JP6860641B2 - Roll screen - Google Patents

Description

The present invention relates to a roll screen that allows a double screen to be relatively movable in the vertical direction.

Conventionally, there is a roll screen in which the amount of light taken into the room can be adjusted by relatively moving the double-stacked screens in the vertical direction.

In such a roll screen, a transmitting portion that partially transmits light and a light-shielding portion that blocks light are alternately formed in a striped pattern, and the screen is suspended and supported in a state in which the screen is doubly overlapped. There is. Then, by operating the operating means, the front and rear screens are relatively moved in the vertical direction to adjust the degree of overlap between the transmissive portion and the light-shielding portion, whereby the amount of lighting can be adjusted.

For example, in order to facilitate the adjustment of the length of the screen, when one end is fixed to the take-up rod, the screen is hung down, folded back by the weight member, and the other end is fixed to the fixing member, inside the fixing member. A configuration for accommodating the length of the screen in an adjustable manner is disclosed (see, for example, Patent Document 1). In this configuration, there is a gap between the double screens so that they do not stick to each other.

On the other hand, a configuration is disclosed in which the screen can be smoothly raised and lowered while maintaining the double screen in close contact (see, for example, Patent Document 2).

JP-A-2009-79430 Japanese Patent No. 331 1994

In the technique disclosed in Patent Document 1 described above, a gap between the double screens is formed, and the double screens move relative to each other without friction during the raising and lowering operation, so that there is no risk of damaging the screens. It is valid. However, this technique has a problem that even if the transmissive portion and the light-shielding portion of the screen are matched with each other to provide a light-shielding state, light leaks from the gap of the screen and the light cannot be completely shielded.

On the other hand, in the technique disclosed in Patent Document 2, since the double screen is maintained in close contact with each other, light leaks from the gap between the screens when the transmissive portion and the light-shielding portion of the screen are brought into a light-shielding state. It is effective in that there is no risk. However, this technique has a problem that the screen may be damaged because the double screens are in close contact with each other and move relative to each other during the raising / lowering operation.

An object of the present invention is to provide a roll screen in which a double screen that can be relatively moved is relatively moved in the vertical direction in view of the above problems.

The roll screen of the present invention is a roll screen that allows a double screen to be relatively movable in the vertical direction, and the double screen is formed by folding one screen and attaching one side of the screen. A take-up pipe that is suspended and supported so that it can be taken up, and a fixing that attaches the other side of the screen that is folded back from the take-up pipe via a weight member and supports it above the take-up pipe. A means and an operating means for performing an operation for making the double screen relatively movable in the vertical direction are provided, and the operating means always operates a pendulum during an operation for making the double screen relatively movable in the vertical direction. The operation plate or operation unit to be operated is separated from the double screen configured to be relatively movable according to the pendulum operation, and is always separated during the operation when the operation plate or the operation unit is not operated in a stationary state without the pendulum operation. It is characterized by comprising a mechanism that operates closer or closer than the distance between the double screens.

Further, in the roll screen of the present invention, the operation plate or the operation unit in the operation means pendulums so that the interval at the time of operation of the double screen is larger than the interval at the time of rest.

Further, in the roll screen of the present invention, the operation plate or the operation unit in the operation means pendulums so that the double screens are brought into close contact with each other by their own weight when the operation is stopped and the operation is not performed. And.

Further, in the roll screen of the present invention, the double screen is characterized in that transmissive portions that partially transmit light and light-shielding portions that block light are alternately formed.

Further, in the roll screen of the present invention, the double screen is formed by folding back one screen, and a winding pipe that attaches one side of the screen and suspends and supports it so that it can be wound up, and the winding. The operation plate or operation unit in the operation means includes a support shaft that attaches and supports the other side of the screen that hangs down from the take-up pipe and is folded back via a weight member. It is characterized in that it operates as a pendulum so as to change the positional relationship between the take-up pipe and the support shaft.

Further, in the roll screen of the present invention, the operation plate or the operation unit in the operation means is engaged with the operation code for operating the opening / closing operation of the double screen, and the tensile force of the operation code during the operation causes the operation code. The operation plate or operation unit in the operation means is configured to have a force point that acts to rotate the double screen together with the support shaft in a direction in which the double screen is separated.

Further, in the roll screen of the present invention, the support shaft is provided on the indoor side below the take-up pipe.

Further, in the roll screen of the present invention, in the mechanism in the operating means , the distance between the double screens is separated according to the pendulum operation, and the distance between the double screens is always separated during the non-operation. characterized Rukoto configured as dough interval adjusting means operate on the other side of the screen so as to close or intimate contact than.

Further, in the roll screen of the present invention, the fabric spacing adjusting means includes movable fins that press the screens so that the double screens are spaced apart by the pendulum operation of the operating unit, and the movable fins are on the base axis thereof. It is characterized in that it is rotatably suspended from the fixing means.

Further, in the roll screen of the present invention, the movable fin has a length sufficient to close the gap between the fixing means and the winding means.

Further, in the roll screen of the present invention, the fabric spacing adjusting means includes a fixing bar that presses the screen so that the double screens are separated by the pendulum operation of the operating unit, and the fixing bar is the operating unit. It is characterized in that it is partially fixed.

Further, in the roll screen of the present invention, the operation unit is provided with a rotation regulating means for regulating the rotation range of the pendulum operation.

Further, in the roll screen of the present invention, the operation unit is characterized by having a code guide portion that guides the hanging of the operation code and supports the operation code so as to operate the pendulum.

Further, in the roll screen of the present invention, the operation unit has an operation code by a ball chain in which a plurality of ball portions are connected, and the code guide portion is always pressed by at least two continuous ball portions at a predetermined pitch. It is characterized in that it is configured to be in contact with and guided.

Further, in the roll screen of the present invention, the fixing means has a dough retainer whose length can be adjusted by winding an end portion of the screen, and a fixing portion for detachably locking the dough retainer. It is a feature.

According to the present invention, there is no risk of damaging the screen because the double screen does not rub during the ascending / descending operation, or even if it rubs, it moves partially during the ascending / descending operation, or the frictional force is reduced and moves relative to each other. .. Further, when the screen is stationary, the distance between the double screens can be brought close to or in close contact with each other. The sex can be improved.

It is a front view which shows the schematic structure of the roll screen of 1st Embodiment by this invention. It is a side view which shows the schematic structure of the roll screen of 1st Embodiment by this invention. It is an exploded perspective view which shows the schematic structure around the operation plate in the roll screen of 1st Embodiment by this invention. (A), (b), and (c) are operation explanatory views of the operation plate in the roll screen of the first embodiment according to the present invention. It is a front view which shows the schematic structure of the roll screen of the 2nd Embodiment by this invention. It is an exploded perspective view which shows the schematic structure around the operation plate in the roll screen of 2nd Embodiment by this invention. (A), (b), and (c) are operation explanatory views of the operation plate in the roll screen of the second embodiment according to the present invention. It is a front view which shows the schematic structure of the roll screen of 3rd Embodiment by this invention. It is an exploded perspective view which shows the schematic structure around the operation plate in the roll screen of 3rd Embodiment by this invention. (A), (b), and (c) are explanatory views of the operation of the operation plate in the roll screen of the third embodiment according to the present invention when the operation plate is stationary. (A) and (b) are operation explanatory views at the time of operation of the operation plate in the roll screen of 3rd Embodiment by this invention. (A) and (b) are explanatory views accompanied by a comparative example of the operation plate in the roll screen of the 3rd Embodiment of this invention. It is an exploded perspective view which shows the schematic structure around the operation plate in the roll screen of 4th Embodiment by this invention. (A), (b), and (c) are explanatory views of the operation of the operation plate in the roll screen of the fourth embodiment according to the present invention when the operation plate is stationary. It is a front view which shows the schematic structure of the roll screen of 5th Embodiment by this invention. It is a side view which shows the schematic structure of the roll screen of 5th Embodiment by this invention. It is an exploded perspective view which shows the schematic structure around the operation unit in the roll screen of 5th Embodiment by this invention. (A), (b), and (c) are operation explanatory views of the operation unit in the roll screen of the fifth embodiment according to the present invention. (A), (b), and (c) are operation explanatory views of the operation unit of the modified example for the roll screen of the fifth embodiment according to the present invention. It is a front view which shows the schematic structure of the roll screen of 6th Embodiment by this invention. It is an exploded perspective view which shows the schematic structure around the operation unit in the roll screen of 6th Embodiment by this invention. It is a front view which shows the schematic structure of the roll screen of 7th Embodiment by this invention. It is an exploded perspective view which shows the schematic structure around the operation unit in the roll screen of 7th Embodiment by this invention. (A), (b), and (c) are operation explanatory views of the operation unit in the roll screen of the seventh embodiment according to the present invention.

Hereinafter, the roll screen 1 of each embodiment according to the present invention will be described with reference to the drawings. In the specification of the present application, with respect to the front view of the roll screen 1 shown in FIG. 1 and the like, the upper side and the lower side of the drawing are upward (or upper) and lower (or lower), respectively, according to the hanging direction of the screen 4. The left side in the drawing is defined as the left side of the roll screen 1, and the right direction in the drawing is defined as the right side of the roll screen 1. Further, in the example described below, with respect to the front view of the roll screen 1 shown in FIG. 1, the side to be visually recognized is the front side (or the indoor side), and the opposite side is the rear side (or the outdoor side). When referred to as the front-rear direction, the direction perpendicular to the illustrated surface in the front view of FIG. 1 is referred to.

[First Embodiment]
First, the configuration of the roll screen 1 of the first embodiment according to the present invention will be described with reference to FIGS. 1 to 4. FIG. 1 is a front view showing a schematic configuration of the roll screen 1 of the first embodiment according to the present invention, and FIG. 2 is a side view showing a schematic configuration of the roll screen 1 of the first embodiment according to the present invention. FIG. 3 is an exploded perspective view showing a schematic configuration around the operation plate 6 in the roll screen 1 of the first embodiment according to the present invention. 4 (a), (b), and (c) are explanatory views of the operation of the operation plate 6 in the roll screen 1 of the first embodiment according to the present invention.

In the roll screen 1 shown in FIGS. 1 and 2, support members 2a and 2b are fixed to both ends of the mounting frame 2, and a fixed shaft 11 extending from the support members 2a and 2b forms a cylindrical shape between the support members 2a and 2b. The take-up pipe 9 is rotatably supported.

An operation pulley 10 is provided at the right end of the take-up pipe 9, and an endless operation cord 3 hung around the operation pulley 10 is hung. The take-up pipe 9 can be rotated by the operation of the operation code 3, and the surface of the operation pulley 10 on which the operation code 3 is hung has a highly frictional surface shape. The operation code 3 may be composed of a ball chain, and the surface of the operation pulley 10 on which the ball chain is hung may be configured to have irregularities having a shape suitable for the ball portion of the ball chain.

An operation plate 6 is provided between the support member 2a and the operation pulley 10 so as to be rotatable relative to the take-up pipe 9. Below the operation plate 6, one end of a cylindrical support shaft 7 extending between the support members 2a and 2b is attached. The specific configuration and operation of the operation plate 6 will be described in detail later.

Further, a support plate 8 is provided between the support member 2b and the left end portion of the take-up pipe 9 so as to be rotatable relative to the take-up pipe 9, and the support shaft 7 and other parts are provided below the support plate 8. The ends are attached. The shape of the support plate 8 of the present embodiment is substantially the same as the shape of the operation plate 6 except that the cord guide portions 12 and 13 described later are not provided. However, the outer shape of the support plate 8 may be different from the outer shape of the operation plate 6 as long as it can rotate relative to the take-up pipe 9 and the other end of the support shaft 7 is attached. Good.

