JP3823430B2 - Blind device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a blind device that is disposed in an opening such as a window of a building and used to open and close the opening.
[0002]
[Problems to be solved by the invention]
In this type of blind device, a rotating shaft is generally provided by bridging left and right vertical frames at the top of the opening, and sprocket wheels are attached to both ends of the rotating shaft. One chain is hung, a link mechanism that supports each end of a number of slats is connected to the chain, and when the rotation shaft is rotated by the operation of a drive mechanism such as an electric motor, each sprocket wheel The chain is rotated so that the chain travels, and a large number of slats are raised and lowered through the link mechanism by the travel of the chain, thereby opening and closing openings such as windows of the building.
[0003]
In such a conventional blind device, the chain is usually held in the guide passage and is in an inflexible state so that the slat can be easily lifted and the opening is not opened for crime prevention after the closure is completed. The link mechanism cannot be folded even when the lower slat is lifted.
[0004]
By the way, if you want to escape from the building urgently in a disaster such as a fire or an earthquake where you can not expect the opening of the opening by chain running and you can not always expect the power supply necessary for chain running As described above, it is extremely inconvenient if the opening is not opened from the viewpoint of crime prevention, and it is required for the blind device that the opening can be easily and quickly opened manually. Is done.
[0005]
Therefore, the applicant of the present invention has disclosed blind devices capable of solving the above-described inconveniences and easily and quickly opening the closed opening by Japanese Patent Application No. 8-165218 and Japanese Patent Application No. 8-247062. Proposed in each. The blind device according to this proposal includes a link mechanism connected to both ends of each slat so that the lifting means for raising and lowering the slat supports each slat, and a link mechanism that causes the link mechanism to expand and contract by running. A traveling body connected to the traveling body, and a traveling device for traveling the traveling body, wherein the traveling device generates a traveling force for the traveling body, and a manual traveling for generating a traveling force for the traveling body by a manual pull-down operation. Force generating means, and transmission means for transmitting the traveling force from the electric motor and the manual traveling force generating means to the traveling body. The manual traveling force generating means is a string-like body and the string-like body is hung. Thus, the blind device raises the slat lowered to close the opening from the slat at the lower end by the running of the string-like body. It is those that have become way.
[0006]
Although the blind device according to this proposal can sufficiently achieve the above-mentioned initial purpose, it is not necessary to provide such a blind device for emergency escape in all windows in one room. Only when it is desired to install a blind device equipped with a manual running force generating means for emergency escape, and to install a blind device equipped with a manual running force generating means for power failure in other windows There is.
[0007]
In such a case, the blind device for that purpose must be designed and manufactured separately, which is expensive and increases costs.
[0008]
The present invention has been made in view of the above-mentioned points, and the object of the present invention is to obtain the effect of the blind device proposed in Japanese Patent Application No. 8-165218 as it is, and in addition, an emergency escape function. It is an object of the present invention to provide a blind device that can be easily changed with little expense to either a device having a power supply or a device having an opening function during a power failure.
[0009]
[Means for Solving the Problems]
The blind device of the present invention is a blind device comprising a large number of slats juxtaposed in an opening and lifting means for lifting and lowering each slat, and the lifting means supports both ends of each slat so as to support each slat. A link mechanism connected to the section, a traveling body connected to the link mechanism so that the link mechanism can be expanded and contracted by traveling, and a traveling device that causes the traveling body to travel. An electric motor for generating a running force on the body, a manual running force generating means for generating a running force on the running body by a manual pull-down operation, and a transmission for transmitting the running force from the electric motor and the manual running force generating means to the running body As a manual travel force generation means, either a manual travel force generation mechanism for emergency escape or a manual travel force generation mechanism for power failure is selectively used. And it is configured to be able to kick.
[0010]
The body case fitted with the transmission means is selectively selected from either a case equipped with a manual running force generation mechanism for emergency escape or a case fitted with a manual running force generation mechanism for power failure. The so-called cassette type can be attached freely.
