen 2.

The outer ring member 56 has a drive gear 56a on whose outer circumference a plurality of gear teeth are provided at equal angular intervals. In contrast, the operating unit 55 has a plurality of transmission gears 55a, 55b, 55c, and 55d made of spur gears that mesh with the drive gear 56a of the outer ring member 56 to transmit rotational force around the axis L1 to the outer ring member 56. The transmission gears 55a-55d have different rotation axes, and these rotation axes are aligned in a straight line parallel to the axis L1. An even number of the transmission gears 55a-55d are arranged, and in this embodiment, a total of four are arranged. One end of the rotation axis of the transmission gears 55a-55d is rotatably supported by a plurality of circular holes 61 opened in the gear cover 60, and the other end is rotatably supported by a plurality of gear openings 16c opened in the cover mounting groove 16a of the pulley box 16.

The transmission gears 55a-55d also have a concave outer engagement groove 57 on the end face of one end of the rotating shaft (the gear cover 60 side), and the transmission gears 55a-55d can be rotated in unison by engaging the tip of a flathead screwdriver with the outer engagement groove 57. Since this outer engagement groove 57 faces the outside through a circular hole 61 in the gear cover 60, for example, the rotational biasing force of the winding spring 9 can be adjusted by rotating the transmission gears 55a-55d from outside the winding box 4 before attaching the winding box 4 to an opening in a building.

The transmission gears 55a-55d also have an inner engagement groove 58 formed on the end face of the other end of the rotating shaft (pulley box 16 side) that can be engaged with a flathead screwdriver. However, of the transmission gears 55a-55d, except for the transmission gear 55d connected furthest from the outer ring member 56 (referred to as the "outermost transmission gear"), these inner engagement grooves 58 cannot be seen from inside the winding box 4 because the inner surface of the pulley box 16 is blocked by the end cap 12.

The outermost transmission gear 55d has a rotating shaft 59 supported by the pulley box 16 that extends into the box body 11 of the winding box 4 through the opening 17b in the end plate 17 and the opening 12c in the end cap 12, and the inner engagement groove 58 faces the inside of the box body 11. As a result, even after the roller screen device 1 is attached to the building opening, for example, the outermost transmission gear 55d can be rotated from inside the winding box 4 to adjust the rotational biasing force of the winding spring 9. In addition, the outermost transmission gear 55d is arranged radially outward of the axis L1 than the outer diameter of the screen 2 when it is wound most around the winding shaft 3, so that it does not interfere with the screen 2 when it is rotated from inside the winding box 4. In addition, the number of teeth on the transmission gears 55a-55d is smaller than the number of teeth on the drive gear 56a of the outer ring member 56 (i.e., the diameter of the transmission gears 55a-55d is smaller than the diameter of the drive gear 56a of the outer ring member 56), thereby reducing the operating load when rotating the transmission gears 55a-55d.

When adjusting the rotational biasing force of the winding spring 9, the tip of a flat head screwdriver is engaged with the outer engagement groove 57 of one of the transmission gears 55a-55d from the outside of the winding box 4, or the tip of a flat head screwdriver is engaged with the inner engagement groove 58 of the outermost transmission gear 55d from the inside of the winding box 4, and the transmission gears 55a-55d are rotated to transmit the rotational force around the axis L1 to the outer ring member 56.

For example, when the rotational biasing force is to be increased, the operating portion 55 is operated to rotate the outer ring member 56 in one direction around the axis L1 (the direction of the arrow A in FIG. 12), and the biasing force adjustment piece 54 is engaged with the first end 51a of the brake spring 51, and the first end 51a is pressed in a direction that increases the circumferential angle formed with the second end 51b, and in a direction that loosens the winding of the brake spring 51 and expands its diameter. Then, the fitting force of the brake spring 51 with respect to the brake fitting portion 50 is reduced, and the rotation of the brake spring 51 around the axis L1 is permitted. Then, the biasing force adjustment piece 54 is engaged with both the first end 51 of the brake spring 51 and the first surface 53a of the rotor 52. By further rotating the outer ring member 56, the rotor 52 and the spring shaft 10 connected to it rotate together with the outer ring member 56, and as a result, the winding spring 9 is wound up and its rotational biasing force is increased.