The take-up pipe 9 is attached to one side of the screen 4 and is suspended and supported so that it can be taken up. The screen 4 that hangs down from the take-up pipe 9 and is folded back via a bottom rail 5 that functions as a weight member. The other side is attached to the support shaft 7. A roller 15 rotatably supported by both ends of the bottom rail 5 is inserted through the lower end of the screen 4 that hangs down between the take-up pipe 9 and the support shaft 7. Therefore, the screen 4 is stretched based on the weight of the bottom rail 5.

Then, when the operation code 3 is operated to rotate the winding pipe 9 in the screen winding direction, the bottom rail 5 rises, and when the winding pipe 9 is rotated in the screen rewinding direction, the bottom rail 5 descends.

Further, in the take-up pipe 9, a spring motor for reducing the operating force at the time of hoisting the screen 4 is housed on the left end side thereof, and a stopper device for preventing the weight of the screen 4 from dropping is housed on the right end side. Not shown).

In the screen 4, the transmitting portion 4b that partially transmits light and the light-shielding portion 4a that blocks light are alternately formed in a striped pattern, and the screen 4 is suspended and supported in a state in which the screen 4 is doubly overlapped. By operating the operation code 3, the front and rear screens 4 are relatively moved in the vertical direction to adjust the degree of overlap between the transmitting portion 4b and the light shielding portion 4a, so that the amount of light collected can be adjusted.

Next, with reference to FIGS. 1 and 2, a specific configuration of the operation plate 6 and its surroundings will be described. The operation pulley 10 is provided with a through hole for using the fixed shaft 11 extending from the support member 2a as a rotation shaft, and the winding pipe 9 is rotatably supported by the fixed shaft 11 as the operation pulley 10 rotates. .. Therefore, a fitting portion 25 that fits on the inner peripheral surface of the right end of the take-up pipe 9 is provided on the left end side of the operation pulley 10. Further, the left end portion of the operation pulley 10 is adapted to mesh with a gear mechanism connected to a stopper device housed in the take-up pipe 9 (not shown). This gear mechanism may be omitted if it is not necessary to increase or decrease the deceleration, and the take-up pipe 9 and the operation pulley 10 may be simply directly connected.

A substantially cylindrical rotation support portion 24 is provided at the right end portion of the operation pulley 10, and a round hole-shaped rotation receiving portion 23 having a diameter slightly larger than the rotation support portion 24 is provided on the operation plate 6. Has been done. Therefore, the operation plate 6 is rotatably supported with respect to the operation pulley 10 and the take-up pipe 9.

A hole 22 capable of supporting the support shaft 7 is provided below the operation plate 6. The support shaft 7 can be attached to one end of the support shaft 7 by a holding member 21 such as a rivet, and is held so as to extend between the support members 2a and 2b. The support shaft 7 may be rotatably attached to the operation plate 6 or may be non-rotatably attached. If a ratchet mechanism or the like that is rotatable and can be held at the rotating position is provided, the height of the bottom rail 5 in the lower limit state of the screen 4 can be finely adjusted.

It should be noted that the clockwise rotation of the operation plate 6 in FIG. 2 may be configured to prevent the relative rotation of a certain angle or more.

Further, the cord cover 20 is attached to a fixed member (not shown) fixed to the fixed shaft 11 (or support member 2a) so that the operation cord 3 hooked on the operation pulley 10 does not come off from the operation pulley 10 and does not slip. It is provided.

On the left end surface of the operation plate 6, two cord guide portions 12 and 13 extending in a columnar shape in the illustrated example are provided. The cord guide portion 12 guides one (front side) of the endless operation cord 3 hanging from the operation pulley 10 so as to hang from above the cord guide portion 12, and the cord guide portion 13 hangs from the operation pulley 10. The other end (rear side) of the endless operation cord 3 is guided so as to hang down from above the cord guide portion 13 and below the cord guide portion 12 (see FIG. 2).

The operation plate 6 configured in this way is configured to perform a pendulum operation so that the relative movable double screens 4 are separated from each other when the operation code 3 is operated. In particular, the operation plate 6 pendulums so that the positional relationship between the take-up pipe 9 and the support shaft 7 changes between when it is stationary and when it is operated. Then, the interval at the time of operation of the double screen 4 is configured to be larger than the interval at the time of rest.

More specifically, the operation of the operation plate 6 will be described with reference to FIG. First, referring to FIG. 4A, the operation plate 6 is supported so as to be relatively rotatable with respect to the operation pulley 10 and the take-up pipe 9, and the lower limit position, the intermediate position, and the upper limit position of the bottom rail 5 are respectively supported. When the screen is stationary, the operation plate 6 is in close contact with the front and rear screens 4 due to its own weight (the weight of the screen 4, the bottom rail 5, the operation plate 6, the support plate 8, and the support shaft 7), that is, in the front side (FIG. 4). Torque works (clockwise). The operation code 3 is hung with reference to the code guide units 12 and 13.

In this stationary state, when the bottom rail 5 is in the lower limit position, or when the screen 4 is wound around the take-up pipe 9 at the intermediate position and the upper limit position of the bottom rail 5 with a winding diameter R, the screen 4 is wound. The distance between the heavy screens 4 is stabilized at a position where they are close to each other or in close contact with each other (the distance between the double screens 4 d1). Therefore, it is possible to shift the transmissive portion 4b and the light-shielding portion 4a of the double screen 4 to make a semi-transparent state, or to make the transparent portion 4b and the light-shielding portion 4a of the screen 4 match to make a light-shielding state. In particular, it is possible to improve the light-shielding property when the light-shielding state is set. In the lower limit state, the upper end of the screen 4 is attached to the take-up pipe 9 and the support shaft 7 so that the hanging positions of the screen 4 on the take-up pipe 9 and the support shaft 7 overlap in the front-rear direction. , It is suitable for enhancing the light-shielding property of the double screen 4.

Next, referring to FIG. 4B, for example, when the operation code 3 is operated so as to raise the bottom rail 5 from the state where the bottom rail 5 is in the lower limit position or the intermediate position, the screen 4 is wound around the take-up pipe 9. Taken. At this time, when the operation code 3 comes into contact with the code guide portion 12 on the indoor side and a clockwise torque is applied to the operation plate 6, the operation plate 6 operates as a pendulum, and the interval d2 during operation of the double screen 4 is increased. , It is configured to be larger than the resting interval d1. Therefore, the double screen 4 does not rub during the ascending operation, or even if it rubs, it is partially moving up and down, or the frictional force is reduced and the screen 4 moves relative to each other, so that there is no risk of damaging the screen 4.

Similarly, referring to FIG. 4C, for example, when the operation code 3 is operated so as to lower the bottom rail 5 from the state where the bottom rail 5 is in the intermediate position or the upper limit position, the bottom rail 5 is wound around the take-up pipe 9. The screen 4 is lowered. At this time, when the operation code 3 comes into contact with the code guide portion 13 on the indoor side and a clockwise torque is applied to the operation plate 6, the operation plate 6 operates as a pendulum, and the interval d3 during operation of the double screen 4 is increased. , It is configured to be larger than the resting interval d1. Therefore, the double screen 4 does not rub during the lowering operation, or even if it rubs, it moves partially during ascending / descending, or the frictional force is reduced and the screen 4 moves relative to each other, so that there is no risk of damaging the screen 4. Even if friction occurs in a part of the screen 4 near the upper limit of the roll-up thickness, the frictional force acts in a direction of reducing the frictional force.

Therefore, according to the roll screen 1 of the first embodiment, the operation plate 6 is rotated by the tensile force of the operation code 3 during the ascending / descending operation, and the double screen 4 is separated without friction (or even if friction is rubbed). Is reduced), so that there is no risk of damaging the screen 4 (or it is reduced). Further, when stationary, the operation cord 3 loses tension, and the operation plate 6 rotates in the direction in which the double screen 4 approaches due to the weight of the screen 4 or the like. This makes it possible to improve the light-shielding property when the transmissive portion 4b and the light-shielding portion 4a of the screen 4 are brought into a light-shielding state.

[Second Embodiment]
Next, the configuration of the roll screen 1 of the second embodiment according to the present invention will be described with reference to FIGS. 5 to 7. FIG. 5 is a front view showing a schematic configuration of the roll screen 1 of the second embodiment according to the present invention, and FIG. 6 shows a schematic configuration around the operation plate 6 in the roll screen 1 of the second embodiment according to the present invention. It is an exploded perspective view. 7 (a), (b), and (c) are explanatory views of the operation of the operation plate 6 in the roll screen 1 of the second embodiment according to the present invention. The components that function in the same manner as in the first embodiment are designated by the same reference numbers.

The roll screen 1 of the second embodiment shown in FIG. 5 has substantially the same configuration as that of the first embodiment except that the forms of the support member 2a (and the support member 2b) and the operation plate 6 (and the support plate 8) are different. It has become. Therefore, in the following description, the support member 2a and the operation plate 6 of the second embodiment will be mainly described.

A specific configuration of the operation plate 6 of the second embodiment and its surroundings will be described with reference to FIG. At the right end of the take-up pipe 9, the take-up pipe 9 is rotatably supported with respect to the fixed shaft 11 extending from the support member 2a, as in the first embodiment. The operation pulley 10 is provided with a through hole for serving as a rotating shaft with respect to the fixed shaft 11. The take-up pipe 9 can rotate with the rotation of the operation pulley 10.

Similar to the first embodiment, a substantially columnar rotation support portion 24 is provided at the right end portion of the operation pulley 10. However, the operation plate 6 of the second embodiment is provided with an elongated hole-shaped rotation receiving portion 23 having a diameter larger than that of the rotation supporting portion 24. The elongated hole-shaped rotation receiving portion 23 is formed so as to straddle the fixed shaft 11 so as to be able to rotate relative to the support shaft 16 described later and to regulate the relative rotation so as not to rotate more than a certain angle. Has been done. The shape of the support plate 8 of the present embodiment is substantially the same as the shape of the operation plate 6 of the present embodiment, and the elongated hole-shaped rotation receiving portion 23 similar to the operation plate 6 of the present embodiment (shown). Is provided.

Further, in the operation plate 6 of the second embodiment, a rotation shaft 16 is inserted above the outdoor side so that the support shaft 16 extending from the support member 2a is used as a rotation shaft to perform the pendulum operation of the operation plate 6. A hole 27 is provided. Similarly, in the support plate 8, the rotation shaft hole portion 27 through which the support shaft 16 is inserted is inserted above the outdoor side so that the support shaft 16 extending from the support member 2b is used as the rotation shaft to perform the pendulum operation of the support plate 8. (Not shown) is provided. The operation plate 6 and the support plate 8 may be provided with the support shafts 16, and the support members 2a and 2b may be provided with the rotation shaft holes 27, respectively.

Therefore, the operation plate 6 and the support plate 8 of the second embodiment are wound with the operation pulley 10 in a state where the rotation range is restricted by the elongated hole-shaped rotation receiving portion 23 with the support shaft 16 as the rotation axis. It can rotate relative to the take pipe 9.

