JP3885701B2 - Blind device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a blind device that is arranged in an opening such as a window of a building and opens and closes the opening.
[0002]
[Prior art]
The present applicant has previously proposed a blind device as described in JP-A-8-326445.
[0003]
Such a blind device includes a pair of link mechanisms, a plurality of slat support mechanisms in which one end is connected to one link mechanism and the other end is connected to the other link mechanism, and the slat support mechanism The slats supported by each, the ascending / descending mechanism for raising and lowering the slats, and the slats rising and falling by this ascending / descending mechanism cause a relative positional change in the pair of link mechanisms to tilt the slats Each slat support mechanism includes an arm member that supports an end portion of the slat at a substantially central portion.
[0004]
[Patent Document 1]
JP-A-8-326445
[0005]
[Problems to be solved by the invention]
By the way, in the blind device as long as it is described in the above publication, since each of the link mechanisms connects the plate-like rigid link members to each other via a shaft, it takes a considerable time to assemble the link mechanism. Moreover, a large force is required to lift and lower the slats due to the weight of the link member.
[0006]
The present invention has been made in view of the above-mentioned points. The object of the present invention is to assemble the link mechanism in a short time and to reduce the weight of the link mechanism so that the slat can be lifted and lowered with great force. Therefore, it is an object of the present invention to provide a blind device that can easily lift and lower slats.
[0007]
[Means for Solving the Problems]
The blind device according to the first aspect of the present invention includes a first link mechanism, a second link mechanism juxtaposed to the first link mechanism, one end portion of the first link mechanism, and the other link mechanism. A plurality of slat support mechanisms each having an end connected to the second link mechanism, slats supported by each of the slat support mechanisms, an ascending / descending mechanism for raising and lowering the slats, and this ascending / descending mechanism And a tilt mechanism that tilts the slat by causing a relative positional change in the first and second link mechanisms when the slat is raised and lowered by the mechanism. The first link mechanism includes a flexible belt-like body, and the belt-like body is fixed to one end of each arm member. Rotatably connected The second link mechanism includes a flexible belt-like body, and the belt-like body is fixed and rotatably connected to the other end of each arm member. And a shaft member.
[0008]
According to the blind device of the first aspect of the present invention, instead of a pair of rigid link member rows that are rotatably connected to each other via a shaft, a flexible belt-like body and the belt-like body are fixed. And each link mechanism is configured to include a shaft member rotatably connected to the end of each arm member, so that each link mechanism can be assembled in a short time, and the link mechanism Thus, the slat can be lifted and lowered easily without requiring a large force for lifting and lowering the slat.
[0009]
Preferably, as in the blind device according to the second aspect of the present invention, each band is composed of a single continuous band member, and the band member is rotatably fitted to the corresponding end of each arm member. It is good to penetrate the shaft member.
[0010]
Each strip need only be strong and flexible, and may not have so much elasticity. Rather, it is preferably non-stretchable and has some elasticity. Although it is preferable that it does not have elasticity, it is preferable to use a synthetic resin yarn woven or knitted belt such as polyester or a synthetic resin as in the blind device of the third aspect of the present invention. Made of non-woven fabric band. In the present invention, each belt may be made of a flat belt made of leather or the like instead of the above, and the synthetic resin yarn is preferably a polyester yarn, and a width of 6 mm to 12 mm obtained by plain weaving such a polyester yarn, A flexible belt-like body having a thickness of 0.4 mm to 0.7 mm, more specifically a width of 7 mm and a thickness of 0.6 mm can be further preferred.
[0011]
Each shaft member is preferably composed of an integrally molded product made of a synthetic resin having a cylindrical portion and a shaft portion disposed on each end face of the cylindrical portion, as in the blind device of the fourth aspect of the present invention. The shaft portion is rotatably fitted to the corresponding end portion of each arm member, and in this case, the belt-like body may be integrally fixed to the cylindrical portion and penetrate the cylindrical portion. .
[0012]
When each shaft member is made of an integrally molded product made of synthetic resin as in the blind device of the fourth aspect, the fixing of each shaft member to the belt-like body is performed between the pair of molds for integral molding of the shaft member. It is good to carry out simultaneously with integral molding of each shaft member by pouring the forming material of the shaft member into a pair of molds in a state where the body is sandwiched and the belt-like body is sandwiched.
[0013]
Each shaft member in the blind device of the fourth aspect is made of a synthetic resin further provided with a pair of rectangular protrusions arranged at symmetrical positions with respect to the cylindrical portion, as in the blind device of the fifth aspect of the present invention. In this case, the belt-like body is integrally fixed to the cylindrical portion and the pair of rectangular protrusions, and penetrates the cylindrical portion and the pair of rectangular protrusions. It is good to be.