After adjusting the winding spring 9 to an appropriate rotational biasing force in this way, when the flathead screwdriver is removed from the outer engagement groove 57 or the inner engagement groove 58, the first surface 53a of the rotor 52 is engaged with the first end 51a of the brake spring 51 by the rotational biasing force in the unwinding direction of the winding spring 9, and the first end 51 is pressed in a direction that reduces the circumferential angle formed with the second end 51b and that tightens the brake spring 51 to reduce its diameter. Then, the fitting force of the brake spring 51 to the brake fitting portion 50 is increased, and the brake spring 51 is fitted to the brake fitting portion 50 with a fitting force that does not allow the brake spring 51 to rotate around the axis L1. As a result, the rotation of the rotor 52 and the spring shaft 10 connected thereto is prevented, and the spring shaft 10 is fixed to the winding box 4, completing the adjustment of the rotational biasing force of the winding spring 9.

On the other hand, when the rotational biasing force is reduced, the operating portion 55 is operated to rotate the outer ring member 56 in the other direction around the axis L1 (the direction of the arrow B in FIG. 12), and the biasing force adjustment piece 54 engages with the second end 51b of the brake spring 51, and the second end 51b is pressed in a direction that increases the circumferential angle with the first end 51a and unwinds the brake spring 51 to expand its diameter. This reduces the engagement force of the brake spring 51 with the brake fitting portion 50, and allows the brake spring 51 to rotate around the axis L1. This causes the biasing force adjustment piece 54 to be engaged with both the second end 51b of the brake spring 51 and the second surface 53b of the rotor 52. By further rotating the outer ring member 56, the rotor 52 and the spring shaft 10 connected to it rotate together with the outer ring member 56, and as a result, the winding of the winding spring 9 is loosened, and the rotational biasing force can be reduced.

In this case as well, when the flathead screwdriver is removed from the outer engagement groove 57 or the inner engagement groove 58, the first surface 53a of the rotor 52 engages with the first end 51a of the brake spring 51 due to the rotational force in the rewinding direction of the winding spring 9, and the brake spring 51 is wound up again, and the brake spring 51 is fitted to the brake fitting portion 50 with a fitting force that does not allow the brake spring 51 to rotate around the axis L1. As a result, the rotation of the rotor 52 and the spring shaft 10 connected thereto is prevented, and the spring shaft 10 is fixed to the winding box 4, completing the adjustment of the rotational force of the winding spring 9.

In addition, the above-mentioned roller screen device 1 allows the rotational biasing force of the winding springs 9, 9 arranged on both the left and right sides to be adjusted individually by the winding force adjustment mechanism arranged on both the left and right sides. However, if the rotational biasing forces of the left and right winding springs 9, 9 are different, there is a risk that the winding shaft 3 will become twisted and the screen 2 will not be wound evenly around the winding shaft 3. Therefore, it is desirable to adjust the rotational biasing forces of the left and right winding springs 9, 9 to be equal.

Next, a mounting structure of the winding box 4 to the building opening in this embodiment will be described.
15 to 17, the building opening is formed by an upper horizontal frame 71 that defines its upper end, and a pair of side frames 72, 72 that hang down from both ends of the upper horizontal frame 71 and have inner faces that face each other in the width direction. A pair of brackets 73, 73 are attached to the inner faces of the upper ends of the side frames 72, 72 of the building opening, and both ends of the winding box 4 in the direction of the axis L1 are supported by these brackets 73, 73.

The pair of brackets 73, 73 each have a fixed wall 74 fixed to the inner surface of the side frame 72, a lower support wall 76 erected from the fixed wall 74 toward the inside of the building opening and extending in the depth direction, and a rear support wall 77 erected from the fixed wall 74 toward the inside of the building opening and extending in the vertical direction. The fixed wall 74 is a rectangular plate in a plan view that is long in one direction, and is fixed to the side frame 72 with screws 78 in a position where the longitudinal direction is aligned in the vertical direction. The upper end of this fixed wall 74 abuts against the inner surface of the upper horizontal frame 71.