Above the operation plate 6, another component (not shown) provided with the cord cover 20 is provided on the fixed shaft 11 as in the first embodiment. The cord cover 20 may be attached to the support member 2a. A hole 22 capable of supporting the support shaft 7 is provided below the operation plate 6. The support shaft 7 can be attached to one end of the support shaft 7 by a holding member 21 such as a rivet, and is held so as to extend between the support members 2a and 2b. The support shaft 7 may be rotatably attached to the operation plate 6 or may be non-rotatably attached. If a ratchet mechanism or the like that is rotatable and can be held at the rotating position is provided, the height of the bottom rail 5 in the lower limit state of the screen 4 can be finely adjusted.

However, the operation plate 6 of the second embodiment is not provided with the two cord guide portions 12 and 13 as in the first embodiment. Instead, the support shaft 7 is arranged on the front side of the screen 4, and the operation code 3 passes through the back side of the support shaft 7. Therefore, in the present embodiment, the support shaft 7 is configured to have a function corresponding to the code guide portions 12 and 13 of the first embodiment. Further, a cord guide portion 14 is provided at the lower end portion of the support member 2a so that the hanging position of the operation cord 3 is on the front side. That is, the cord guide portion 14 guides the endless operation cord 3 hanging from the operation pulley 10 so as to be hung from above the cord guide portion 14 after being hung on the outdoor side of the support shaft 7 (FIG. FIG. 5). The shape of the support member 2b is almost the same as the shape of the support member 2a except that the cord guide portion 14 is not provided.

Therefore, the operation plate 6 of the second embodiment is also configured to perform a pendulum operation so that the relative movable double screens 4 are separated from each other when the operation code 3 is operated. In particular, the operation plate 6 pendulums so that the positional relationship between the take-up pipe 9 and the support shaft 7 changes between when it is stationary and when it is operated. Then, the interval at the time of operation of the double screen 4 is configured to be larger than the interval at the time of rest. The code guide unit 14 is not essential for the pendulum operation. Further, two cord guide portions 12 and 13 as in the first embodiment are provided on the front side of the screen 4 below the take-up shaft, and the operation code 3 is inserted through the back side of the cord guide portions 12 and 13, respectively. You may. The portion of the support shaft 7 with which the operation code 3 comes into contact may be a separate rotatable component to reduce resistance.

More specifically, the operation of the operation plate 6 of the second embodiment will be described with reference to FIG. 7. First, referring to FIG. 7A, the operation plate 6 is supported so as to be relatively rotatable with respect to the operation pulley 10 and the take-up pipe 9 with the support shaft 16 as the rotation axis, and the lower limit of the bottom rail 5 is formed. When stationary at the position, intermediate position, and upper limit position, the front and rear screens 4 are in close contact with the operation plate 6 due to their own weight (weight of screen 4, bottom rail 5, operation plate 6, support plate 8, and support shaft 7). Torque acts in the direction, that is, toward the front side (clockwise in FIG. 7). Then, the operation code 3 is hung with reference to the code guide portion 14 provided on the support member 2a.

In this stationary state, when the bottom rail 5 is in the lower limit position, or when the screen 4 is wound around the take-up pipe 9 at the intermediate position and the upper limit position of the bottom rail 5 with a winding diameter R, the screen 4 is wound. The distance between the heavy screens 4 is stabilized at a position where they are close to each other or in close contact with each other (the distance between the double screens 4 d1). Therefore, it is possible to shift the transmissive portion 4b and the light-shielding portion 4a of the double screen 4 to make a semi-transparent state, or to make the transparent portion 4b and the light-shielding portion 4a of the screen 4 match to make a light-shielding state. In particular, it is possible to improve the light-shielding property when the light-shielding state is set. In the lower limit state, the upper end of the screen 4 is attached to the take-up pipe 9 and the support shaft 7 so that the hanging positions of the screen 4 on the take-up pipe 9 and the support shaft 7 overlap in the front-rear direction. , It is suitable for enhancing the light-shielding property of the double screen 4.

Next, referring to FIG. 7B, for example, when the operation code 3 is operated so as to raise the bottom rail 5 from the state where the bottom rail 5 is in the lower limit position or the intermediate position, the screen 4 is wound around the take-up pipe 9. Taken. At this time, the operation plate 6 operates as a pendulum by applying torque to the support shaft 7 with the code guide portion 14 as a support shaft by the operation code 3, and the interval d2 during operation of the double screen 4 is the interval when stationary. It is configured to be larger than d1. Therefore, the double screen 4 does not rub during the ascending operation, or even if it rubs, it is partially moving up and down, or the frictional force is reduced and the screen 4 moves relative to each other, so that there is no risk of damaging the screen 4.

Similarly, referring to FIG. 7C, for example, when the operation code 3 is operated so as to lower the bottom rail 5 from the state where the bottom rail 5 is in the intermediate position or the upper limit position, the bottom rail 5 is wound around the take-up pipe 9. The screen 4 is lowered. At this time, the operation plate 6 operates as a pendulum by applying torque to the support shaft 7 with the code guide portion 14 as a support shaft by the operation code 3, and the interval d3 during operation of the double screen 4 is the interval when stationary. It is configured to be larger than d1. Therefore, the double screen 4 does not rub during the lowering operation, or even if it rubs, it moves partially during ascending / descending, or the frictional force is reduced and the screen 4 moves relative to each other, so that there is no risk of damaging the screen 4.

Therefore, according to the roll screen 1 of the second embodiment, the operation plate 6 is rotated by the tensile force of the operation code 3 during the ascending / descending operation, and the double screen 4 is separated without friction (or even if friction is rubbed). Is reduced), so that there is no risk of damaging the screen 4. Further, when stationary, the operation cord 3 loses tension, and the operation plate 6 rotates in the direction in which the double screen 4 approaches due to the weight of the screen 4 or the like. This makes it possible to improve the light-shielding property when the transmissive portion 4b and the light-shielding portion 4a of the screen 4 are brought into a light-shielding state.

In particular, according to the roll screen 1 of the second embodiment, the installation space of the front-rear width of the roll screen 1 determined in consideration of the pendulum operation of the operation plate 6 can be reduced as compared with the first embodiment. Further, by providing the cord guide portion 14, the operation plate 6 and the support plate 8 can be rotated in the separation direction by pulling the operation cord 3 downward.

[Third Embodiment]
Next, the configuration of the roll screen 1 according to the third embodiment of the present invention will be described with reference to FIGS. 8 to 12. FIG. 8 is a front view showing a schematic configuration of the roll screen 1 of the third embodiment according to the present invention, and FIG. 9 shows a schematic configuration around the operation plate 6 in the roll screen 1 of the third embodiment according to the present invention. It is an exploded perspective view. 10 (a), (b), and (c) are explanatory views of the operation of the operation plate 6 in the roll screen 1 of the third embodiment according to the present invention. 11 (a) and 11 (b) are explanatory views of the operation of the operation plate 6 in the roll screen 1 of the third embodiment according to the present invention. 12 (a) and 12 (b) are explanatory views accompanied by a comparative example of the operation plate 6 in the roll screen 1 of the third embodiment according to the present invention. The components that function in the same manner as in the first embodiment are designated by the same reference numbers.

The roll screen 1 of the third embodiment shown in FIG. 8 is different from that of the first embodiment except that the modes of the operation pulley 10, the support member 2a (and the support member 2b), and the operation plate 6 (and the support plate 8) are different. It has almost the same structure. Therefore, in the following description, the support member 2a and the operation plate 6 of the third embodiment will be mainly described.

A specific configuration of the operation plate 6 of the third embodiment and its surroundings will be described with reference to FIG. At the right end of the take-up pipe 9, the take-up pipe 9 is rotatably supported with respect to the fixed shaft 11 extending from the support member 2a, as in the first embodiment. The operation pulley 10 is provided with a through hole for serving as a rotating shaft with respect to the fixed shaft 11. The take-up pipe 9 can rotate with the rotation of the operation pulley 10.

The operation plate 6 of the third embodiment has an elongated shape, is arranged between the operation pulley 10 and the support member 2a on the outdoor side so as to avoid the fixed shaft 11, and is a support extending from the support member 2a. A rotating shaft hole 27 through which the support shaft 16 is inserted is provided so that the operation plate 6 can perform the pendulum operation with the shaft 16 as the rotating shaft. Similar to the first embodiment, a hole 22 for attaching one end of the support shaft 7 extending between the support members 2a and 2b by the holding member 21 such as a rivet is provided below the operation plate 6. ..

The support plate 8 of the present embodiment also has substantially the same shape as the operation plate 6 of the present embodiment. The support shaft 7 may be rotatably attached to the operation plate 6 and the support plate 8 or may be non-rotatably attached. Further, the operation plate 6 and the support plate 8 may be provided with the support shaft 16, and the support members 2a and 2b may be provided with the rotation shaft hole portion 27, respectively.

The operation plate 6 and the support plate 8 of the third embodiment can rotate relative to the operation pulley 10 and the take-up pipe 9 with the support shaft 16 as the rotation axis. The position of the pendulum operation is determined by the weight of the screen 4 or the like located at the lower end of the screen 4 suspended and supported by the support shaft 7 and the take-up pipe 9.

In the operation plate 6 and the support plate 8 of the third embodiment configured in this way, the support shaft 16 is used as a rotation axis, and the operation pulley 10 and the take-up pipe 9 are operated by a pendulum operation by the weight of the screen 4 or the like. It can rotate relative to each other.

A cord cover 20 is arranged above the support member 2a so that the operation cord 3 that hangs on the operation pulley 10 does not come off (not shown). The cord cover 20 may be composed of a separate component fixed to the fixed shaft 11.

The operation plate 6 of the third embodiment is not provided with the two cord guide portions 12 and 13 as in the first embodiment. Instead, the support shaft 7 is arranged on the front side of the screen 4, and the operation code 3 passes through the back side of the support shaft 7. Therefore, in the present embodiment, the support shaft 7 is configured to have a function corresponding to the code guide portions 12 and 13 of the first embodiment. Further, a cord guide portion 14 is provided at the lower end portion of the support member 2a so that the hanging position of the operation cord 3 is on the front side. That is, the cord guide portion 14 guides the endless operation cord 3 hanging from the operation pulley 10 so as to be hung from above the cord guide portion 14 after being hung on the outdoor side of the support shaft 7 (FIG. FIG. 8). The shape of the support member 2b is almost the same as the shape of the support member 2a except that the cord guide portion 14 is not provided.

Therefore, the operation plate 6 of the third embodiment is also configured to perform a pendulum operation so that the relative movable double screens 4 are separated from each other when the operation code 3 is operated. In particular, the operation plate 6 pendulums so that the positional relationship between the take-up pipe 9 and the support shaft 7 changes between when it is stationary and when it is operated. Then, the interval at the time of operation of the double screen 4 is configured to be larger than the interval at the time of rest.

More specifically, the operation of the operation plate 6 of the third embodiment will be described with reference to FIGS. 10 to 12. First, referring to FIG. 10A, the operation plate 6 is rotatably supported with respect to the operation pulley 10 and the take-up pipe 9 with the support shaft 16 as a rotation axis, and is supported by the lower limit of the bottom rail 5. When the position is stationary, the operation plate 6 is in close contact with the front and rear screens 4 due to its own weight (the weight of the screen 4, the bottom rail 5, the operation plate 6, the support plate 8, and the support shaft 7), that is, toward the front side (FIG. Torque works (clockwise at 11). Then, the operation code 3 is hung with reference to the code guide portion 14 provided on the support member 2a.