[0011]
In the present invention, an emergency escape manual running force generating mechanism includes a rotatable shaft, a one-way clutch bearing mounted on the shaft, a pulley mounted on the one-way clutch bearing, and a pulley wound around the pulley. And a spring spring having one end fixed on the rotation side and the other end fixed on the fixed side, and the one-way clutch bearing is formed by lowering the string-like body. While the rotation of the pulley is transmitted to the shaft, the reverse rotation of the pulley due to the elastic force of the mainspring spring is not transmitted to the shaft. Is stored and is configured to reverse the pulley with the elastic energy stored by the removal of the pull-down force of the string-like body, the manual running force generating mechanism for power failure includes a rotatable shaft, A pulley mounted on the shaft of the, I hung on the pulley, and a string-like body operably hanging down was endless.
[0012]
If the manual running force generating mechanism for emergency escape is configured in this way, the running force on the running body can be generated without error by simply pulling down a single string-like body, and safety is improved. If the manual running force generation mechanism for power failure is configured as described above, it is possible to provide a low-cost blind device.
[0013]
The transmission means includes a rotatable shaft that can be connected to the shafts of the emergency traveling manual traveling force generating mechanism and the manual traveling force generating mechanism for power failure. The transmission means has a large-diameter spur gear and a small-diameter spur gear meshed with the spur gear, and the rotatable shaft of the large-diameter spur gear generates a manual running force for emergency escape. The shaft of the mechanism and the rotatable shaft of the small-diameter spur gear are configured to be connectable to the shaft of the manual travel force generating mechanism for power failure, respectively. It is transmitted to the traveling body via a small-diameter spur gear. In such a blind device, the rotation of the shaft of the manual running force generating mechanism for power failure is increased, and as a result, quick opening can be achieved. It can be provided.
[0014]
Further, in the present invention, the transmission means includes a worm wheel and the worm wheel so that the transmission of the traveling force to the traveling body due to the operation of the electric motor to the manual traveling force generation means can be prohibited when the manual traveling force generation means is not operated. A worm that meshes with the wheel, the worm wheel rotates from either the electric motor or the manual running force generating means, and the worm has the other of the electric motor or the manual running force generating means. The rotation from is transmitted respectively. By using the combination of the worm wheel and the worm in the transmission mechanism, it is not necessary to provide a special prohibition mechanism, the configuration can be simplified, and the cost can be reduced.
[0015]
In the brand device of the present invention, the transmission means includes a planetary gear mechanism having a sun gear, a planetary gear meshing with the sun gear, and an internal gear meshing with the planetary gear. The internal gear is connected to the manual travel force generating means via the worm wheel and the worm, and the planetary gear is connected to the travel body. When such a planetary gear mechanism is used, coupled with the combination of the worm wheel and the worm, the rotation of the output rotation shaft of the electric motor and the rotation from the manual travel force generating means can be easily switched and transmitted to the traveling body. can do. In this case, when the electric motor is not in operation, it is preferable to use a motor in which braking is forcibly applied to the output rotation shaft so that the output rotation shaft cannot be easily rotated by an external force. .
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Next, the present invention and its embodiments will be described in more detail based on preferred embodiments shown in the drawings. The present invention is not limited to these examples.
[0017]
【Example】
1 to 11, the blind device 1 of this example includes a large number of slats 7 juxtaposed in openings 6 surrounded by left and right vertical frames 2 and 3 and upper and lower frames 4 and 5, and each slat 7 is lifted and lowered. Lifting and lowering means 8 for tilting and a tilt mechanism 9 for tilting the slat 7 are provided. The left and right vertical frames 2 and 3 and the upper and lower frames 4 and 5 are respectively arranged corresponding to the left and right vertical fences and upper and lower fences of a window of a building, for example. A blindfold plate 10 is provided above the opening 6 by being supported by the vertical frames 2 and 3 and the like, and the blindfold plate 10 covers the bundle of slats 7 superimposed on the upper side.
[0018]
The elevating means 8 includes a link mechanism 11 connected to one end of each slat 7 so as to support each slat 7, and a traveling body connected to the link mechanism 11 so that the link mechanism 11 can be expanded and contracted by traveling. As a chain 12, a traveling device 13 for running the chain 12, and a bending prevention means 14 for preventing the chain 12 from bending.
[0019]
The link mechanism 11 includes a first link mechanism 21, a second link mechanism 22 juxtaposed to the link mechanism 21, one end 23 via the shaft 24, and the other end 25 via the shaft 26. A plurality of slat support mechanisms 27 are rotatably connected to the link mechanism 22, and each slat 7 is supported by each of the slat support mechanisms 27.