The lower support wall 76 is provided on the lower edge of the fixed wall 74 and extends over the entire width (depth) of the fixed wall 74. The length of the lower support wall 76 in the depth direction is smaller than the length of the pulley box 16 in the depth direction. On the other hand, the rear support wall 77 is provided on the side edge of the fixed wall 74 on the exterior side in the depth direction and extends over the entire length (vertical direction) of the fixed wall 74. The vertical length of the rear support wall 77 is approximately the same as or slightly larger than the height of the pulley box 16. Furthermore, the heights of the lower support wall 76 and the rear support wall 77 in the erection direction are equal. In addition, a locking hole 76a is provided on the interior side of the lower support wall 76 in the depth direction, and the locking hole 76a and a locking claw 80 provided on the winding box 4 side that locks into the locking hole 76a constitute a locking mechanism that restricts movement of the winding box 4 in the depth direction.

The pair of brackets 73, 73 support the pulley box 16 arranged at both ends of the winding box 4. As shown in Figures 13 and 20, the lower surface of the pulley box 16 is provided with the locking claw 80 that is locked to the locking hole 76a, and the locking claw 80 has a plate-shaped portion 81 whose base end is supported by the lower surface of the pulley box 16 and is elastically deformable in the vertical direction, and a mountain-shaped (triangular in cross section) locking portion 82 that is provided at the tip of the plate-shaped portion 81 and protrudes downward. The plate-shaped portion 81 is formed by a cantilever leaf spring whose base end is integrally connected and supported by the lower surface of the pulley box 16 and extends along the lower surface toward the end of the pulley box 16 on the indoor side. As shown in FIG. 20, the locking portion 82 has an inclined portion 82a that is formed with a downward gradient from the outside of the room to the inside of the room in the depth direction, and a hook portion 82b that extends upward approximately vertically from the lower end of the inclined portion 82a and locks onto the opening edge of the locking hole 76a.

As shown in Figures 1, 18 and 19, an L-shaped metal fitting 83 is provided on the upper surface of the box body 11 of the winding box 4. One end of the metal fitting 83 is fixed to the box body 11, and the other end of the metal fitting 83 stands upward and has a round hole 83a for inserting a screw. With the winding box 4 supported by a pair of brackets 73, 73, it is screwed to the front end of the upper horizontal frame 71 through the round hole 83a.

When attaching the winding box 4 of the roller blind device 1 to the pair of brackets 73, 73, the lower end of the pulley box 16 in the winding box 4 is supported on the lower support wall 76 of the brackets 73, 73, and the winding box 4 is pushed toward the outside of the room. Before the rear end (outside end) of the pulley box 16 abuts against the rear support wall 77 of the pair of brackets 73, 73, the inclined surface 82a of the locking claw 82 rides up on the front edge of the lower support wall 76, the plate-shaped portion 81 elastically deforms upward, and the lower end of the locking portion 82 (the intersection line between the inclined portion 82a and the hook portion 82b) rises to the same height as the lower surface of the pulley box 16. Furthermore, when the winding box 4 is pushed in and the rear end of the pulley box 16 abuts against the rear support wall 77 and is supported, the hook portion 82b of the locking claw 82 reaches the opening edge of the locking hole 76a, the plate-shaped portion 81 elastically returns, and the locking claw 80 is locked in the locking hole 76a, completing the installation of the winding box 4.

When the installation is complete, both ends of the winding box 4 are clamped between the lower support walls 76 of the pair of brackets 73, 73 and the upper horizontal frame 71 in the vertical direction, restricting movement in the vertical direction, and in the depth direction, movement in the depth direction is restricted by the rear support wall 77 and the locking mechanism.
On the other hand, when removing the winding box 4 from the pair of brackets 73, 73, the locking claws 80 locked in the locking holes 76a are pushed upward from the underside of the lower support wall 76 using a tool such as a screwdriver to release the locked state, and the winding box 4 can be pulled out to the inside of the room. In this way, the winding box 4 is configured to be easily attached to or removed from the building opening.

21 to 28 show various modified examples of the operating mechanism in the roller blind device. In the following description of the modified examples, the description of the same as that of the above embodiment will be omitted.
In the roll screen device 1A of the first modification shown in Fig. 21, the pulley box 16 has a first storage section 26 in which a first gear pulley 25 rotating around an axis L1 is stored, and a second storage section 28 formed on the room side (front side) in the depth direction from the first storage section 26 and in which a second gear pulley 27 meshing with the first gear pulley 25 is stored. In addition, a rectangular hole 14a is opened in the center of the first gear pulley 25 as in the above embodiment (see Fig. 22), and the tip of the square tube upper part 3e is fitted into this rectangular hole 14a. In this embodiment, the second gear pulley 27 is the same as the first gear pulley 25, but the rectangular hole of the second gear pulley is not used.