When the bottom rail 5 is at the lower limit position and is stationary, the distance between the double screens 4 is stabilized at a position where the distance between the double screens 4 is close to or close to each other (the distance between the double screens 4 is d1). Therefore, it is possible to shift the transmissive portion 4b and the light-shielding portion 4a of the double screen 4 to make a semi-transparent state, or to make the transparent portion 4b and the light-shielding portion 4a of the screen 4 match to make a light-shielding state. In particular, it is possible to improve the light-shielding property when the light-shielding state is set. In the lower limit state, the upper end of the screen 4 is attached to the take-up pipe 9 and the support shaft 7 so that the hanging positions of the screen 4 on the take-up pipe 9 and the support shaft 7 overlap in the front-rear direction. , It is suitable for enhancing the light-shielding property of the double screen 4.

Further, referring to FIG. 10B, when the bottom rail 5 is at an intermediate position and is stationary, the bottom rail 5 is wound around the take-up pipe 9 so as to move from the lower limit position to the upper limit position. The winding diameter R of the screen 4 is increased, and the position of the screen 4 suspended by the weight of the screen 4 or the like shifts to the outdoor side, but at a predetermined height, the space between the double screens 4 is brought close to or in close contact with each other. The position does not change (interval d1'≈ d1 of the double screen 4). Therefore, when the screen 4 is lowered below the intermediate position, the transmissive portion 4b and the light-shielding portion 4a of the double screen 4 are shifted to be in a semi-transparent state, and the transmissive portion 4b and the light-shielding portion 4a of the screen 4 are arranged. Can be matched to create a light-shielding state, and in particular, the light-shielding property can be improved when the light-shielding state is set.

Further, referring to FIG. 10C, the winding diameter R of the screen 4 wound around the winding pipe 9 is expanded to the maximum when the bottom rail 5 is stationary when the bottom rail 5 is in the upper limit position. The position of the screen 4 suspended by the weight of the screen 4 or the like further shifts to the outdoor side, but even in this state, the position of the double screen 4 is stabilized at a position where the distance between the double screens 4 is close. However, it should be noted that in this state, since the screen 4 itself is in the open state, there is no practical problem regarding the proximity of the double screen 4 at rest.

Next, referring to FIG. 11A, for example, when the operation code 3 is operated so as to raise the bottom rail 5 from the state where the bottom rail 5 is in the lower limit position, the screen 4 is wound around the take-up pipe 9. At this time, the operation plate 6 operates as a pendulum by applying torque to the support shaft 7 with the code guide portion 14 as a support shaft by the operation code 3, and the interval d2 during operation of the double screen 4 is the interval when stationary. It is configured to be larger than d1. Therefore, the double screen 4 does not rub during the ascending operation, or even if it rubs, it is partially moving up and down, or the frictional force is reduced and the screen 4 moves relative to each other, so that there is no risk of damaging the screen 4.

Similarly, referring to FIG. 11B, for example, when the operation code 3 is operated so as to lower the bottom rail 5 from the state where the bottom rail 5 is in the intermediate position or the upper limit position, the bottom rail 5 is wound around the take-up pipe 9. The screen 4 is lowered. At this time, the operation plate 6 operates as a pendulum by applying torque to the support shaft 7 with the code guide portion 14 as a support shaft by the operation code 3, and the interval d3 during operation of the double screen 4 is the interval when stationary. It is configured to be larger than d1. Therefore, the double screen 4 does not rub during the lowering operation, or even if it rubs, it moves partially during ascending / descending, or the frictional force is reduced and the screen 4 moves relative to each other, so that there is no risk of damaging the screen 4.

Here, in order to explain the points to be noted regarding the pendulum operation in the operation plate 6 of the third embodiment, the position of the support shaft 16 of the operation plate 6 is different from that of the present embodiment shown in FIG. 12 (a). A comparative example in which the fixed shaft 11 is arranged closer to the fixed shaft 11 is shown in FIG. 12 (b). In the present embodiment shown in FIG. 12A, the double screen 4 is formed by the weight of the screen 4 or the like suspended and supported by the support shaft 7 and the take-up pipe 9 when the bottom rail 5 is stationary at the lower limit position. The distance between the screens is stabilized at a position where the screens are close to each other or in close contact with each other (the distance between the double screens 4 d1).

On the other hand, in the comparative example shown in FIG. 12B, since the support shaft 16 is arranged closer to the fixed shaft 11, the distance D (D> d1) between the double screens 4 becomes large, which is not preferable. Therefore, the preferred position of the support shaft 16 depends on the diameter of the support shaft 7 and the take-up pipe 9 and the distance between the support shaft 7 and the take-up pipe 9, but the distance between the double screens 4 is large. It is preferable to set the lower limit position of the bottom rail 5 as a reference when the bottom rail 5 is stationary so as to be close to or in close contact with each other.

Therefore, according to the roll screen 1 of the third embodiment, the operation plate 6 is rotated by the tensile force of the operation code 3 during the ascending / descending operation, and the double screen 4 is separated without friction (or even if friction is rubbed). Is reduced), so that there is no risk of damaging the screen 4. Further, when stationary, the operation cord 3 loses tension, and the operation plate 6 rotates in the direction in which the double screen 4 approaches due to the weight of the screen 4 or the like. This makes it possible to improve the light-shielding property when the transmissive portion 4b and the light-shielding portion 4a of the screen 4 are brought into a light-shielding state.

In particular, according to the roll screen 1 of the third embodiment, since the support shaft 7 is arranged inside the room and has a plate structure that swings downward inside the room, the roll screen 1 is determined in consideration of the pendulum operation of the operation plate 6. The front-rear width installation space can be reduced as compared with the first embodiment.

[Fourth Embodiment]
Next, the configuration of the roll screen 1 of the fourth embodiment according to the present invention will be described as a modification of the first embodiment with reference to FIGS. 13 to 14. FIG. 13 is an exploded perspective view showing a schematic configuration around the operation plate 6 in the roll screen 1 of the fourth embodiment according to the present invention. 14 (a), (b), and (c) are explanatory views of the operation of the operation plate 6 in the roll screen 1 of the first embodiment according to the present invention. The components that function in the same manner as in the first embodiment are given the same reference numbers.

The roll screen 1 shown in FIGS. 13 and 14 is first implemented except that a take-up gear mechanism (drive gear 31, transmission gear 32, driven gear 33) is provided between the operation plate 6 and the operation pulley 10. It has the same configuration as the form. Therefore, in the following description, the operation plate 6, the operation pulley 10, and the take-up gear mechanism (drive gear 31, transmission gear 32, driven gear 33) of the third embodiment will be mainly described.

A specific configuration of the operation plate 6 of the fourth embodiment and its surroundings will be described with reference to FIG. At the right end of the take-up pipe 9, the take-up pipe 9 is rotatably supported with respect to the fixed shaft 11 extending from the support member 2a, as in the first embodiment. The operation pulley 10 is provided with a through hole for serving as a rotating shaft with respect to the fixed shaft 11. The take-up pipe 9 can rotate with the rotation of the operation pulley 10.

A drive gear 31 that rotates with the rotation of the operation pulley 10 is fixed to the right end portion of the operation pulley 10, and a substantially cylindrical rotation support portion 24 is provided at the right end portion thereof as in the first embodiment. ing. The operation plate 6 is provided with a round hole-shaped rotation receiving portion 23 having a diameter slightly larger than that of the rotation supporting portion 24. Therefore, the operation plate 6 is supported so as to be relatively rotatable with respect to the fixed shaft 11, the operation pulley 10, and the take-up pipe 9.

A driven gear 33 for rotating the support shaft 7 is provided at the right end of the support shaft 7 extending between the support members 2a and 2b, and the driven gear 33 is operated by the holding member 21 such as a rivet. A hole 22 for rotatably supporting the operation plate 6 is provided in the operation plate 6.

A transmission gear 32 that transmits the rotation of the drive gear 31 to the driven gear 33 is rotatably attached to the operation plate 6. The transmission gear 32 is configured to transmit the rotation of the drive gear 31 to the driven gear 33.

Therefore, if the take-up pipe 9 is the first take-up shaft with respect to the screen 4, the support shaft 7 functions as the second take-up shaft with respect to the screen 4. Further, the diameter of the first take-up shaft is larger than the diameter of the second take-up shaft. The number of teeth of the drive gear 31 and the driven gear 33 is the same, and the second take-up shaft rotates by the same amount as the rotation of the first take-up shaft. Therefore, the winding length of the screen 4 per unit rotation of the first winding shaft and the winding length of the screen 4 per unit rotation of the second winding shaft are different. When the operation code 3 is pulled and the operation pulley 10 is rotated in the winding direction, the first winding shaft rotates and winds up the screen 4, and the second winding shaft also winds up the screen 4 and the bottom rail 5 Rise. During ascending, the ascending speeds of the front screen 4 wound on the first winding shaft and the rear screen 4 wound on the second winding shaft are different (rotation of the first winding shaft> first. (Rotation of the winding shaft of 2), a state in which the light-shielding portion 4a and the transmission portion 4b overlap and a state in which the light-shielding portion 4a and the light-shielding portion 4b overlap each other appear alternately. The same applies when rewinding. In the lower limit state of the screen 4, the light-shielding portion 4a and the transmissive portion 4b overlap each other to provide a light-shielding state.

Even in the operation plate 6 of the fourth embodiment configured in this way, when the operation code 3 is operated, the pendulum operation is performed so that the distance between the double screens 4 that can be moved relative to each other is separated. In particular, the operation plate 6 pendulums so that the positional relationship between the take-up pipe 9 and the support shaft 7 changes between when it is stationary and when it is operated. Then, the interval at the time of operation of the double screen 4 is configured to be larger than the interval at the time of rest.

More specifically, the operation of the operation plate 6 will be described with reference to FIG. First, referring to FIG. 14A, the operation plate 6 is supported so as to be relatively rotatable with respect to the operation pulley 10 and the take-up pipe 9, and the lower limit position, the intermediate position, and the upper limit position of the bottom rail 5 are respectively supported. When stationary, the operation plate 6 is in close contact with the front and rear screens 4 due to its own weight (weight of screen 4, bottom rail 5, operation plate 6, support plate 8, and support shaft 7), that is, in the front side (FIG. 14). Torque works (clockwise). The operation code 3 is hung with reference to the code guide units 12 and 13.

In this example, in the stationary position when the bottom rail 5 is in the lower limit position, the screen 4 is set in a state where it is not wound by the take-up pipe 9 and the support shaft 7, and the distance between the double screens 4 is close. Alternatively, it is stabilized at a position where it is brought into close contact (interval d1 between the double screens 4). In the lower limit state, the upper end of the screen 4 is attached to the take-up pipe 9 and the support shaft 7 so that the hanging positions of the screen 4 on the take-up pipe 9 and the support shaft 7 overlap in the front-rear direction. , It is suitable for enhancing the light-shielding property of the double screen 4.

Then, even when the screen 4 is wound around the take-up pipe 9 and the support shaft 7 at the intermediate position and the upper limit position of the bottom rail 5 with the take-up diameters R1 and R2, respectively, the interval between the double screens 4 Is stabilized at a position where they are close to each other or in close contact with each other. In the fourth embodiment, since the take-up gear mechanism (drive gear 31, transmission gear 32, driven gear 33) is provided, the take-up pipe 9 and the support shaft 7 have screens 4 with take-up diameters R1 and R2, respectively. By winding, the adhesion of the double screen 4 is increased from the lower limit position to the upper limit position of the bottom rail 5.

Therefore, it is possible to shift the transmissive portion 4b and the light-shielding portion 4a of the double screen 4 to make a semi-transparent state, or to make the transparent portion 4b and the light-shielding portion 4a of the screen 4 match to make a light-shielding state. In particular, it is possible to improve the light-shielding property when the light-shielding state is set.