[0020]
The link mechanism 21 includes a plurality of link members 32 rotatably connected in series via a shaft 24 and a shaft 31, and the link mechanism 22 is connected to each other in series via a shaft 26 and a shaft 33. A plurality of link members 34 rotatably connected are provided. The link members 32 and 34 are integrally provided with a restriction piece 35 that defines the folding direction of the link mechanisms 21 and 22.
[0021]
In each of the slat support mechanisms 27, one end 23 is connected to every other connecting portion (a portion of the shaft 24) in the connecting portion (a portion of the shaft 24 and the shaft 31) of the link member 32 so as to be rotatable relative to each other. The other end 25 is connected to every other connecting portion (the shaft 26 and the shaft 33) of the link member 34 in the mutually rotatable connecting portion (the portion of the shaft 26 and the shaft 33). The arm 41 is pivotally connected to the part) via the shaft 26, and the mounting portion 42 is fixed to the substantially central portion of the arm 41 and extends in the horizontal direction. The portion 42 extends through a guide path 44 formed in the vertical frame 2 and extends in the vertical direction, and the slat 7 is fixed to the mounting portion 42 on the outer side of the vertical frame 2, and thus the slat support mechanism 27. Each of them can be moved up and down by being guided by the guide path 44. And it supports each of the slats 7.
[0022]
The chain 12 has one end 51 and the other end 52 and is hung on a sprocket wheel 53, and the one end 51 of the chain 12 is connected to the lower portions 55 of the link mechanisms 21 and 22 through connection means 54. . In this example, the connecting means 54 connects the lower end 51 of the chain 12 to the lower portions 55 of the link mechanisms 21 and 22 via the lowermost slat support mechanism 27 and is guided by the guide path 44 so as to be movable up and down. The movable body 61 connected to the slat support mechanism 27 and one end 62 are rotatably and linearly connected to the movable body 61, and the other end 63 is connected to one end 51 of the chain 12 via a pin 67. The arm 64 is movably connected, and is disposed between one end 51 of the chain 12 and the arm 64. One end 65 is locked to the one end 51 of the chain 12, and the other end 66 is locked to the arm 64. And elastic means 69 comprising a torsion coil spring 68 wound around a pin 67.
[0023]
The movable body 61 has a mounting portion 42 of the slat support mechanism 27 penetrating therethrough, a main body 71 arranged on the guide path 44 and guided by the guide path 44 and movable up and down, and a pin 71 on the main body 71 via a pin 72. The arm 64 has a long hole 74 at one end 62, and a pin 75 is inserted into the long hole 74. It is connected to the movable body 61 so as to be rotatable and linearly movable. The spring 68 elastically biases the arm 64 against the one end 51 of the chain 12 so as to rotate the arm 64 counterclockwise in FIG. The body 61 is moved downward along the guide path 44.
[0024]
The travel device 13 includes an electric motor 81 that generates a travel force for the chain 12, a manual travel force generation mechanism 82 for emergency escape as a manual travel force generation unit that generates a travel force for the chain 12 by a manual pull-down operation, A transmission means 83 for transmitting the traveling force from the motor 81 and the manual traveling force generation mechanism 82 to the chain 12 is provided.
[0025]
The electric motor 81 attached to the upper part of the vertical frame 2 in the upper frame 4 via the main body case 84 in which the transmission means 83 is accommodated and mounted is automatically rotationally braked on the output rotary shaft 85 when not operating. Configured to be. Therefore, when the electric motor 81 is not in operation and the opening 6 is in the open state, the slat 7 is lowered by the dead weight of the slat 7 or the like so that the opening 6 is not closed without permission.
[0026]
The manual running force generation mechanism 82 includes a shaft 89 rotatably supported by a case 86 via a bearing 88, a one-way clutch bearing 90 attached to the shaft 89, and a pulley 91 attached to the one-way clutch bearing 90. And the other end is fixed to the inner surface of the cylindrical portion of the pulley 91, which is wound around the pulley 91 and is operably hung down, the grip portion 92 is attached to the lower end, and one end is the rotation side. The springs 94 are fixed to the outer surface of the cylindrical portion of the case 86 on the side. One end of the shaft 89 opposite to the bearing 88 protrudes from the case 86 to the outside, and the manual running force generation mechanism 82 is accommodated and mounted in the case 86.