The first storage section 26 has an outer peripheral wall 29 that is erected in an annular shape around the axis L1, and an inner peripheral wall 30 that is erected in an annular shape inside the outer peripheral wall 29 and has the same center as the outer peripheral wall 29. The second storage section 28 has an outer peripheral wall 31 that is erected in an annular shape around the rotation axis L2 of the second gear pulley 27, and an inner peripheral wall 32 that is erected in an annular shape inside the outer peripheral wall 31 and has the same center as the outer peripheral wall 31. The first storage section 26 and the second storage section 28 are connected to each other at the portion where the outer peripheral walls 29, 31 of the first storage section 26 and the second storage section 28 overlap, so that the first gear pulley 25 and the second gear pulley 27 are meshed with each other.

The first and second gear pulleys 25, 27 are integrally formed by gear flanges 25a, 27a (gear parts) arranged on the winding shaft 3 side in the axis L1, L2 direction, circular flanges 25b, 27b arranged on the pulley box 16 side opposite the winding shaft 3, and engagement gears 25c, 27c (pulley parts) sandwiched between the gear flanges 25a, 27a and the circular flanges 25b, 27b and formed with a smaller diameter than the flanges 25a, 25b, 27a, 27b. The gear flanges 25a, 27a of the first and second gear pulleys 25, 27 have a plurality of gear teeth on their outer circumferences at equal angular intervals, and are meshed with each other as described above. The operating cord 15 is wound around the engagement gear 27c of the second gear pulley 27. However, in this embodiment, the engagement gear 25c of the first gear pulley 25 is not used.

In this modified example, as in the above embodiment, the shaft portion on one side (the winding shaft 3 side) of the first gear pulley 25 is rotatably supported by the through hole 17a penetrating the end plate 17 attached to the end cap 12, and the shaft portion on the other side (the pulley box 16 side) is rotatably supported by the inner peripheral wall 30. As in the first gear pulley 25, the shaft portion on one side of the second gear pulley 27 is rotatably supported by the through hole 17c penetrating the end plate 17 and arranged adjacent to the through hole 17a, and the shaft portion on the other side is rotatably supported by the inner peripheral wall 32. In this modified example, the axis L2 of the second gear pulley 27 is horizontally disposed on the indoor side in the depth direction with respect to the axis L1 of the first gear pulley 25.

Furthermore, the pulley box 16 in this modified example also has a pair of outlets 20 that open on the front surface of the pulley box 16 facing the indoor side, and a pair of connecting paths 21 that connect the second storage section 28 to the pair of outlets 20. The operating cord 15 that is wound around the engagement gear 27c of the second gear pulley 27 in the second storage section 28 is led out from the pair of outlets 20 to the indoor side through the pair of connecting paths 21. In this way, when the operating cord 15 is operated, the operating force is transmitted from the second gear pulley 27 to the first gear pulley 25, causing the winding shaft 3 to rotate and the screen 2 to be led in and out of the winding box 4. In this modified example, the second gear pulley 27 around which the operating cord 15 is wound is positioned closer to the indoor side, so that the operating cord 15 can be operated more smoothly.

The operating cord may be led out not only to the indoor side but also to the outdoor side. Figure 23 shows a roller blind unit 1B equipped with the second modified operating mechanism. In this modified example, as in the first modified example, the second gear pulley 27 is accommodated in the second storage section 28, and the first storage section 26 also accommodates a first gear pulley 25 that is the same as the second gear pulley. In this modified example, the outdoor operating cord 15A is wound around the engaging gear 25c of the first gear pulley 25, and the indoor operating cord 15 is wound around the engaging gear 27c of the second gear pulley 27, as in the first modified example.

The pulley box 16 in this modification, like the first modification, has a pair of outlets 20 that open on the front surface of the pulley box 16 facing the indoor side, and a pair of connecting paths 21 that connect the second storage section 28 to the pair of outlets 20. The indoor side operating cord 15 that is looped around the engagement gear 27c of the second gear pulley 27 in the second storage section 28 is led out from the pair of outlets 20 to the indoor side through the pair of connecting paths 21. In this way, when the operating cord 15 is operated on the indoor side, the operating force is transmitted from the second gear pulley 27 to the first gear pulley 25, causing the winding shaft 3 to rotate and leading the screen 2 in and out of the winding box 4.