Next, referring to FIG. 14B, for example, when the operation code 3 is operated so as to raise the bottom rail 5 from the state where the bottom rail 5 is in the lower limit position or the intermediate position, the take-up pipe 9 and the support shaft 7 are affected. The screen 4 is wound up. At this time, the operation plate 6 operates as a pendulum by applying torque to the code guide portion 12 by the operation code 3, and the interval d2 at the time of operation of the double screen 4 is configured to be larger than the interval d1 at the time of rest. There is. Therefore, even if there is a relative movement due to the difference in the ascending speed of the front and rear screens 4, the double screens 4 do not rub during the ascending operation, or even if they rub, they are partially or a frictional force during ascent and descent. Is reduced and moves relative to each other, so that there is no risk of damaging the screen 4.

Similarly, referring to FIG. 14C, for example, when the operation code 3 is operated so as to lower the bottom rail 5 from the state where the bottom rail 5 is in the intermediate position or the upper limit position, the take-up pipe 9 and the support shaft 7 are affected. The screen 4 that has been wound down is lowered. At this time, the operation plate 6 operates as a pendulum by applying torque to the code guide portion 13 by the operation code 3, and the interval d3 at the time of operation of the double screen 4 is configured to be larger than the interval d1 at the time of rest. There is. Therefore, even if there is a relative movement due to the difference in the lowering speed of the front and rear screens 4, the double screens 4 do not rub during the lowering operation, or even if they rub, they are partially moving up and down, or frictional force. Is reduced and moves relative to each other, so that there is no risk of damaging the screen 4.

Therefore, during the ascending / descending operation, the operation plate 6 is rotated by the tensile force of the operation code 3, the double screen 4 is separated, and the screen 4 is moved relative to each other without friction (or even if friction is reduced). There is no risk of damaging. Further, when stationary, the operation cord 3 loses tension, and the operation plate 6 rotates in the direction in which the double screen 4 approaches due to the weight of the screen 4 or the like. This makes it possible to improve the light-shielding property when the transmissive portion 4b and the light-shielding portion 4a of the screen 4 are brought into a light-shielding state.

In particular, according to the roll screen 1 of the fourth embodiment, since the take-up gear mechanism (drive gear 31, transmission gear 32, driven gear 33) is provided, the take-up diameter R1 is provided on the take-up pipe 9 and the support shaft 7, respectively. By winding the screen 4 on R2, the adhesion of the double screen 4 is increased from the lower limit position to the upper limit position of the bottom rail 5.

Further, even with the above-described configuration alone, it is possible to switch between a state in which the light-shielding portions 4a and the transmissive portions 4b on the front and rear screens 4 overlap each other and a state in which the light-shielding portions 4a (or the transmissive portions 4b) on the front and rear screens 4 overlap each other. However, by adding the following configuration, the amount of vertical movement of the bottom rail 5 at the time of switching can be reduced. Regarding the take-up gear mechanism (drive gear 31, transmission gear 32, driven gear 33), the transmission portion 4b and the light-shielding portion of the double screen 4 are changed from the light-shielding state in which the transmission portion 4b and the light-shielding portion 4a of the screen 4 are matched. An idling device for idling the amount of rotation corresponding to the moving distance until the semitransparent state is achieved by shifting the 4a may be further provided on either one or both of the drive gear 31 and the driven gear 33. For details of such an idling device, refer to, for example, Japanese Patent Application Laid-Open No. 2012-77501.

Although the present invention has been described above with reference to examples of specific embodiments, the present invention is not limited to the examples of the above-described embodiments, and various modifications can be made without departing from the technical idea.

For example, as a modification of the first embodiment, an example in which a take-up gear mechanism (drive gear 31, transmission gear 32, driven gear 33) is provided to form the fourth embodiment has been described, but the second embodiment or the third embodiment has been described. As a modification of the embodiment, the techniques of each embodiment may be combined and applied to form a form in which the take-up gear mechanism is provided.

Further, when the take-up gear mechanism is provided as a modification of the second embodiment or the third embodiment, it is also possible to configure the idling device to be provided.

Further, in the example of each of the above-described embodiments, as a double screen 4 in which one screen is folded back, a transmitting portion 4b that partially transmits light and a light shielding portion 4a that blocks light are alternately formed in a striped pattern. Although the example described above has been described, the operation plate 6 according to the present invention has a double screen even if it is not a single screen or a mode in which the transmission portions 4b and the light shielding portions 4a are alternately formed. If there is, the operation plate 6 is rotated by the tensile force of the operation code 3 during the ascending / descending operation, and the double screen 4 is separated from each other. It is effective in that it is reduced and can be moved relative to each other.

Further, various shapes such as the outer shapes of the support members 2a and 2b, the operation plate 6 and the support plate 8, and the shapes of the cord guide portions 12, 13 and 14 can be formed as long as the actions and effects of the present invention are produced. ..

Further, in each embodiment, the mode in which the support plate 8 also operates the pendulum along with the pendulum operation of the operation plate 6 has been described, but the techniques of each embodiment are combined and applied, and the operation plate 6 is stationary by the pendulum operation only. It is also possible that the distance between the double screens, which are sometimes close to each other or in close contact with each other, is separated during operation. For example, by combining the first embodiment and the second embodiment (or the fourth embodiment or a modification thereof), the support member 2b is provided with a guide hole for moving the end portion of the support shaft 7 without providing the support plate 8. The movement guide hole is configured to guide the end of the support shaft 7 that moves with the pendulum movement of the operation plate 6 while preferably having a rotation regulation function, whereby only the operation plate 6 is provided. With the pendulum operation of, the distance between the double screens that were close to each other or in close contact with each other at rest can be separated at the time of operation.

Further, a wall portion (cover) that rises upward from the support shaft 7 may be provided to prevent light leakage between the take-up pipe 9 and the mounting frame 2 / ceiling side mounting surface.

[Fifth Embodiment]
Next, the configuration of the roll screen 1 according to the fifth embodiment of the present invention will be described with reference to FIGS. 15 to 18. In each of the above-described embodiments, an example in which the other side of the screen 4 having one side attached to the take-up pipe 9 is attached to the support shaft 7 has been described, but in this embodiment, one side is attached to the take-up pipe 9. The other side of the screen 4 is an example of attaching to the fixing portion 2c provided on the outdoor end surface of the mounting frame 2. FIG. 15 is a front view showing a schematic configuration of the roll screen 1 of the fifth embodiment according to the present invention, and FIG. 16 is a side view showing the schematic configuration of the roll screen 1 of the fifth embodiment according to the present invention. FIG. 17 is an exploded perspective view showing a schematic configuration around the operation unit 60 in the roll screen 1 of the fifth embodiment according to the present invention. 18 (a), (b), and (c) are explanatory views of the operation of the operation unit 60 in the roll screen 1 of the fifth embodiment according to the present invention. The same reference numbers are assigned to the same components as those in the above-described embodiments.

In the roll screen 1 shown in FIGS. 15 and 16, the support members 2a and 2b are fixed to both ends of the mounting frame 2, and the fixed shafts 11 extending from the support members 2a and 2b form a cylindrical shape between the support members 2a and 2b. The take-up pipe 9 is rotatably supported.

At the right end of the take-up pipe 9, an operation unit 60 that can rotate relative to the take-up pipe 9 and the support members 2a and 2b is provided. Further, an operation pulley 10 is housed in the operation unit 60, and an endless operation code 3 hung around the operation pulley 10 is hung down. The take-up pipe 9 can be rotated by the operation of the operation code 3, and the surface of the operation pulley 10 on which the operation code 3 is hung has a highly frictional surface shape. The operation code 3 may be composed of a ball chain, and the surface of the operation pulley 10 on which the ball chain is hung may be configured to have irregularities having a shape suitable for the ball portion of the ball chain. The specific configuration and operation of the operation unit 60 will be described in detail later.

The take-up pipe 9 is attached to one side of the screen 4 and is suspended and supported so that it can be taken up. The screen 4 that hangs down from the take-up pipe 9 and is folded back via a bottom rail 5 that functions as a weight member. The other side is attached to a fixing portion 2c provided on the outdoor end surface of the mounting frame 2 located above the take-up pipe 9. For example, the fixing portion 2c can be configured to detachably lock the fabric retainer anchored to the end portion of the screen 4 by welding or the like. A roller 15 rotatably supported at both ends of the bottom rail 5 is inserted through the lower end of the screen 4 that hangs down between the take-up pipe 9 and the fixing portion 2c. As a result, the screen 4 is stretched based on the weight of the bottom rail 5.

Therefore, when the operation code 3 is operated to rotate the take-up pipe 9 in the screen winding direction, the bottom rail 5 rises, and when the take-up pipe 9 is rotated in the screen rewind direction, the bottom rail 5 lowers.

Further, in the take-up pipe 9, a spring motor for reducing the operating force when hoisting the screen 4 is housed on the left end side thereof, and a stopper device for preventing the screen 4 from dropping its own weight is housed on the right end side (the right end side thereof). Not shown).

In the screen 4, the transmitting portion 4b that partially transmits light and the light-shielding portion 4a that blocks light are alternately formed in a striped pattern, and the screen 4 is suspended and supported in a state in which the screen 4 is doubly overlapped. By operating the operation code 3, the front and rear screens 4 are relatively moved in the vertical direction to adjust the degree of overlap between the transmitting portion 4b and the light shielding portion 4a, so that the amount of light collected can be adjusted.

Next, a specific configuration of the operation unit 60 and its surroundings will be described with reference to FIGS. 15 and 16. The operation unit 60 is composed of two operation plate members 6a and 6b in which the operation pulley 10 and the cord cover 20 are sandwiched and integrated so as to be accommodated inside. The operation plate member 6b is provided with protruding cord guide portions 12 and 13 that stand upright toward the operation plate member 6a. The endless operation cord 3 hung from the operation pulley 10 is guided by the cord guide portions 12 and 13 and hangs downward. The cord cover 20 is fixed to the support member 2a. The cord cover 20 may be in any form as long as the operation cord 3 hooked on the operation pulley 10 is provided so as not to come off the operation pulley 10 and cause slippage. For example, the operation unit 60 as shown in the figure. In addition to the form of accommodating inside, the form of being fixed to the fixed shaft 11 or the support member 2a can be used.

The cord guide portions 12 in this example are provided at two locations above the cord guide portion 13, and one (front side) of the endless operation cord 3 hanging from the operation pulley 10 is the cord guide portion 12 (front side). One (rear side) of the endless operation cord 3 which is guided to hang down between the cord guide portion 13 and the cord guide portion 13 and hangs down from the operation pulley 10 is the cord guide portion 12 (rear side) and the cord guide portion 13. You will be guided to hang down through the space (see FIG. 16).

The operation pulley 10 is provided with a through hole for using the fixed shaft 11 extending from the support member 2a as a rotation shaft, and the winding pipe 9 is rotatably supported by the fixed shaft 11 as the operation pulley 10 rotates. .. Therefore, a fitting portion 25 that fits on the inner peripheral surface of the right end of the take-up pipe 9 is provided on the left end side of the operation pulley 10. Further, the left end portion of the operation pulley 10 is adapted to mesh with a gear mechanism connected to a stopper device housed in the take-up pipe 9 (not shown). This gear mechanism may be omitted if it is not necessary to increase or decrease the deceleration, and the take-up pipe 9 and the operation pulley 10 may be simply directly connected.