[0027]
The one-way clutch bearing 90 transmits the rotation in one direction around the shaft 89 of the pulley 91 due to the lowering of the string-like body 93 in the downward direction C to the shaft 89, while the pulley 91 due to the elastic force of the mainspring spring 94. The pulley 91 is configured to rotate freely with respect to the shaft 89 without transmitting the rotation (reverse rotation) in the direction opposite to the one direction to the shaft 89, and the mainspring spring 94 is formed on the cylindrical portion of the case 86. It consists of a leaf spring concentrically wound around the outer surface and is reduced in diameter by the rotation of the pulley 91 due to the lowering of the string-like body 93 so that elastic energy is stored in itself, and the lowering force of the string-like body 93 The pulley 91 is rotated in the reverse direction by expanding the diameter with the elastic energy stored by the removal. The string-like body 93 is wound around the pulley 91 by the reverse rotation of the pulley 91.
[0028]
In the manual running force generation mechanism 82, the pulley 91 is rotated by grasping the grip portion 92 and running the string-like body 93 in the C direction, so that the shaft 89 can be similarly rotated. The body 93 is suspended from the room side of the building so that the opening 93 can be manually pulled down from the room side of the building at the opening 6. The shaft 89 is continuously moved in one direction by alternately repeating the traveling in the C direction of the string-like body 93 while grasping the grip portion 92 and the winding of the string-like body 93 around the pulley 91 by the mainspring spring 94. Can be rotated.
[0029]
The transmission means 83 is rotatably supported on the body case 84 via bearings 95 and 96, and has a fitting recess 97 at one end of the shaft 95 protruding from the case 86 at one end on the bearing 95 side. The shaft 98, the large-diameter spur gear 99 fixed to the shaft 98, and the main body case 84 are rotatably supported via bearings 100 and 101, and the fitting recess 102 is formed at one end on the bearing 100 side. A shaft 103 having a small diameter, a small-diameter spur gear 113 meshed with the spur gear 99 and fixed to the shaft 103, a worm 105 formed on the shaft 103, a worm wheel 106 meshed with the worm 105, and a reduction gear mechanism. A functioning planetary gear mechanism 107, a helical gear 109 fixed to the output shaft 108 of the planetary gear mechanism 107, a helical gear 110 meshed with the gear 109, and the gear 110 axially The rotary shaft 104 and the overload detecting means 114 are mounted so as to be slidably connected to each other, and are rotatably supported by the body case 84 via bearings 111 and 112. Yes. The output shaft 108, the gear 109 and the gear 110 are rotatably supported by the main body case 84 via bearings 118 and 119, respectively.
[0030]
The worm wheel 106 that is concentrically and relatively rotatably mounted on the output shaft 108 via the slide bearing 115 has a cylindrical portion 116 integrally therewith. The main body case 84 is rotatably supported.
[0031]
The planetary gear mechanism 106 is rotatably disposed around the input shaft 121 supported by the main body case 84 via the bearing 120, the sun gear 122 fixed to the input shaft 121, and the sun gear 122. And a plurality of planetary gears 123 meshing with the sun gear 122, and an internal gear 124 having rotatable internal gears meshing with the planetary gears 123.
[0032]
The input shaft 121 is connected to the output rotation shaft 85 of the electric motor 81, and the internal gear 124 includes a large-diameter cylindrical portion 126 formed on the inner surface with internal teeth that mesh with the planetary gear 123, and a small-diameter cylindrical portion. 127, and the cylindrical portion 127 is fitted into the cylindrical portion 116 of the worm wheel 106, and is connected and fixed thereto, and is concentrically and relatively rotatable with respect to the output shaft 108. It is installed. Each of the planetary gears 123 is connected to the output shaft 108 so as to transmit the rotation around the sun gear 122 to the output shaft 108.
[0033]
Both ends of the rotating shaft 104 protrude from the main body case 84. A sprocket wheel 53 is fixed to one protruding end of the rotating shaft 104, and a rotating body 162 described later is rotatably provided via a bearing 161. The connecting shaft 131 is fitted to the other protruding end. In this way, the planetary gear 107 is connected to the chain 12 via the output shaft 108, the gears 109 and 110, the rotating shaft 104 and the sprocket wheel 53.