Furthermore, the pulley box 16 in this modified example has a pair of outer outlets 35 that open at a position on the outside of the vertical frame member 5 on the underside of the pulley box 16, and a pair of connecting paths 36 that connect the first storage section 26 to the pair of outer outlets 35. The outdoor operation cord 15A that is looped around the engagement gear 25c of the first gear pulley 25 is led out from the pair of outer outlets 35 to the outside of the room through the pair of connecting paths 36. In this way, when the operation cord 15A led out to the outside of the room is operated on the outside of the room, the winding shaft 3 rotates with the rotation of the first gear pulley 25, and the screen 2 is led in and out of the winding box 4. According to this second modified example, since the operation cords 15, 15A are led out to both the inside and outside of the room, the screen 2 can be led in and out of the winding box 4 from either the inside or outside of the room.

Figure 24 shows a roller blind device 1C of the third modified example, which is the same as the second modified example in that the first and second gear pulleys 25, 27 are housed in the first and second storage sections 26, 28. However, this third modified example differs from the second modified example in that the indoor operating cord 15, which is looped around the engaging gear 27c of the second gear pulley 27 in the second storage section 28, is led out from the bottom surface of the winding box 4 to the indoor side.

The pulley box 16 in this modified example also has a pair of outer outlets 35 that open at a position on the outside of the room from the vertical frame member 5 on the underside of the pulley box 16, and a pair of connecting passages 36 that connect the first storage section 26 and the pair of outer outlets 35. In addition, the pulley box 16 has a pair of drawer openings 37 that open at the indoor end of the underside of the pulley box 16, and a pair of connecting passages 38 that connect the pair of drawer openings 37 and the second storage section 28. Here, the pair of drawer openings 37 are located directly above the storage space S in the vertical frame member 5 (second frame section 5b), and the indoor operation cord 15 is stored in the storage space S from the pair of drawer openings 37 through the connecting passages 38. The operation cord 15 can be operated through the opening 5c that opens to the indoor side of the vertical frame member 5. That is, in this example, the opening 5c of the vertical frame member 5 plays the role of the outlet 20 that leads the operation cord 15 to the indoor side. Therefore, in this modified example, in order to facilitate operation of the operating cord 15 from inside the room, it is desirable that the opening width of the opening 5c be large enough that the operating cord 15 can be pulled out by hand from inside the storage space S to the outside through the opening 5c.

In the second and third modified examples, the first gear pulley 25 and the second gear pulley 27 have the same structure and diameter, but if necessary, gears with different structures or diameters may be used. For example, the central rectangular hole of the second gear pulley 27 can be omitted, and in the second modified example, the engagement gear 25c of the first gear pulley 25 can be omitted. Also, by making the diameters of the first gear pulley 25 and the second gear pulley 27 different, the operating force of the indoor operating cord 15 can be adjusted.

Furthermore, in the case where the operating cord 15 is led out from within the winding box 4 into the storage space S of the vertical frame member 5 as in the third modified example, it can also be configured as follows.
25 to 28 show a roller blind device 1D of a fourth modified example. In this fourth modified example, as in the third modified example, the operation cord can be led out to both the indoor and outdoor sides, or, in the third modified example, the outdoor side operation cord 15A can be omitted and the operation cord 15 can be led out only to the indoor side. Therefore, the configuration inside the winding box 4 (pulley box 16) will be omitted and the configuration related to the vertical frame member 5 will be mainly described here.

In this fourth modified example, the operating cord 15 is accommodated in the storage space S of the vertical frame member 5 from the outlet 37 and once led out from the opening 5c as the outlet 20 in the vertical frame member 5 to the outside, and is again accommodated in the storage space S through the opening 5c as the inlet 39 opened below the outlet 20. Specifically, the second frame portion 5b of the vertical frame member 5 is provided with an outlet member 40 for leading the operating cord 15 from the storage space S to the inside of the room through the opening 5c as the outlet 20, and a cord holding member 41 for operably retaining the operating cord 15 once led out to the inside of the room by the outlet member 40 in a state where it is introduced into the storage space S again through the opening 5c as the inlet 39, below the outlet member 40.