The operation plate member 6a is provided with a round hole-shaped rotation receiving portion 23a whose diameter is larger than the outer diameter of the edge frame of the operation pulley 10, and the operation plate member 6b is larger than the outer diameter of the take-up pipe 9. A half-round hole-shaped rotation receiving portion 23b having a diameter is provided. Therefore, the operation unit 60 is rotatably supported with respect to the operation pulley 10 and the take-up pipe 9. Further, a recess 20a is provided above the cord cover 20 fixed to the support member 2a, and a substantially inverted trapezoidal protruding piece 61 is provided above the operation plate member 6a. When the two operation plate members 6a and 6b are integrated by sandwiching the operation pulley 10 and the cord cover 20 inside so as to be accommodateable, the protruding piece 61 is engaged with the recess 20a within a predetermined rotation range. It is composed. Further, a step portion 20b that regulates the relative rotation of the operation unit 60 within a certain angle is provided on the inner wall of the upper protruding piece of the cord cover 20 that can accommodate the operation plate member 6b inside. That is, the step portion 20b can come into contact with the edge portions 26 on both upper ends of the cord guide portion 12 of the operation plate member 6b when the operation unit 60 is relatively rotated. Therefore, the relative rotation of the operation unit 60 is regulated within a certain angle by the contact between the edge portion 26 and the step portion 20b.

On the other hand, on the mounting frame 2 whose both ends are fixed by the support members 2a and 2b, a substantially spear-shaped movable fin 40 is rotatably suspended from the base shaft at the outdoor end portion on the bottom surface thereof. Since the screen 4 hangs down from the fixing portion 2c provided on the outdoor end surface of the mounting frame 2, the movable fin 40 causes the protruding piece 61 of the operating plate member 6a to rotate relative to the operating unit 60. When pressed by the side end portion, the movable fin 40 rotates so that the screen 4 on the outdoor side moves further to the outdoor side.

The operation unit 60 configured in this way is configured to perform a pendulum operation so that the relative movable double screens 4 are separated from each other when the operation code 3 is operated. Then, the interval at the time of operation of the double screen 4 is configured to be larger than the interval at the time of rest.

More specifically, the operation of the operation unit 60 will be described with reference to FIG. First, referring to FIG. 18A, the operation unit 60 is supported so as to be relatively rotatable with respect to the operation pulley 10 (and the take-up pipe 9), and the lower limit position, the intermediate position, and the upper limit position of the bottom rail 5 are supported. At each stationary state, torque acts on the operation unit 60 in the direction in which the front and rear screens 4 are in close contact with each other due to their own weight (weight of the screen 4, bottom rail 5, etc.). As a result, the operation code 3 is hung with reference to the code guide units 12 and 13.

In this stationary state, when the bottom rail 5 is in the lower limit position, or when the screen 4 is wound around the take-up pipe 9 at a predetermined winding diameter at the intermediate position and the upper limit position of the bottom rail 5. The space between the double screens 4 is stabilized at a position where they are close to each other or in close contact with each other (the space between the double screens 4 d1). Therefore, it is possible to shift the transmissive portion 4b and the light-shielding portion 4a of the double screen 4 to make a semi-transparent state, or to make the transparent portion 4b and the light-shielding portion 4a of the screen 4 match to make a light-shielding state. In particular, it is possible to improve the light-shielding property when the light-shielding state is set.

Next, referring to FIG. 18B, for example, when the operation code 3 is operated so as to raise the bottom rail 5 from the state where the bottom rail 5 is in the lower limit position or the intermediate position, the screen 4 is wound around the take-up pipe 9. Taken. At this time, when the operation code 3 comes into contact with the code guide portion 12 on the indoor side and a clockwise torque is applied to the operation unit 60, the operation unit 60 operates as a pendulum, and the side end portion of the protruding piece 61 of the operation plate member 6a. Rotates the movable fin 40 and presses the screen 4 on the outdoor side. Therefore, the interval d2 at the time of operation of the double screen 4 is configured to be larger than the interval d1 at the time of rest. Therefore, the double screen 4 does not rub during the ascending operation, or even if it rubs, it is partially moving up and down, or the frictional force is reduced and the screen 4 moves relative to each other, so that there is no risk of damaging the screen 4.

Similarly, referring to FIG. 18C, for example, when the operation code 3 is operated so as to lower the bottom rail 5 from the state where the bottom rail 5 is in the intermediate position or the upper limit position, the bottom rail 5 is wound around the take-up pipe 9. The screen 4 is lowered. At this time, the operation code 3 comes into contact with the code guide portion 13 on the indoor side, and a clockwise torque is applied to the operation unit 60, so that the operation unit 60 operates as a pendulum, and the side end portion of the protruding piece 61 of the operation plate member 6a. Rotates the movable fin 40 and presses the screen 4 on the outdoor side. Therefore, the interval d3 when the double screen 4 is operated is configured to be larger than the interval d1 when the double screen 4 is stationary. Therefore, the double screen 4 does not rub during the lowering operation, or even if it rubs, it moves partially during ascending / descending, or the frictional force is reduced and the screen 4 moves relative to each other, so that there is no risk of damaging the screen 4. Even if friction occurs in a part of the screen 4 near the upper limit of the roll-up thickness, the frictional force acts in a direction of reducing the frictional force.

Therefore, according to the roll screen 1 of the fifth embodiment, the operation unit 60 is rotated by the tensile force of the operation code 3 during the ascending / descending operation, and the double screen 4 is separated without friction (or even if friction is rubbed). Is reduced), so that there is no risk of damaging the screen 4 (or it is reduced). Further, when stationary, the operation code 3 loses tension, and the operation unit 60 rotates in the direction in which the double screen 4 approaches due to the weight of the screen 4 or the like. This makes it possible to improve the light-shielding property when the transmissive portion 4b and the light-shielding portion 4a of the screen 4 are brought into a light-shielding state.

Here, the forms of the operation plate members 6a and 6b and the cord cover 20 constituting the operation unit 60 may be other forms as long as they have the functions of providing the above-mentioned actions, for example, as shown in FIG. 19 (a), (b), and (c) are operation explanatory views of the operation unit 60 of the modified example with respect to the roll screen 1 of the fifth embodiment according to the present invention. In the example shown in FIG. 19, the operation unit 60 is provided with code guide units 12 and 13 one by one. Further, a rotation restricting shaft 63 is provided on the protruding piece 61 of the operation plate member 6a, and the relative rotation of the operating unit 60 is constant by the rotation restricting groove 62 provided on the protruding piece extending above the cord cover 20. It is configured to regulate within an angle. The rotation restricting groove 62 may be provided in the protruding piece 61 of the operation plate member 6a, and the rotation restricting shaft 63 may be provided on the protruding piece extending above the cord cover 20. When it is not necessary to regulate within a certain angle, it is not necessary to provide a mechanism for regulating the relative rotation of the operation unit 60.

The operation of the modified example shown in FIG. 19 will be described. First, referring to FIG. 19A, the operation unit 60 is supported so as to be relatively rotatable with respect to the operation pulley 10 (and the take-up pipe 9), and the lower limit position, the intermediate position, and the upper limit position of the bottom rail 5 are supported. At each stationary state, torque acts on the operation unit 60 in the direction in which the front and rear screens 4 are in close contact with each other due to their own weight (weight of the screen 4, bottom rail 5, etc.). As a result, the operation code 3 is hung with reference to the code guide units 12 and 13.

In this stationary state, when the bottom rail 5 is in the lower limit position, or when the screen 4 is wound around the take-up pipe 9 at a predetermined winding diameter at the intermediate position and the upper limit position of the bottom rail 5. Stabilize at a position where the intervals between the double screens 4 are close to each other or in close contact with each other (interval between the double screens 4 d1).

Next, referring to FIG. 19B, for example, when the operation code 3 is operated so as to raise the bottom rail 5 from the state where the bottom rail 5 is in the lower limit position or the intermediate position, the screen 4 is wound around the take-up pipe 9. Taken. At this time, when the operation code 3 comes into contact with the code guide portion 12 on the indoor side and a clockwise torque is applied to the operation unit 60, the operation unit 60 operates as a pendulum, and the side end portion of the protruding piece 61 of the operation plate member 6a. Rotates the movable fin 40 and presses the screen 4 on the outdoor side. Therefore, the interval d2 at the time of operation of the double screen 4 becomes larger than the interval d1 at the time of rest.

Similarly, referring to FIG. 18C, for example, when the operation code 3 is operated so as to lower the bottom rail 5 from the state where the bottom rail 5 is in the intermediate position or the upper limit position, the bottom rail 5 is wound around the take-up pipe 9. The screen 4 is lowered. At this time, the operation code 3 comes into contact with the code guide portion 13 on the indoor side, and a clockwise torque is applied to the operation unit 60, so that the operation unit 60 operates as a pendulum, and the side end portion of the protruding piece 61 of the operation plate member 6a. Rotates the movable fin 40 and presses the screen 4 on the outdoor side. Therefore, the interval d3 when the double screen 4 is operated becomes larger than the interval d1 when the double screen 4 is stationary.

Therefore, also in the example shown in FIG. 19, the operation unit 60 is rotated by the tensile force of the operation code 3 during the ascending / descending operation, the double screen 4 is separated, and friction is reduced without friction (or even if friction is performed). ) Since it moves relative to each other, there is no risk of damaging the screen 4 (or it is reduced). Further, when stationary, the operation code 3 loses tension, and the operation unit 60 rotates in the direction in which the double screen 4 approaches due to the weight of the screen 4 or the like. This makes it possible to improve the light-shielding property when the transmissive portion 4b and the light-shielding portion 4a of the screen 4 are brought into a light-shielding state.

[Sixth Embodiment]
Next, the configuration of the roll screen 1 of the sixth embodiment according to the present invention will be described with reference to FIGS. 20 and 21. In the sixth embodiment, as in the fifth embodiment, the other side of the screen 4 having one side attached to the take-up pipe 9 is attached to the fixing portion 2c provided on the outdoor end surface of the mounting frame 2. .. FIG. 20 is a front view showing a schematic configuration of the roll screen 1 of the sixth embodiment according to the present invention, and FIG. 21 shows a schematic configuration around the operation unit 60 in the roll screen 1 of the sixth embodiment according to the present invention. It is an exploded perspective view. The same reference numbers are assigned to the same components as those in the above-described embodiments.

In the sixth embodiment, as compared with the fifth embodiment, the support plate 8 is provided at the left end of the take-up pipe 9, the movable fin 60 is not provided on the mounting frame 2, and the solid bar 50 is the operation unit. The difference is that it is fixed between the 60 and the support plate 8.

As shown in FIG. 20, support members 2a and 2b are fixed to both ends of the mounting frame 2, and a cylindrical winding pipe 9 is provided between the support members 2a and 2b by a fixed shaft 11 extending from the support members 2a and 2b. It is rotatably supported.

At the right end of the take-up pipe 9, an operation unit 60 that can rotate relative to the take-up pipe 9 and the support members 2a and 2b is provided as in the fifth embodiment. Further, an operation pulley 10 is housed in the operation unit 60, and an endless operation code 3 hung around the operation pulley 10 is hung down. Then, the take-up pipe 9 can be rotated by the operation of the operation code 3.

The take-up pipe 9 is attached to one side of the screen 4 and is suspended and supported so that it can be taken up. The screen 4 that hangs down from the take-up pipe 9 and is folded back via a bottom rail 5 that functions as a weight member. The other side is attached to the fixing portion provided on the outdoor end surface of the mounting frame 2 as in the fifth embodiment. A roller 15 rotatably supported at both ends of the bottom rail 5 is inserted through the lower end of the screen 4 that hangs down between the take-up pipe 9 and the fixed portion. As a result, the screen 4 is stretched based on the weight of the bottom rail 5.