[0014]
Even in the case of a shaft member having a pair of rectangular protrusions, the band-shaped body is sandwiched between a pair of molds for integral molding of the shaft member as described above, and the pair of mold frames in a state in which the band-shaped body is sandwiched The shaft member forming material may be poured into the shaft member, and the shaft members may be fixed to the belt-like body simultaneously with the integral molding of the shaft members.
[0015]
Further, instead of the above, each belt-like body is a shaft that is rotatably fitted to each corresponding end portion of a pair of arm members adjacent in the vertical direction as in the blind device according to the sixth aspect of the present invention. A plurality of strips terminating in the member may be provided.
[0016]
Each slat is provided with a hollow portion as in the blind device according to the seventh aspect of the present invention in a preferred example. Here, each slat support mechanism is provided at a substantially central portion of the arm member. It is good to further comprise the fitting part fitted by the hollow part in the edge part of a slat.
[0017]
In the blind device according to the eighth aspect of the present invention, each arm member includes an arm body made of a synthetic resin and an arm plate fitted in a snap-fit manner to the arm body. The arm body and the arm plate are sandwiched between them.
[0018]
In the present invention, the ascending / descending mechanism is connected to the lowermost arm member as in the blind device of the ninth aspect, and lifts the lowermost arm member to raise the slat. However, instead of this, it may be connected to the uppermost arm member and lift the slat by lifting the uppermost arm member as in the blind device of the tenth aspect. Good.
[0019]
Next, the present invention and its embodiments will be described in more detail based on preferred examples shown in the drawings. In addition, this invention is not limited to these at all.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
1 to 6, the blind device 1 of the present example includes a pair of vertical frames 2 and 3, a link mechanism 4, a link mechanism 5 juxtaposed with the link mechanism 4, and one end 6 at the link mechanism 4. In addition, the other end 7 is connected to the link mechanism 5, and the slat support mechanism 8 is supported by each of the slat support mechanisms 8 and is juxtaposed to the opening P between the vertical frames 2 and 3. A plurality of slats 9, an ascending / descending mechanism 10 that raises and lowers the slats 9, and a vertical position change relative to the link mechanisms 4 and 5 occurs when the slats 9 are raised and lowered by the raising / lowering mechanism 10 Thus, a tilt mechanism 11 for tilting each slat 9 is provided.
[0021]
The hollow vertical frame 2 has a guide slit 15 extending in the vertical direction, and the hollow vertical frame 3 also has a guide slit 16 extending in the vertical direction. The link mechanisms 4 and 5 and the tilt mechanism 11 are accommodated, and the link mechanisms 4 and 5 and the tilt mechanism 11 on the vertical frame 3 side are configured similarly to the link mechanisms 4 and 5 and the tilt mechanism 11 on the vertical frame 2 side. Therefore, the link mechanisms 4 and 5 and the tilt mechanism 11 on the vertical frame 2 side will be described in detail below.
[0022]
The link mechanism 4 has a single continuous flexible belt-like body 21 and an end portion 6 of each arm member 22 to which the belt-like body 21 is fixed and one end portion 6 of each slat support mechanism 8. And a shaft member 23 that is rotatably connected.
[0023]
Similarly to the link mechanism 4, the link mechanism 5 is also provided with a single continuous flexible band 25 similar to the band 21, the band 25 is fixed, and the other of the slat support mechanisms 8. A shaft member 26 that is rotatably fitted to the end portion 7 of each arm member 22 that is also the end portion 7 and that is the same as the shaft member 23 is provided.
[0024]
The belt-like body 21 includes a shaft member 23 that is rotatably fitted to the end portion 6 of each arm member 22 including the end portions 6 of the uppermost and lowermost arm members 22, in particular, FIGS. ) And the band-shaped body 21 that is fixed to the shaft member 23 at each penetrating portion and penetrates the shaft member 23 fitted to the end 6 of the uppermost arm member 22. Further, it extends to the tilt mechanism 11 and is inserted into the shaft member 28 of the tilt mechanism 11 at its upper end portion 27 as shown in FIG. The belt-like body 21 that penetrates the shaft member 23 fitted to 6 at the lower end portion 29 is fixed to the shaft member 23 at the lower end portion 29 and terminates.
[0025]
Like the belt-like body 21, the belt-like body 25 penetrates the shaft member 26 that is rotatably fitted to the end portions 7 of the arm members 22 including the end portions 7 of the uppermost and lowermost arm members 22. In addition, the belt-like body 25 that is fixed to each shaft member 26 at each penetrating portion and penetrates the shaft member 26 fitted to the end 7 of the uppermost arm member 22 further extends to the tilt mechanism 11. The shaft member 26 is inserted into the shaft member 32 of the tilt mechanism 11 at the upper end portion 31 and fixed to the shaft member 32, and the shaft member 26 fitted to the end portion 7 of the lowest arm member 22 is moved to the lower end. The belt-like body 25 penetrating at the portion 33 is fixed to the shaft member 26 at the lowermost end portion 33 and terminates.