The lead-out member 40 has a cover 40a formed in a long and narrow mountain shape extending in the vertical direction so as to cover a part of the opening 5c of the vertical frame member 5 and protrude forward into the room, and a pair of legs 40b, 40b that are pushed into the opening 5c, and the pair of legs 40b, 40b have locking claws 40c, 40c that face each other on the outer side of the tip of the pair of legs 40b, 40b. When the lead-out member 40 is attached to the opening 5c, the legs 40b, 40b are pushed into the storage space S from the opening 5c. Then, the inclined surface of the locking claw 40c abuts against the tip of the opening 5c, and the legs 40b, 40b are elastically deformed inward, and when the inclined surface of the locking claw 40c passes through the opening 5c, the legs 40b, 40b elastically return to their original state, the locking claw 40c is locked to the opening 5c, and the lead-out member 40 is attached to the vertical frame member 5.

The cord holding member 41 is arranged in the storage space S and has a guide wheel 41a around which the operating cord 15 is wound, a pair of support plates 41b, 41b arranged in the storage space S and supporting the guide wheel 41a from both sides, a shaft portion 41c of the guide wheel 41a suspended between the pair of support plates 41b, 41b, a lever 41d arranged on the front side of the vertical frame member 5, and a guide groove 41e provided between the pair of support plates 41b, 41b and the lever 41d, which engages with the opening 5c of the vertical frame member 5 to guide the vertical movement of the cord holding member 41.

The cord holding member 41 is fixed at an appropriate position in the vertical direction of the vertical frame member 5 by fastening a screw stopper portion 41f having a screw hole and a receiving piece 41g arranged in the storage space S together with a screw 42, and the vertical position can be adjusted by loosening these fastenings. The lever 41d can be used for this adjustment. The cord holding member 41 is configured so that the operating cord led out to the indoor side is smoothly returned into the storage space S by the guide wheel 41a rotating about its axis as the operating cord 15 is operated.
According to this fourth modified example, for example, the operating cord 15 can be extended into the room on the upper side of the vertical frame member 5 and stored within the storage space S of the vertical frame member 5 on the lower side, thereby positioning the operating cord 15 out of reach of children.

REFERENCE SIGNS LIST 1, 1A, 1B, 1C, 1D Roller screen device 3 Winding shaft 4 Winding box 71 Upper horizontal frame 72 Side frame 73 Bracket 74 Fixed wall 76 Lower support wall 76a Locking hole 77 Rear support wall 80 Locking claw 83 Metal fitting (fixing member)
L1 axis

Claims (3)

A mounting structure for a roller blind device to a building opening,
The building opening is formed by an upper horizontal frame that defines the upper end of the building opening, and a pair of side frames that hang down from both ends of the upper horizontal frame and have inner faces facing each other in the width direction,
The roller blind device has a winding box having a winding shaft therein for winding up the screen by rotating about an axis line,
The roller blind device is attached to the building opening by supporting both ends of the winding box in the axial direction with a pair of brackets attached to inner surfaces of both side frames of the building opening,
Each of the pair of brackets has a fixed wall fixed to the inner surface of the side frame, a lower support wall erected from the fixed wall toward the inside of the building opening and extending in the depth direction, and a rear support wall erected from the fixed wall toward the inside of the building opening and extending in the vertical direction,
A locking mechanism is provided between the lower support walls of the brackets and the lower surfaces of both ends of the winding box, for detachably locking both ends of the winding box to the brackets in the depth direction,
Both ends of the winding box are supported from below by the lower support walls of the pair of brackets in the vertical direction and are sandwiched between the lower support walls and the upper horizontal frame of the building opening, and are locked to the brackets by the locking mechanism in the depth direction while being abutted against the rear support walls of the pair of brackets.
A mounting structure for a roller blind device. The mounting structure for the roller blind device according to claim 1, characterized in that the locking mechanism is composed of locking holes provided on both ends of the winding box and on one side of the rear support walls of the pair of brackets, and locking claws provided on both ends of the winding box and on the other side of the rear support walls of the pair of brackets, and the locking claws are configured to elastically lock into the locking holes. The mounting structure for the roller blind device according to claim 1, characterized in that the winding box is provided with a fixing member that is fixed to the front end surface of the upper horizontal frame in the depth direction.

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