Therefore, when the operation code 3 is operated to rotate the take-up pipe 9 in the screen winding direction, the bottom rail 5 rises, and when the take-up pipe 9 is rotated in the screen rewind direction, the bottom rail 5 lowers.

Further, in the take-up pipe 9, a spring motor for reducing the operating force when hoisting the screen 4 is housed on the left end side thereof, and a stopper device for preventing the screen 4 from dropping its own weight is housed on the right end side (the right end side thereof). Not shown).

In the screen 4, the transmitting portion 4b that partially transmits light and the light-shielding portion 4a that blocks light are alternately formed in a striped pattern, and the screen 4 is suspended and supported in a state in which the screen 4 is doubly overlapped. By operating the operation code 3, the front and rear screens 4 are relatively moved in the vertical direction to adjust the degree of overlap between the transmitting portion 4b and the light shielding portion 4a, so that the amount of light collected can be adjusted.

Next, with reference to FIG. 21, a specific configuration of the operation unit 60 and its surroundings will be described. The operation unit 60 of the sixth embodiment is the same as that of the fifth embodiment except for the shape of the protruding piece 61 of the operation plate member 6a.

The protruding piece 61 of the operation plate member 6a is formed in a shape extending outward in a substantially F shape, and one end of the solid bar 50 is attached to the tip end portion thereof. The support plate 8 provided between the take-up pipe 9 and the support member 2b is configured to have a projecting piece having a shape substantially similar to that of the operation plate member 6a, and the projecting piece of the support plate 8 is formed with a solid bar 50 and others. The ends are attached (see FIG. 20).

Since the screen 4 hangs down from the fixing portion provided on the outdoor end surface of the mounting frame 2, the take-up pipe is located rearward from the protruding piece 61 of the operation plate member 6a due to the relative rotation of the operation unit 60. The solid bar 50 extending substantially parallel to 9 is displaced, and the solid bar 50 presses the outdoor screen 4 to move further to the outdoor side.

Therefore, also in the sixth embodiment, the same actions and effects as those in the fifth embodiment can be produced, and the operation unit 60 has a space between the double screens 4 that can be moved relative to each other when the operation code 3 is operated. It is configured to pendulum to move away. Then, the interval at the time of operation of the double screen 4 is configured to be larger than the interval at the time of rest.

In particular, in the examples of the fifth and sixth embodiments, as compared with the examples of the first to fourth embodiments, it is not necessary to provide the support shaft 7 below the take-up pipe 9, so that the front and rear of the roll screen 1 are used. It is possible to avoid increasing the width of the direction. Further, in the examples of the first to fourth embodiments, since the support shaft 7 is provided on the operation plate 6 that operates the pendulum and the operation plate 6 is configured to rotate relative to each other, the rotation angle accompanying the pendulum operation is large. However, in the examples of the fifth and sixth embodiments, the operation unit 60 is operated by the pendulum without increasing the rotation angle, and the interval at the time of operation of the double screen 4 is the interval at the time of rest. It can be configured to be larger.

More specifically, in the examples of the fifth and sixth embodiments, the movable fins assist the operation of the double screen 4 to be larger than the stationary interval according to the pendulum operation of the operation unit 60. By providing the fabric spacing adjusting means such as the 40 and the fixed bar 50, the width of the roll screen 1 including the operation unit 60 accompanied by the pendulum operation in the front-rear direction can be further reduced.

[7th Embodiment]
Next, the configuration of the roll screen 1 according to the seventh embodiment of the present invention will be described with reference to FIGS. 22 to 24. The roll screen 1 of the seventh embodiment is composed of substantially the same components as the roll screen 1 of the fifth embodiment, but includes a mounting frame 2, a support member 2a, a cord cover 20, movable fins 40, and an operation unit 60. The shape of the operation code 3 composed of the ball chain and the operation pulley 10 thereof is different from that of the fifth embodiment.

FIG. 22 is a front view showing a schematic configuration of a roll screen according to a seventh embodiment of the present invention. FIG. 23 is an exploded perspective view showing a schematic configuration around the operation unit 60 in the roll screen 1 of the seventh embodiment according to the present invention. In addition, FIGS. 24 (a), 24 (b), and 24 (c) are operation explanatory views of the operation unit 60 in the roll screen 1 of the seventh embodiment according to the present invention. The same reference numbers are assigned to the components similar to those in the fifth embodiment.

As shown in FIG. 22, in the roll screen 1 of the seventh embodiment, the support members 2a and 2b are fixed to both ends of the mounting frame 2 as in the fifth embodiment, and the fixed shafts extending from the support members 2a and 2b are fixed. A cylindrical take-up pipe 9 is rotatably supported between the support members 2a and 2b by the 11.

At the right end of the take-up pipe 9, an operation unit 60 that can rotate relative to the take-up pipe 9 and the support members 2a and 2b is provided. Further, an operation pulley 10 is housed in the operation unit 60, and an endless operation code 3 hung around the operation pulley 10 is hung down. Then, the take-up pipe 9 can be rotated by the operation of the operation code 3. The operation code 3 is composed of an endless ball chain composed of a ball portion 3a and a chain portion 3b that are continuous at a predetermined pitch, and the surface of the operation pulley 10 has irregularities having a shape suitable for the ball portion 3a. It is composed.

The take-up pipe 9 is attached to one side of the screen 4 and is suspended and supported so that it can be taken up. The screen 4 that hangs down from the take-up pipe 9 and is folded back via a bottom rail 5 that functions as a weight member. The other side is attached to a fixing portion 2c provided on the outdoor end surface of the mounting frame 2 located above the take-up pipe 9. As shown in FIG. 24, the fixing portion 2c according to the present embodiment is configured to wrap the end portion of the screen 4 and detachably lock the fabric retainer 80 whose length can be adjusted. .. A roller 15 rotatably supported at both ends of the bottom rail 5 is inserted through the lower end of the screen 4 that hangs down between the take-up pipe 9 and the fixing portion 2c. As a result, the screen 4 is stretched based on the weight of the bottom rail 5.

Therefore, when the operation code 3 is operated to rotate the take-up pipe 9 in the screen winding direction, the bottom rail 5 rises, and when the take-up pipe 9 is rotated in the screen rewind direction, the bottom rail 5 lowers.

Further, in the take-up pipe 9, a spring motor for reducing the operating force when hoisting the screen 4 is housed on the left end side thereof, and a stopper device for preventing the screen 4 from dropping its own weight is housed on the right end side (the right end side thereof). Not shown).

In the screen 4, the transmitting portion 4b that partially transmits light and the light-shielding portion 4a that blocks light are alternately formed in a striped pattern, and the screen 4 is suspended and supported in a state in which the screen 4 is doubly overlapped. By operating the operation code 3, the front and rear screens 4 are relatively moved in the vertical direction to adjust the degree of overlap between the transmitting portion 4b and the light shielding portion 4a, so that the amount of light collected can be adjusted.

Next, with reference to FIG. 22, a specific configuration of the operation unit 60 and its surroundings will be described with reference to FIG. The operation unit 60 is composed of two operation plate members 6a and 6b in which the operation pulley 10 and the cord cover 20 are sandwiched and integrated so as to be accommodated inside. The operation unit 60 is provided with code guide units 12 and 13.

The code guide portion 12 of the present embodiment will be described in detail. The operation plate member 6b having a substantially V-shaped overall shape has a fixed shaft 11 facing the operation plate member 6a from an end portion in the front-rear direction thereof. A side piece projecting in the axial direction is formed, and an engaging piece 12a is formed in a part of this side piece. The operation plate member 6a also has side pieces 12c protruding in the axial direction facing the operation plate member 6b from the end portions in the front-rear direction, and the side pieces 12c are the engagement pieces 12a of the operation plate member 6b. Can be engaged with. A fitting convex portion 12d is provided on the side piece 12c of the operation plate member 6a, and a fitting receiving portion 12b that can be fitted with the fitting convex portion 12d is formed on the engaging piece 12a of the operation plate member 6b. Has been done. Therefore, when the operation pulley 10 and the cord cover 20 are sandwiched inside so that the operation plate members 6a and 6b are integrated, the side piece 12c of the operation plate member 6a engages with the engagement piece 12a of the operation plate member 6b. By fitting the fitting convex portion 12d and the fitting receiving portion 12b, the side piece protruding from the operation plate member 6b and the side piece 12c protruding from the operation plate member 6a are integrated to form the present embodiment. Code guide unit 12 is configured.

Further, to explain the code guide portion 13 of the present embodiment in detail, the shaft of the fixed shaft 11 facing the operation plate member 6a to form the cord guide portion 13 from the lower surface of the operation plate member 6b on the center side. A vertically long protrusion that protrudes in the direction is formed upright. The surface 13a of the vertically long protrusion (the surface facing the operation plate member 6b) is in contact with and engageable with the engagement groove 13b provided on the lower surface of the operation plate member 6a on the central side. Therefore, when the operation pulley 10 and the cord cover 20 are sandwiched inside so that the operation plate members 6a and 6b are integrated, the surface 13a of the vertically long protrusion on the operation plate member 6b becomes the engagement groove on the operation plate member 6a. Engaging with 13b, the code guide portion 13 of the present embodiment is configured. A screw hole 13c is formed in the engagement groove 13b of the operation plate member 6a, and a screw hole (not shown) similar to the screw hole 13c is formed on the surface 13a of the vertically long protrusion of the operation plate member 6b. It is provided. Then, the operation plate members 6a and 6b can be integrated and fixed through these screw holes by the mounting screws 70 to form the operation unit 60. Instead of fixing the lower ends of the operation plate members 6a and 6b with the mounting screws 70, the lower ends of the operation plate members 6a and 6b may be fitted. Alternatively, the shapes of the fitting convex portion 12d and the fitting receiving portion 12b may be optimized or the number may be increased in order to stabilize the integration of the operation plate members 6a and 6b.

The endless operation cord 3 hung from the operation pulley 10 is guided by the cord guide portions 12 and 13 and hangs downward. In particular, the code guide units 12 in the seventh embodiment are provided at two locations on the front and rear sides of the code guide unit 13 so as to sandwich the code guide unit 13, and between the code guide unit 12 and the code guide unit 13 on the front side. A guide path slightly larger than the outer shape of the ball portion 3a of the operation cord 3 is formed between the cord guide portion 12 and the cord guide portion 13 on the rear side, and the endless operation cord hangs down from the operation pulley 10. One side (front side) of 3 is guided to hang down between the cord guide portion 12 (front side) and the cord guide part 13, and one endless operation cord 3 (rear side) hangs down from the operation pulley 10. Is guided to hang down between the cord guide portion 12 (rear side) and the cord guide portion 13 (see FIG. 24).

Further, a guide slightly larger than the outer shape of the ball portion 3a of the operation code 3 between the front side code guide unit 12 and the code guide unit 13 and between the rear side code guide unit 12 and the code guide unit 13. The path is formed so that at least two consecutive ball portions 3a at a predetermined pitch are always in contact with either one of the cord guide portions 12 and 13. With this configuration, rattling in the operation unit 60 during operation of the operation code 3 is suppressed, and the operation sound that may occur due to interference between the ball unit 3a and the code guide units 12 and 13 is reduced. Can be done.