[0026]
Each of the belt-like bodies 21 and 25 may be made of a synthetic resin yarn woven or knitted belt (belt) such as polyester or a synthetic resin non-woven flat belt. It may consist of a flexible band.
[0027]
Each slat support mechanism 8 includes an arm member 22, a shaft portion 36 formed integrally with the arm main body 35 of the arm member 22, a lid portion 37 formed integrally with the shaft portion 36, The shaft portion 36 is arranged inside and outside the vertical frame 2 through the guide slit 15, and the arm main body 35 of the arm member 22. The fitting part 38 provided in the approximate center part via the shaft part 36 and the cover part 37 is fitted in the hollow part 40 in one end part 39 of the slat 9 made of a hollow body.
[0028]
The arm member 22 includes a synthetic resin arm main body 35 having a pair of split pins 41, and a metal or resin arm plate 42 fitted in a snap-fit manner via the split pins 41 of the arm main body 35. The shaft portion 36 is integrally provided at a substantially central portion of the arm main body 35. Thus, the arm member 22 has a shaft portion 36, a lid portion 37, and a fitting portion 38 at the substantially central portion thereof. The end 39 of the slat 9 is supported via
[0029]
Each of the shaft members 23 and 26 is integrally provided on both end faces of the columnar portion 46 disposed between the columnar portion 46, the arm main body 35 and the arm plate 42, and the arm main body 35 and the arm plate. 42 and a pair of shaft portions 47 that are rotatably inserted into the shaft 42. The shaft portions 47 are rotatably fitted to the end portions 6 or 7 of the arm members 22. Each of the belt-like bodies 21 and 25 is integrally fixed to the cylindrical portion 46 and penetrates the cylindrical portion 46. The cylindrical portions 46 may be fixed to the strips 21 and 25 at the time of integral molding of the shaft members 23 and 26, respectively.
[0030]
Each slat 9 is formed of a hollow body, one end 39 thereof is closed by a lid 37 of the slat support mechanism 8, and the other end 49 is disposed on the vertical frame 3 side. The slat support mechanism 8 is closed by the lid portion 37. Each slat 9 is supported at both ends 39 and 49 so as to be parallel to each other in the opening P by the slat support mechanism 8 on the vertical frame 2 side and the vertical frame 3 side.
[0031]
The ascending / descending mechanism 10 includes a chain 51 as a flexible traveling body arranged in the vertical frames 2 and 3, and the other end 53 of the chain 51 having one end 52 which is a free end. Is connected to the lowest slat support mechanism 8, a traveling device 55 for traveling the chain 51 in the A and B directions, and a guide mechanism 56 for guiding the traveling of the chain 51 in the A and B directions. ing.
[0032]
Since the chain 51, the coupling mechanism 54, and the guide mechanism 56 are similarly configured on the vertical frame 2 side and the vertical frame 3 side, the vertical frame 2 side will be described in detail below.
[0033]
The coupling mechanism 54 is arranged concentrically with the shaft portion 36 of the lowest slat support mechanism 8, and includes a pin member 61 fixed to the shaft portion 36 and protruding from the arm plate 42, and one end portion 62. A connecting arm member 65 having the other end 63 pivotably connected to the end 53 of the chain 51 via a pin member 64, and one end being a chain. 51, the other end is locked to the connecting arm member 65, and the central portion is wound around the pin member 64, and is arranged between the chain 51 and the connecting arm member 65. And a torsion coil spring 66.
[0034]
The connecting arm member 65 has a long hole 67 through which the pin member 61 is inserted on the end portion 62 side, and is thereby connected to the pin member 61 so as to be rotatable and linearly movable on the end portion 62 side. The torsion coil spring 66 is connected to the end portion 53 of the chain 51 so that the connection arm member 65 is rotated in the clockwise direction in FIG. Thus, the lowermost arm member 22 is moved downward along the guide slit 15 via the pin member 61.
[0035]
The traveling device 55 includes an electric motor 71 that generates a traveling force for the chain 51, and a transmission unit 72 that transmits the traveling force from the electric motor 71 to the chain 51.
[0036]
When the electric motor 71 supported by the vertical frame 2 via the speed reducer 73 and the bracket 74 is supplied with electric power and rotates its output rotating shaft, the braking of the output rotating shaft is released and electric power is supplied. When the output rotation shaft is not rotated without being rotated, the brake has a braking mechanism that brakes the output rotation shaft so that the output rotation shaft does not freely rotate. This braking mechanism is electromagnetically coupled with the supply of electric power to the electric motor 71. Actuates to release the braking of the output rotating shaft of the electric motor 71, stops the electromagnetic operation together with the stop of the power supply, and brakes the output rotating shaft of the electric motor 71 by mechanical operation. Yes.