[0034]
The overload detection unit 114 includes a coil spring 135 concentrically mounted on the rotating shaft 104 and a limit switch 136 attached to the main body case 85. When the slat 7 is lowered, the overload detecting means 114 has a person or the like sandwiched between the lowermost slat 7 and the lower frame 5 so that an excessive load is applied to the gear 109 via the rotating shaft 104 and meshes with each other. Due to the action of the tooth gears 109 and 110, the gear 110 is moved in the axial direction so as to contract the coil spring 135 against its elastic force, the gear 110 abuts against the detection piece of the limit switch 136, and the limit switch 136 is By being actuated, an overload of the gear 109 is detected, and thus, a person or the like is caught, and necessary safety measures such as stopping the operation of the electric motor 81 are taken.
[0035]
The transmission means 83 is housed and mounted in the main body case 84 with both ends of the rotating shaft 104 protruding.
[0036]
The blocking means 14 includes a pair of guide walls 151 and 152 formed integrally with the vertical frame 2, and a chain presser 153 provided on the vertical frame 2 and arranged around the sprocket wheel 53. The chain 12 travels through the guide paths 154 and 155 formed between the pair of guide walls 151 and 152 and the chain passage 156 between the chain presser 153 and the sprocket wheel 53, and the pair of guide walls 151. And 152 and the chain presser 153 prevent the unnecessary deflection.
[0037]
The tilt mechanism 9 includes a rotating body 162 rotatably provided on a rotating shaft 104 via a bearing 161, each end 163 and 164 at the rotating body 162, and each other end 165 and 166 at the link mechanisms 21 and 22. A pair of string-like bodies connected to the respective upper ends 167 and 168, for example, chains or wires 169 and 170, and a clutch mechanism 171 for transmitting the traveling of the chain 12 to the rotating body 162.
[0038]
The clutch mechanism 171 includes a claw member 182 that is rotatably attached to the rotating body 162 via a shaft 181, an engagement pin 183 that is attached to the vertical frame 2 so that the claw member 182 is engaged, and a claw member An engaging projection 184 provided on the chain 12 is provided so as to abut against the engaging pin 182 and release the engaging member 182 from the engaging pin 183. The engaging member 182 is provided on the engaging pin 183. A claw portion 186 having an engaging recess 185 and an abutting portion 187 that abuts on the engaging projection 184 are integrally provided, and the abutting portion 187 of the engaging projection 184 is provided on the rotating body 162. A notch 188 that allows the engagement protrusion 184 to approach the contact portion 187 is formed. When the engagement protrusion 184 is brought into contact with the contact portion 187, the claw member 182 is rotated so that the engagement between the recess 185 of the claw portion 186 and the engagement pin 183 is released. Therefore, the rotating body 162 is rotated as the chain 12 travels, and the claw member 182 is rotated by releasing the contact of the engagement protrusion 184 with the contact portion 187, so that the recess of the claw portion 186 is rotated. When 185 and the engaging pin 183 are engaged with each other, the rotating body 162 is fixed to the vertical frame 2 via the engaging pin 183 and cannot be rotated.
[0039]
In the blind device 1, the connecting shaft 131 extends to the vertical frame 3 and is rotatably supported there. The end of the shaft 131 on the vertical frame 3 side is also the same as the sprocket wheel 53 and the rotating body 162. In addition, in the vertical frame 3, a chain similar to the chain 12 hung on the sprocket wheel, a link mechanism similar to the link mechanism 11, and a bending prevention means 14 for preventing the chain from being bent are provided. The same blocking means and the like are mounted, and therefore the other end (not shown) of each slat 7 is supported by each slat support mechanism (not shown) as described above. Therefore, the other end of each of the slats 7 is also raised and lowered in the same manner in synchronism with the one end by the rotation of the rotating shaft 104 as described below.
[0040]
In the above blind device 1, as shown in FIG. 8, when the link mechanisms 21 and 22 are extended, the slat 7 is tilted substantially vertically so as to completely close the opening 6 of the building. As shown in FIG. 11, the engagement protrusion 184 provided on the chain 12 is disposed in the notch 188 and is in contact with the contact portion 187 of the claw member 182.