[0037]
The transmission means 72 is fixed to a speed reducer 73 that decelerates the rotation of the output rotation shaft of the electric motor 71, a rotation shaft 75 that transmits the rotation of the output rotation shaft of the speed reducer 73, and one end of the rotation shaft 75. In addition, a sprocket wheel 76 as a rotating body around which the chain 51 is wound is provided.
[0038]
The rotary shaft 75 is rotatably supported at each end by brackets 77 attached to the vertical frames 2 and 3, and the sprocket wheel 76 is interposed between the bracket 77 and the rotating body 78 of the tilt mechanism 11. A sprocket wheel similar to the sprocket wheel 76 is also fixed to the other end portion of the rotating shaft 75 on the vertical frame 3 side, and the sprocket wheel on the other end side of the rotating shaft 75 is attached to the vertical frame 2. The chain 51 arranged in the vertical frame 3 is wound around in the same manner as the chain 51 arranged inside.
[0039]
The transmission means 72 transmits the rotational force of the output rotation shaft of the electric motor 71 to the chain 51 as a traveling force in the A and B directions via the speed reducer 73, the rotation shaft 75, and the sprocket wheel 76.
[0040]
In this example, the output rotation shaft of the electric motor 71 is connected to the rotation shaft 75 via the speed reducer 73, but instead of indirectly connecting the output rotation shaft of the electric motor 71 to the rotation shaft 75 in this way. In addition, the output rotation shaft of the electric motor 71 may be directly connected to the rotation shaft 75, or the output rotation shaft of the electric motor 71 may be used as the rotation shaft 75.
[0041]
The guide mechanism 56 extends in the up-down direction and is fixed to the bracket 77 with two pairs of guide walls 81 and 82 formed integrally with the side wall 80 of the vertical frame 2 and around the outer periphery of the sprocket wheel 76. The chain 51 travels through the passage between the two pairs of guide walls 81 and 82, between the chain retainer 83 and the sprocket wheel 76, and between the chain retainers 83 and 84. The two pairs of guide walls 81 and 82 and the chain pressers 83 and 84 prevent the deflection thereof.
[0042]
The tilt mechanism 11 has a rotating body 78 rotatably provided on a rotating shaft 75 via a bearing 90 (see FIG. 8), and the rotating shaft 75 passes therethrough, and rotates with the rotation of the rotating body 78. An attachment member 91 fixed to the rotating body 78 and a clutch mechanism 92 that causes the rotating body 78 to rotate when the chain 51 travels in the A and B directions are provided.
[0043]
The clutch mechanism 92 includes a claw member 94 rotatably attached to the rotating body 78 via a shaft 93, and an engagement pin supported by the vertical frame 2 via a bracket or the like so that the claw member 94 engages. 95 and an engagement projection 96 provided on the chain 51 so as to abut the claw member 94 and release the engagement of the claw member 94 with the engagement pin 95.
[0044]
The claw member 94 integrally includes a claw portion 98 having a recess 97 that engages with the engagement pin 95 and a contact portion 99 (see FIG. 8) that contacts the engagement projection 96. The rotating body 78 is formed with a notch 101 that allows the engagement protrusion 96 to approach the contact portion 99 so that the engagement protrusion 96 contacts the contact portion 99.
[0045]
When the chain 51 travels in the A direction, the clutch mechanism 92 rotates the claw member 94 by the abutment of the engagement protrusion 96 against the abutment portion 99, and the recess 97 of the claw portion 98 and the engagement pin 95 In the travel in the B direction opposite to the A direction of the chain 51, while the rotation of the chain 78 is made to rotate, the rotational body 78 is rotated and the rotational body 78 is rotated along with the travel in the A direction of the chain 51. Then, the claw member 94 is rotated by releasing the contact of the engagement protrusion 96 with the contact portion 99, and the recess 97 of the claw portion 98 and the engagement pin 95 are engaged with each other. It is fixed to the vertical frame 2 via an engagement pin 95 so that it cannot rotate.
[0046]
The tilt mechanism 11 swings the mounting member 91 in the counterclockwise direction in FIG. 3 through the rotating body 78 by the contact of the engagement protrusion 96 with the contact portion 99 by the travel of the chain 51 in the A direction. The upper end portion 27 of the belt-like body 21 is lowered, while the upper end portion 31 of the belt-like body 25 is raised, and the contact of the engagement protrusion 96 with the contact portion 99 by the travel of the chain 51 in the B direction is released. The attachment member 91 is swung in the clockwise direction in FIG. 3 via the rotating body 78 to raise the upper end portion 27 of the belt-like body 21 while lowering the upper end portion 31 of the belt-like body 25. .
[0047]
In the blind device 1 described above, the chain 51 travels in the A direction, and the engagement protrusion 96 provided on the chain 51 is arranged in the notch 101 as shown in FIG. In a state in which the upper end portion 27 of the belt-like body 21 is lowered while the upper end portion 31 of the belt-like body 25 is raised, the lowest-order arm member 22 is a torsion coil as shown in FIG. The belts 21 and 25 are urged downward by the springs 66 via the connecting arm members 65 and the pin members 64, so that the slats 9 are substantially vertical as shown in FIG. And the opening P between the vertical frames 2 and 3 is completely closed. When the electric motor 71 is operated from this state, the rotation of the rotating shaft 75 via the speed reducer 73 causes the sprocket wheel to rotate. 76 Is rolling chain 51 is running in the B direction.
[0048]
As the chain 51 travels in the B direction, the engaging protrusion 96 is also moved in the clockwise direction around the rotation shaft 75. By this movement of the engaging protrusion 96, the rotating body 78 is also rotated in the clockwise direction as shown in FIG. By this rotation of the rotating body 78, the upper end portion 27 of the strip-shaped body 21 is pulled upward, the upper end portion 31 of the strip-shaped body 25 is lowered downward, and thus the strip-shaped bodies 21 and 25 Due to the differential rise and fall, as shown in FIGS. 3 and 4, the end 6 is lifted upward relative to the end 7 of the arm member 22, and each of the arm members 22 rotates clockwise. Thus, as shown in FIGS. 1, 3 and 4, each of the slats 9 is also rotated almost horizontally to form a bowl shape.
[0049]
When the chain 51 further travels in the direction B, the engagement protrusion 96 starts to come off from the notch 101, and the engagement protrusion 96 then comes into contact with the claw portion 98 due to the removal of the engagement protrusion 96 from the notch 101. The claw member 94 is contacted and rotated about the shaft 93, and the recess 97 of the claw portion 98 and the engagement pin 95 are engaged with each other. As shown in FIG. 8, when the recess 97 of the claw portion 98 is engaged with the engagement pin 95, the rotation of the rotating body 78 is prevented and held in that state.
[0050]
As the traveling of the chain 51 in the B direction is continued, the lowermost arm member 22 connected to the end portion 53 of the chain 51 starts to be lifted by the connecting mechanism 54 and is bent from the lower strips 21 and 25 together with this. First, as shown in FIG. 11, the slats 9 are sequentially overlapped from below by this bending. In FIG. 11, the band-like bodies 21 and 25 which are bent for the sake of explanation are shown protruding in the lateral direction due to their slight elasticity, but if they have little elasticity, they will hang down. When all the slats 9 are overlaid on the upper side, the operation of the electric motor 71 is stopped by a signal from a detector or the like, and the state where the opening P is completely opened is maintained.
[0051]
When the electric motor 71 is operated in the state in which the opening P is completely opened or in the middle of the opening P, the chain 51 travels in the direction A, whereby the strips 21 and 25 are moved upward. The superposition starts and the superposition of the upper slats 9 starts to be released. When all the flexures of the belts 21 and 25 are eliminated and the slats 9 are all unsuperposed, the engagement protrusion 96 starts to be inserted into the notch 101 as shown in FIG. 9, the engagement protrusion 96 contacts the contact portion 99 of the claw member 94 to rotate the claw member 94, thereby releasing the engagement of the recess 97 with the engagement pin 95. 10, the rotating body 78 is rotated counterclockwise as shown in FIG. 10 together with the movement of the engaging protrusion 96, and the upper end 31 of the band 25 is pulled upward, so that the upper end of the band 21 is The portion 27 is lowered downward, and the band-like bodies 21 and 25 are displaced relative to each other by such differential rise and fall of the band-like bodies 21 and 25, so that the band-like bodies 21 and 25 are connected to each other via the slat support mechanism 8. The supported slat 9 is tilted in the opposite direction and is shown in FIG. It comes to completely close the opening P as. Thereafter, the operation of the electric motor 71 is stopped by a signal from the detector or the like, and the state where the opening P is completely closed is maintained.
[0052]
In the blind device 1, the operation of the electric motor 71 is not stopped immediately after the opening P is completely closed, and the pin member 64 is attached to the end portion 53 of the chain 51 even if the chain 51 further travels in the A direction. The connecting arm member 65, which is rotatably connected via the torsion, rotates about the pin member 61 against the elastic force of the torsion coil spring 66 and moves directly with respect to the pin member 61. Further lower movement of the lowermost arm member 22 is not caused.
[0053]
In the above-described blind device 1 including the combination of the link mechanisms 4 and 5 and the slat support mechanism 8, instead of a pair of rigid link member rows that are rotatably connected to each other via a shaft, it is possible. A link having flexible strips 21 and 25 and shaft members 23 and 26 to which the strips 21 and 25 are fixed and rotatably connected to the end portions 6 and 7 of each arm member 22. Since the mechanisms 4 and 5 are configured, the link mechanisms 4 and 5 can be assembled in a short time, and the link mechanisms 4 and 5 can be reduced in weight so that a large force is not required for lifting and lowering the slats 9. The slat 9 can be easily lifted and lowered.