[0041]
When the electric motor 81 is operated from this state, the sun gear 122 fixed to the input shaft 121 is rotated by the rotation of the output rotation shaft 85. Since the gear 124 cannot rotate due to the meshing between the worm 105 and the worm wheel 106, each planetary gear 123 is rotated around the sun gear 122 while rotating by the rotation of the sun gear 122. The output shaft 108 is rotated. The rotation of the output shaft 108 causes the rotation shaft 104 to rotate via the gears 109 and 110, and thus the sprocket wheel 53 rotates to cause the chain 12 to travel in the A direction.
[0042]
As the chain 12 travels in the A direction, the protrusion 184 is also moved counterclockwise about the rotation shaft 104, and the movement of the protrusion 184 causes the rotating body 162 to be rotated counterclockwise as shown in FIG. The rotation of the body 162 pulls the wire 169 upward, lowers the wire 170 downward, and thus the link mechanism 21 is lifted upward relative to the link mechanism 22 as shown in FIG. As a result, each of the arms 41 is rotated substantially horizontally, whereby each of the slats 7 is also rotated substantially horizontally to form a bowl shape.
[0043]
When the chain 12 further travels in the A direction, the protrusion 184 starts to be removed from the notch 188, and the protrusion 184 is then brought into contact with the claw portion 186 by the removal of the protrusion 184 from the notch 188. By rotating around the shaft 181, the recess 185 of the claw 186 and the engagement pin 183 are engaged with each other. As shown in FIG. 9, when the recess 185 of the claw portion 186 engages with the engagement pin 183, the rotation of the rotating body 162 is prevented and held in that state. By continuing the travel of the chain 12 in the A direction, the link mechanisms 21 and 22 connected to the chain 12 at the lower part by the connecting means 54 start to be folded, and this folding causes the link mechanisms 21 and 22 to slat support mechanism 27. The slats 7 attached via the are sequentially stacked from below. When all the slats 7 are overlapped, the operation of the electric motor 81 is stopped by a signal from a detector or the like, and the state where the opening 6 is completely opened is maintained.
[0044]
When the electric motor 81 is operated in the state in which the opening 6 is completely opened or in the middle of the opening, the chain 12 travels in the direction B, whereby the link mechanisms 21 and 22 are moved from above. The bundle of slats 7 starts to be unrolled from the upper slat 7 as it begins to extend. When the link mechanisms 21 and 22 are all extended and the slat 7 is also completely unsuperposed, the projection 184 begins to be inserted into the notch 188, as shown in FIG. In addition, the protrusion 184 contacts the contact portion 187 of the claw member 182 to rotate the claw member 182 to release the engagement of the recess 185 with the engagement pin 183. With this release, the protrusion 184 moves together. As shown in FIG. 11, the rotating body 162 is rotated clockwise in the reverse direction to that described above, the wire 170 is pulled upward, and the wire 169 is lowered downward, which causes relative displacement in the link mechanisms 21 and 22. Then, the slat 7 attached to the link mechanisms 21 and 22 via the slat support mechanism 27 is tilted in the opposite direction, and after being tilted at one end by this tilting, as shown in FIG. I would like to completely closed. Thereafter, the operation of the electric motor 81 is stopped by a signal from the detector or the like, and the state where the opening is completely closed is maintained.
[0045]
In the blind device 1, the operation of the electric motor 81 is not stopped immediately after the opening 6 is completely closed, and the other end 63 is connected to the one end 51 of the chain 12 even if the chain 12 further travels in the B direction. The arm 64 that is pivotally connected to the pin 64 rotates about the pin 75 against the elastic force of the spring 68 and moves directly with respect to the movable body 61 at one end 62 thereof. Therefore, there is no inconvenience that the fully extended link mechanisms 21 and 22 are further extended, and the slat 7 that is fully closed is further tilted. The link mechanisms 21 and 22 and the slats 7 can be prevented from being damaged, and the present invention is not limited to the case where a prohibition mechanism for prohibiting further downward movement of the movable body 61 in the state shown in FIG. It may eliminate cause excessive deflection of the chain 12, as occupying bring the guide walls 151 and 152 to the damage.