[0054]
In the above example, the traveling body is not limited to the end chain 51 having the end portions 53 and 52, and may be an endless chain. In this case, in addition to the sprocket wheel 76, another sprocket wheel is disposed. Thus, an endless chain may be hung between the two sprocket wheels. If such an endless chain is used as the traveling body, the guide mechanism 56 can be omitted. In addition, the traveling body may be a timing belt or the like. When a timing belt is used, a toothed pulley may be used instead of the sprocket wheel 76. Further, the transmission means 72 may be configured without the speed reducer 73. In this case, an electric motor 71 capable of speed control may be used as necessary.
[0055]
In the link mechanisms 4 and 5, the belt-like bodies 21 and 25 are terminated at the lower ends 29 and 33 of the shaft members 23 and 26 and terminated outside the shaft members 23 and 26. The bodies 21 and 25 may be terminated within the cylindrical portion 46 of the shaft members 23 and 26 at their lower end portions 29 and 33, and the shaft members 23 and 26 are added to the cylindrical portion 46 and the shaft portion 47, respectively. 12 (a) and 12 (b), a pair of rectangular protrusions 115 and 116 that are disposed symmetrically with respect to the axial center of the cylindrical portion 46 and are formed integrally with the cylindrical portion 46 are provided. In this case, each of the belt-like bodies 21 and 25 is integrally fixed to the cylindrical portion 46 and the pair of rectangular protrusions 115 and 116. The cylindrical part 4 And it extends through the pair of rectangular projecting portions 115 and 116. Furthermore, in the above, the link mechanisms 4 and 5 are constituted by the two continuous strips 21 and 25, but instead of this, as shown in FIGS. A plurality of strips 111 and 112 respectively terminating in shaft members 23 and 26 that are rotatably fitted to corresponding ends 6 and 7 of a pair of adjacent arm members 22, respectively, are linked. Mechanisms 4 and 5 may be configured. In this case, the strips excluding the upper ends 113 (corresponding to the upper ends 27 and 31) of the uppermost strips 111 and 112 and the lower ends 114 (corresponding to the lower ends 29 and 33) of the lowermost strips 111 and 112. 111 and 112 are fixed to the respective cylindrical portions 46 of the shaft members 23 and 26 at the upper end portion 113 and the lower end portion 114, respectively, and terminate in the cylindrical portion 46, and the uppermost strips 111 and 112 are The lower end strips 111 and 112 are fixed to the respective cylindrical portions 46 of the lowermost shaft members 23 and 26 at the lower end portion 114 thereof. It terminates in the cylindrical portion 46. Even in the case of such strips 111 and 112, shaft members 23 and 26 as shown in FIGS. 12A and 12B may be used.
[0056]
By the way, in the blind device 1 described above, the arm member 22 of the lowermost slat support mechanism 8 is lifted by the ascending / descending mechanism 10 and sequentially lifted from the lower slat 9 to open the opening P. Instead, as shown in FIGS. 14 and 15, the ascending / descending mechanism 10 is connected to the uppermost arm member 22, and the uppermost arm member 22 is lifted and sequentially lifted from the upper slat 9 to open. You may make it make the part P into a closed state.
[0057]
That is, in the ascending / descending mechanism 10 in the blind device 1 shown in FIGS. 14 and 15, the end portion 53 of the chain 51 guided by the guide mechanism 56 in the A and B directions is rotatably connected to the pin member 121. The pin member 121 is arranged concentrically with the shaft portion 36 of the uppermost slat support mechanism 8 and is fixed to the shaft portion 36 so as to protrude from the arm plate 42. When the end portion 53 is lowered and raised by the running of the chain 51 in the A and B directions by the operation of 71, the arm member 22 of the uppermost slat support mechanism 8 is similarly lowered and raised via the pin member 121. Here, the arm member 22 of the lowest-order slat support mechanism 8 is rotatably connected to the pin member 61 and guided in the vertical movement. A slider member 122 disposed in the guide slit 15, and a coil spring 124 connected to the slider member 122 at one end and to the bottom wall 123 of the vertical frame 2 at the other end. The pulling mechanism 125 is elastically pulled downward.
[0058]
The tilt mechanism 11 in the blind device 1 shown in FIGS. 14 and 15 includes a cam roller 132 rotatably provided on the shaft member 131 and a cam protrusion 134 integrally provided on the front wall portion 133 of the vertical frame 2. And a cam surface member 136 that extends in the vertical direction below the cam projection 134 and is provided integrally with the front wall portion 133 of the vertical frame 2 with the recess 135 interposed therebetween. The uppermost arm member 22 is arranged concentrically with the shaft member 23 on the end 6 side, and is fixed to the shaft portion 47 of the shaft member 23 so as to protrude from the arm plate 42, and is provided with a link mechanism. The upper end portion 27 of the belt-like member 21 is fixed to the uppermost shaft member 23 and terminated in the cylindrical portion 46 of the shaft member 23, while the upper end portion 31 of the belt-like member 25 of the link mechanism 5 is Fixed to the uppermost shaft member 26 It is being terminated in the cylindrical portion 46 of the shaft member 26.
[0059]
In the blind device 1 shown in FIGS. 14 and 15, in the open state of the opening P, as shown in FIG. 17, the strips 21 and 25 are bent, and the cam roller 132 is in contact with the cam surface member 136. Each of the slats 9 is closely polymerized (bundled) downward from each other. When closing the opening P, first, the electric motor 71 is operated, and the rotation of its output rotation shaft rotates the sprocket wheel 76, thereby causing the chain 51 to travel in the direction B, as shown in FIG. The strips 21 and 25 are also extended from the upper end side thereof, and the arm member 22 is also lifted upward from the upper side. As a result, the slats 9 supported by the arm member 22 are sequentially lifted in the closing direction. When the cam roller 132 is guided in contact with the cam surface member 136, the slat 9 is held in a substantially horizontal tilted state.
[0060]
Further, when the chain 51 travels in the B direction, the belt-like bodies 21 and 25 extend at a position immediately before the opening P is completely closed, while the lowermost arm member 22 is elasticated by the coil spring 124 via the belt-like bodies 21 and 25. When the cam roller 132 is slightly lifted against the force and faces the recess 135 and comes into contact with the cam projection 134 as shown in FIG. 16 from the contact with the cam surface member 136, the uppermost arm member 22. Is started to rotate, and the upper end 31 of the strip 25 is lifted more than the upper end 27 of the strip 21 so that the uppermost slat 9 is rotated in the counterclockwise direction. Then, the rotation of the uppermost arm member 22 in the counterclockwise direction is transmitted to the lower arm member 22 via the belt-like body 21 and the belt-like body 25, and all the slats 9 are held in a substantially vertical tilt state. Results Opening P by the slats 9 will be fully closed. Thereafter, the operation of the electric motor 71 is stopped and the closing operation is completed. Even when the operation stop of the electric motor 71 is slightly delayed and the belt-like bodies 21 and 25 that are fully extended, even if the lowermost arm member 22 is further lifted upward, it is elastically biased downward by the coil spring 124. Since the lower slider member 122 moves upward, even if the operation stop of the electric motor 71 is delayed, the strips 21 and 25 and the like are not damaged.
[0061]
When the opening P is opened, the electric motor 71 is operated reversely to the above, whereby the cam roller 132 is shifted from the contact with the cam projection 134 to the contact with the cam surface member 136, and the belt-like bodies 21 and 25 are moved. It will bend sequentially from below.
[0062]
Also in the blind device 1 shown in FIGS. 14 and 15, the flexible strips 21 and 25 and the strips 21 and 25 are inserted and rotatably connected to the end portions 6 and 7 of each arm member 22. Since the link mechanisms 4 and 5 are configured to include the shaft members 23 and 26, the link mechanisms 4 and 5 can be assembled in a short time, and the link mechanisms 4 and 5 can be reduced in weight and slats. The slats 9 can be easily lifted and lowered without requiring a large force for lifting and lowering 9.
[0063]
In the above ascending / descending mechanism 10, the electric motor 71 is provided and the slat 9 is automatically lifted. Alternatively, the ascending / descending mechanism 10 may be configured to manually lift the slat 9. Good.
[0064]
In the blind device 1 described above, the slat 9 made of a hollow body is used. Instead, as shown in FIGS. 18 and 19, a plate-like and curved slat main body 151, and a slat main body are provided. The blind device 1 may be configured by using a slat 9 having a hollow rectangular portion 153 integrally formed on one surface 152 of the 151. In this case, the end portion of the slat 9 shown in FIGS. The fitting portion 38 of the slat support mechanism 8 is fitted into the hollow portion 154 formed by the rectangular portion 153 in 39 and 49 to support the slat 9. According to the slats 9 shown in FIGS. 18 and 19, the weight can be further reduced, so that a large force is not required for lifting and lowering the slats 9, and the slats 9 can be easily lifted and lowered. 9 can be manufactured easily.
[0065]
【The invention's effect】
According to the present invention, a blind device that can assemble a link mechanism in a short time, can reduce the weight of the link mechanism, does not require a large force for lifting and lowering the slat, and can easily lift and lower the slat. Can be provided.
[Brief description of the drawings]
FIG. 1 is a perspective view of a preferred example of the present invention.
2 is a side view of a part of the example shown in FIG.
3 is an explanatory side view of the slat in the example shown in FIG. 1 and one of the vertical frames. FIG.
4 is an explanatory side view in one vertical frame of the example shown in FIG. 1; FIG.