[0046]
The opening / closing operation of the normal opening 6 has been described above. First, the opening 6 in the event of an emergency such as a fire is opened by first pulling down the string-like body 93 by grasping the grip 92 and the spring spring 94. The winding of the string-like body 93 around the pulley 91 is alternately repeated. As a result, the shaft 89 is rotated via the pulley 91 and the gear 99 is rotated. The rotation of the gear 99 is transmitted to the gear 124 via the gear 113, the shaft 103, the worm 105 and the worm wheel 106. At this time, since the electric motor 81 is inactive, the output rotation shaft 85 is braked so as not to rotate.
[0047]
Therefore, the planetary gears 123 are rotated around the sun gear 122 while rotating by the rotation of the gears 124 to rotate the output shaft 108. The rotation of the output shaft 108 causes the rotation shaft 104 to rotate through the gears 109 and 110, and thus the sprocket wheel 53 rotates to cause the chain 12 to travel in the A direction. In the slat 7 lowered so as to close the opening 6 by the string-like body 93 being pulled down in the C direction a predetermined number of times, at least a predetermined number from the lower slat 7 is at least a predetermined distance, for example, a person can pass. Of about 650 mm.
[0048]
Thus, in the blind device 1, the both ends of the slats 7 can be synchronously pulled up by opening the string-like body 93 in the C direction a predetermined number of times to open the opening 6 by a certain amount. An emergency escape can be ensured.
[0049]
The blind device 1 of the present example is provided with a manual running force generating mechanism 82 for emergency escape as a manual running force generating means, but instead of the manual running force generating mechanism 82, as shown in FIG. A manual running force generation mechanism 201 for power failure can be attached.
[0050]
The manual running force generation mechanism 201 is operable by being hung on a shaft 205 rotatably supported on a case 204 via bearings 202 and 203, a pulley 2006 fixedly attached to the shaft 205, and a pulley 206. And a ball chain 207 as an endless string-like body hanging from the bottom. One end of the shaft 205 on the bearing 23 side protrudes from the case 204 to the outside, and the manual running force generation mechanism 201 is accommodated and mounted in the case 204.
[0051]
When the manual travel force generation mechanism 201 is used instead of the manual travel force generation mechanism 82, the screw 210 is first loosened, and one end of the shaft 89 is removed from the fitting recess 97 of the shaft 98, and the case 86 is removed. The manual running force generation mechanism 82 is removed from the main body case 84. Next, one end of the shaft 205 protruding outward from the case 204 is fitted into the fitting recess 102 formed on the bearing 100 side of the shaft 103, and the case 204 is attached to the main body case 84 with a screw.
[0052]
Thus, in the blind device 1 equipped with the manual running force generating mechanism 201, during a power failure, the ball chain 207 is gripped and moved downward in one direction, so that the pulley 206 and the shafts 205 and 103 are used. The worm 105 can be rotated in one direction, thereby raising the slat 7 and opening the opening 6, while conversely by lowering the ball chain 207 in the other direction and running. The worm 105 can be rotated in the other direction, so that the slat 7 can be lowered and the opening 6 can be closed.
[0053]
When the blind device 1 to which the manual travel force generation mechanism 201 is attached is changed to the blind device 1 to which the manual travel force generation mechanism 82 is attached, the same operation as described above may be performed. As is clear from the operation of the manual travel force generation mechanism 201 described above, the manual travel force generation mechanism 201 can also be used as a manual travel force generation mechanism for emergency escape.
[0054]
As described above, in the blind device 1, any of the manual running force generation mechanisms 82 and 201 can be easily attached without any particular design change according to the demand of the customer, and easily after the installation. Can be exchanged.
[0055]
【The invention's effect】
As described above, according to the present invention, the effect of the blind device proposed in Japanese Patent Application No. 8-165218 can be obtained as it is, and in addition to the one having an emergency escape function, the power failure opening function is also provided. Can be easily changed with little expense.
[Brief description of the drawings]
FIG. 1 is a perspective view of a preferred embodiment of the present invention.
FIG. 2 is an explanatory side view of the embodiment shown in FIG. 1;
3 is a partial explanatory view of the back surface of the embodiment shown in FIG. 1; FIG.
4 is an explanatory plan view of a vertical frame of the embodiment shown in FIG. 1; FIG.
FIG. 5 is a detailed explanatory view of the elastic means of the embodiment shown in FIG. 1;
6 is a detailed front view of the transmission means and the like of the embodiment shown in FIG.
7 is an explanatory side view of a manual running force generating mechanism for emergency escape of the embodiment shown in FIG. 1; FIG.
8 is an operation explanatory diagram of the embodiment shown in FIG. 1. FIG.
9 is an operation explanatory diagram of the embodiment shown in FIG. 1. FIG.
10 is an operation explanatory diagram of the embodiment shown in FIG. 1. FIG.
FIG. 11 is an operation explanatory diagram of the embodiment shown in FIG. 1;
12 is an explanatory side view when a manual running force generating mechanism for power failure is used instead of the emergency running manual running force generating mechanism of the embodiment shown in FIG. 1; FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Blind apparatus 6 Opening part 7 Slat 8 Elevating means 11 Link mechanism 12 Chain 13 Traveling apparatus 81 Electric motor 82 Manual traveling force generation mechanism 83 for emergency escape Transmission means

Claims (7)

A blind device comprising a large number of slats juxtaposed in an opening and an elevating means for elevating and lowering each slat, the elevating means being linked to both ends of each slat so as to support each slat And a traveling body connected to the link mechanism and a traveling device that causes the traveling body to travel so that the link mechanism expands and contracts by traveling, and the traveling device generates a traveling force on the traveling body. An electric motor, manual driving force generating means for generating a driving force for the traveling body by a manual pull-down operation, and transmission means for transmitting the driving force from the electric motor and the manual driving force generating means to the traveling body. As a manual running force generation means, either a manual running force generation mechanism for emergency escape or a manual running force generation mechanism for power failure can be selectively attached. By which, the manual driving force generating mechanism for the emergency escape includes a rotatable shaft, and one way clutch bearing mounted on the shaft, and a pulley mounted on the one-way clutch bearing, wrapped pulley The one-way clutch bearing is provided with a string-like body that is operably suspended and a spring spring having one end fixed on the rotation side and the other end fixed on the fixed side. The rotation of the pulley is transmitted to the shaft while the reverse rotation of the pulley due to the elastic force of the spring is not transmitted to the shaft. The spring is elastic to itself due to the rotation of the pulley by pulling down the string. Energy is stored, and the pulley is reversed by elastic energy stored by removing the pull-down force of the string-like body. A pulley mounted on the shaft, hung on the pulley, the blind apparatus which comprises a string-like body operably hanging down was endless.   Either the case with the manual running force generation mechanism for emergency escape or the case with the manual running force generation mechanism for power outage attached selectively to the body case with the transmission means The blind device according to claim 1, which is free. Transmission means, blind apparatus according to claim 1 or 2, comprising a rotatable shaft connectable to the axis of the driven traveling force generating mechanism for emergency escape. Transmission means, blind apparatus according to claim 1 or 2, comprising a universal shaft axis and connectable rotation of the manual driving force generating mechanism for power failure. The transmission means includes a large-diameter spur gear and a small-diameter spur gear meshed with the spur gear. The rotatable shaft of the large-diameter spur gear has a manual running force generating mechanism for emergency escape. The shaft and the rotatable shaft of the small-diameter spur gear are configured so as to be connectable to the shaft of the manual running force generating mechanism for power failure, respectively. The blind device according to any one of claims 1 to 4 , wherein the blind device is transmitted to a traveling body via a spur gear. The transmission means includes a worm wheel and a worm wheel meshed with the worm wheel so that transmission of the traveling force to the traveling body due to the operation of the electric motor to the manual traveling force generation means can be prohibited when the manual traveling force generation means is inactive. The worm wheel is rotated from either the electric motor or the manual travel force generating means, and the worm wheel is rotated from either the electric motor or the manual travel force generating means. blind apparatus according to any one of claims 1 adapted to be transmitted 5. The transmission means includes a planetary gear mechanism having a sun gear, a planetary gear meshing with the sun gear, and an internal gear meshing with the planetary gear, and the sun gear is connected to the output rotation shaft of the electric motor. The blind device according to claim 6 , wherein the internal gear is connected to the manual travel force generating means via the worm wheel and the worm, and the planetary gear is connected to the travel body.

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