FIG. 5 is an explanatory plan view of the example shown in FIG. 1;
6A and 6B are explanatory views of the link mechanism of the example shown in FIG. 1, wherein FIG. 6A is a front explanatory view thereof, and FIG. 6B is a side explanatory view thereof.
7 is an operation explanatory diagram of the example shown in FIG. 1. FIG.
8 is an operation explanatory diagram of the example shown in FIG. 1. FIG.
FIG. 9 is an operation explanatory diagram of the example shown in FIG. 1;
10 is an operation explanatory diagram of the example shown in FIG. 1. FIG.
FIG. 11 is an operation explanatory diagram of the example shown in FIG. 1;
12A and 12B are explanatory views of another example of the link mechanism shown in FIG. 1, wherein FIG. 12A is a front explanatory view thereof, and FIG. 12B is a side explanatory view thereof.
13A and 13B are explanatory views of still another example of the link mechanism shown in FIG. 1, wherein FIG. 13A is a front explanatory view thereof, and FIG. 13B is a side explanatory view thereof.
FIG. 14 is an explanatory diagram of another example of the ascending / descending mechanism and the tilt mechanism shown in FIG.
15 is an explanatory plan view of another example of the raising / lowering mechanism and the tilt mechanism shown in FIG.
16 is an operation explanatory diagram of the example shown in FIGS. 14 and 15. FIG.
17 is an operation explanatory diagram of the example shown in FIGS. 14 and 15. FIG.
FIG. 18 is a perspective explanatory view of another example of a slat used in the blind device of the present invention.
19 is an explanatory cross-sectional view of the example shown in FIG.
[Explanation of symbols]
1 Blind device
2, 3 vertical frame
4, 5 Link mechanism
8 Slat support mechanism
9 Slats
10 Ascent / descent mechanism
11 Tilt mechanism

Claims (11)

The first link mechanism, the second link mechanism juxtaposed to the first link mechanism, one end connected to the first link mechanism, and the other end connected to the second link mechanism. A plurality of slat support mechanisms, slats supported by each of the slat support mechanisms, an ascending / descending mechanism for raising and lowering the slats, and first and second slats ascending and descending by the ascending / descending mechanism. A tilt mechanism that tilts the slat by causing a relative position change in the two link mechanisms, and each slat support mechanism includes an arm member that supports the end of the slat at a substantially central portion. The first link mechanism includes a flexible belt-like body and a shaft member to which the belt-like body is fixed and rotatably connected to one end of each arm member. Second link machine It includes a strip of flexible, blind apparatus which comprises a shaft member which is rotatably connected to the other end of each arm member with this strip is fixed. 2. The blind according to claim 1, wherein each belt-like body is formed of a single continuous belt-like member, and the belt-like member passes through a shaft member that is rotatably fitted to a corresponding end of each arm member. apparatus. 3. The blind device according to claim 1, wherein each belt-shaped body is made of a woven or knitted belt made of synthetic resin such as polyester or a non-woven fabric belt made of synthetic resin. Each shaft member is formed of a synthetic resin-made integral product including a cylindrical portion and a shaft portion disposed on each end face of the cylindrical portion, and the shaft portion can freely rotate to a corresponding end portion of each arm member. The blind device according to any one of claims 1 to 3, wherein the blind device is fitted and the belt-like body is integrally fixed to the cylindrical portion and penetrates the cylindrical portion. Each shaft member is composed of an integrally molded product made of a synthetic resin further provided with a pair of rectangular protrusions arranged at symmetrical positions with respect to the axis of the cylindrical part. The blind device according to claim 4, wherein the blind device is integrally fixed to the portion and penetrates the cylindrical portion and the pair of rectangular protrusions. Each strip | belt body is equipped with the some strip | belt piece which terminates in the shaft member currently rotatably fitted to each edge part corresponding to a pair of arm member adjacent in the up-down direction. The blind device described. Each slat has a hollow portion, and each slat support mechanism is further provided with a fitting portion that is provided at a substantially central portion of the arm member and is fitted into the hollow portion at the end portion of the slat. The blind apparatus as described in any one of Claim 1 to 6. Each arm member includes an arm body made of a synthetic resin and an arm plate fitted in a snap-fit manner to the arm body. Each shaft member is disposed between the arm body and the arm plate. A blind device according to any one of the preceding claims. The blind device according to any one of claims 1 to 8, wherein the ascending / descending mechanism is connected to a lowermost arm member and raises the lowermost arm member to raise the slat. The blind device according to any one of claims 1 to 8, wherein the ascending / descending mechanism is connected to the uppermost arm member and raises the uppermost arm member to raise the slat. A combination of a slat support mechanism for use in the blind device according to any one of claims 1 to 10 and a first and second link mechanism, wherein the slat support mechanism has a slat support at a substantially central portion. Each link mechanism includes a flexible belt-like body and a shaft to which the belt-like body is fixed and rotatably connected to the end of each arm member. A combination of a slat support mechanism and a link mechanism.

Images