As shown in FIG. 23, the cord cover 20 mainly has a flange-shaped main body having a tubular portion having an insertion hole 20d as a base axis, and an upper protruding piece protruding from the upper edge of the main body in the axial direction of the fixed shaft 11. It is configured to prevent the operation cord 3 hanging around the operation pulley 10 from coming off, and is fixed to the support member 2a so as not to rotate. In this example, the fixed shaft 11 is formed in the shape of a square bar, and the fixed shaft 11 is inserted into the insertion hole 20d and engaged with the fixed shaft 11 so that the cord cover 20 can be non-rotatably fixed to the support member 2a. There is. However, the cord cover 20 may be in any form as long as the operation cord 3 hooked on the operation pulley 10 is provided so as not to come off the operation pulley 10 and cause slippage.

The operation pulley 10 is provided with a through hole for using the fixed shaft 11 extending from the support member 2a as a rotation shaft. Further, a protrusion formed in a tubular shape is formed on the right end side of the operation pulley 10 (not shown), and this protrusion is formed with an engaging groove 20c provided around the insertion hole 20d of the cord cover 20. By engaging, it is non-rotatably supported by the cord cover 20 and the support member 2a. On the left end side of the operation pulley 10, a fitting portion 25 that fits into the inner peripheral surface of the right end of the take-up pipe 9 is provided via a flange whose diameter is larger than the outer circumference on which the operation cord 3 is mounted. Therefore, the take-up pipe 9 is rotatably supported as the operation pulley 10 rotates. Further, the left end portion of the operation pulley 10 is adapted to mesh with a gear mechanism connected to a stopper device housed in the take-up pipe 9 (not shown). This gear mechanism may be omitted if it is not necessary to increase or decrease the deceleration, and the take-up pipe 9 and the operation pulley 10 may be simply directly connected.

On the other hand, a protrusion having a tubular protrusion is formed on the right end side of the cord cover 20 (not shown), and the operation plate member 6a has an outer diameter of the protrusion so as to engage with the protrusion. A round hole-shaped rotation receiving portion 23a having a larger diameter is provided. The operation plate member 6b is provided with a semi-round hole-shaped rotation receiving portion 23b whose diameter is larger than the outer diameter of the take-up pipe 9. Further, a recess 20a is provided in the upper protruding piece on the right end side of the cord cover 20 fixed to the support member 2a, and a substantially inverted trapezoidal protruding piece 61 is provided above the operation plate member 6a. .. The protruding piece 61 of this example has substantially the same thickness as the width in the left-right direction of the operating unit 60, and the lower surface of the protruding piece 61 is supported along the upper surface of the cord cover 20, whereby the operating pulley 10 and the take-up pipe are supported. The relative rotation of the operation unit 60 with respect to 9 is stabilized. Therefore, the operation unit 60 is rotatably supported with respect to the operation pulley 10 and the take-up pipe 9.

Then, in a state where the two operation plate members 6a and 6b are integrated by sandwiching the operation pulley 10 and the cord cover 20 inside so as to be accommodated, the protruding piece 61 engages with the recess 20a within a predetermined rotation range. It is configured to do. Further, a step portion 20b that regulates the relative rotation of the operation unit 60 within a certain angle is provided on the inner wall of the upper protruding piece on the left end side of the cord cover 20 that can accommodate the operation plate member 6b inside. .. That is, the step portion 20b can come into contact with the edge portions 26 on both upper ends of the cord guide portion 12 of the operation plate member 6a when the operation unit 60 is relatively rotated. Therefore, the relative rotation of the operation unit 60 is regulated within a certain angle by the contact between the edge portion 26 and the step portion 20b.

On the other hand, on the mounting frame 2 whose both ends are fixed by the support members 2a and 2b, a substantially spear-shaped movable fin 40 is rotatably suspended from the base shaft at the outdoor end portion on the bottom surface thereof. The movable fin 40 of the seventh embodiment is configured to be longer so that there is no gap between the mounting frame 2 and the take-up pipe 9 as compared with the fifth embodiment, and the inside is lightened to maintain the strength. However, it is lighter. The movable fin 40 configured in this way can further shield external light that may be incident from the gap between the mounting frame 2 and the take-up pipe 9, and the weight reduction makes the movable fin 40 related to the pendulum operation. The load for the displacement of 40 can be reduced. Since the screen 4 hangs down from the fixing portion 2c provided on the outdoor end surface of the mounting frame 2, the movable fin 40 causes the protruding piece 61 of the operating plate member 6a to rotate relative to the operating unit 60. When pressed by the side end portion, the movable fin 40 rotates so that the screen 4 on the outdoor side moves further to the outdoor side.

The operation unit 60 configured in this way is configured to perform a pendulum operation so that the relative movable double screens 4 are separated from each other when the operation code 3 is operated. Then, the interval at the time of operation of the double screen 4 is configured to be larger than the interval at the time of rest.

More specifically, the operation of the operation unit 60 will be described with reference to FIG. 24. First, referring to FIG. 24A, the operation unit 60 is supported so as to be relatively rotatable with respect to the operation pulley 10 (and the take-up pipe 9), and the lower limit position, the intermediate position, and the upper limit position of the bottom rail 5 are supported. At each stationary state, torque acts on the operation unit 60 in the direction in which the front and rear screens 4 are in close contact with each other due to their own weight (weight of the screen 4, bottom rail 5, etc.). As a result, the operation code 3 is hung with reference to the code guide units 12 and 13.

In this stationary state, when the bottom rail 5 is in the lower limit position, or when the screen 4 is wound around the take-up pipe 9 at a predetermined winding diameter at the intermediate position and the upper limit position of the bottom rail 5. The space between the double screens 4 is stabilized at a position where they are close to each other or in close contact with each other (the space between the double screens 4 d1). Therefore, it is possible to shift the transmissive portion 4b and the light-shielding portion 4a of the double screen 4 to make a semi-transparent state, or to make the transparent portion 4b and the light-shielding portion 4a of the screen 4 match to make a light-shielding state. In particular, it is possible to improve the light-shielding property when the light-shielding state is set. In particular, the fixing portion 2c of the mounting frame 2 of the present embodiment is configured to wind the end portion of the screen 4 and detachably lock the fabric retainer 80 whose length can be adjusted, for example. The structure is such that it is easy to adjust the length of the screen 4 so that the bottom rail 5 is in a shielded state when it is in the lower limit position. Further, the elongated movable fin 40 can further shield external light that may be incident from the gap between the mounting frame 2 and the take-up pipe 9.

Next, referring to FIG. 24B, for example, when the operation code 3 is operated so as to raise the bottom rail 5 from the state where the bottom rail 5 is in the lower limit position or the intermediate position, the screen 4 is wound around the take-up pipe 9. Taken. At this time, when the operation code 3 comes into contact with the code guide portion 12 on the indoor side and a clockwise torque is applied to the operation unit 60, the operation unit 60 operates as a pendulum, and the side end portion of the protruding piece 61 of the operation plate member 6a. Rotates the movable fin 40 and presses the screen 4 on the outdoor side. Therefore, the interval d2 at the time of operation of the double screen 4 is configured to be larger than the interval d1 at the time of rest. Therefore, the double screen 4 does not rub during the ascending operation, or even if it rubs, it is partially moving up and down, or the frictional force is reduced and the screen 4 moves relative to each other, so that there is no risk of damaging the screen 4. Further, a guide slightly larger than the outer shape of the ball portion 3a of the operation code 3 between the front side code guide unit 12 and the code guide unit 13 and between the rear side code guide unit 12 and the code guide unit 13. Since the path is formed so that at least two consecutive ball portions 3a at a predetermined pitch are always in contact with either one of the cord guide portions 12 and 13, rattling in the operation unit 60 during operation of the operation code 3 is suppressed. At the same time, it is possible to reduce the operation noise that may occur due to the interference between the ball portion 3a and the cord guide portions 12 and 13.

Similarly, referring to FIG. 24 (c), for example, when the operation code 3 is operated so as to lower the bottom rail 5 from the state where the bottom rail 5 is in the intermediate position or the upper limit position, the bottom rail 5 is wound around the take-up pipe 9. The screen 4 is lowered. At this time, the operation code 3 comes into contact with the code guide portion 13 on the indoor side, and a clockwise torque is applied to the operation unit 60, so that the operation unit 60 operates as a pendulum, and the side end portion of the protruding piece 61 of the operation plate member 6a. Rotates the movable fin 40 and presses the screen 4 on the outdoor side. Therefore, the interval d3 when the double screen 4 is operated is configured to be larger than the interval d1 when the double screen 4 is stationary. Therefore, the double screen 4 does not rub during the lowering operation, or even if it rubs, it moves partially during ascending / descending, or the frictional force is reduced and the screen 4 moves relative to each other, so that there is no risk of damaging the screen 4. Even if friction occurs in a part of the screen 4 near the upper limit of the roll-up thickness, the frictional force acts in a direction of reducing the frictional force.

Therefore, according to the roll screen 1 of the seventh embodiment, the operation unit 60 is rotated by the tensile force of the operation code 3 during the ascending / descending operation, the double screen 4 is separated, and friction does not occur (or even if friction occurs). Is reduced), so that there is no risk of damaging the screen 4 (or it is reduced). Further, when stationary, the operation code 3 loses tension, and the operation unit 60 rotates in the direction in which the double screen 4 approaches due to the weight of the screen 4 or the like. This makes it possible to improve the light-shielding property when the transmissive portion 4b and the light-shielding portion 4a of the screen 4 are brought into a light-shielding state.

Further, according to the roll screen 1 of the seventh embodiment, the fixing portion 2c of the mounting frame 2 is configured to detachably lock the fabric retainer 80 whose length of the screen 4 can be adjusted by winding. For example, it becomes easy to adjust the length of the screen 4 so that the bottom rail 5 is in the shielded state when it is in the lower limit position.

Further, according to the roll screen 1 of the seventh embodiment, since the movable fin 40 is configured with a length sufficient to close the gap between the mounting frame 2 and the take-up pipe 9, the mounting frame 2 and the take-up pipe 9 are formed. It is possible to further block the external light that may be incident from the gap between the 9 and 9.

Further, according to the roll screen 1 of the seventh embodiment, a predetermined pitch is provided between the front code guide unit 12 and the code guide unit 13 and between the rear code guide unit 12 and the code guide unit 13. Since at least two consecutive ball portions 3a are configured to always contact and guide one of the code guide portions 12 and 13, the rattling in the operation unit 60 during the operation of the operation code 3 is suppressed, and the ball is suppressed. It is possible to reduce the operation noise that may occur due to the interference between the unit 3a and the code guide units 12 and 13.

As described above, the present invention has been described with reference to examples of specific embodiments, but the present invention is not limited to the examples of the above-described embodiments, and various modifications can be made without departing from the technical idea. is there. For example, in each embodiment, the indoor side and the indoor side have been specified and described, but the indoor side and the indoor side may be installed in opposite directions.

Further, in order to ensure that the screen 4 is separated during operation, an urging means such as a spring that assists the pendulum operation in which the screen 4 moves in the separating direction may be further provided.

According to the roll screen 1 according to the present invention, the double screen 4 does not rub during the ascending / descending operation, or even if it rubs, it moves partially during the ascending / descending operation, or the frictional force is reduced and the double screens move relative to each other. There is no risk of damaging the screen 4, and when stationary, the intervals between the double screens 4 can be brought close to each other or brought into close contact with each other. Since it is possible to improve the light-shielding property when the light-shielding state is set by matching with 4a, it is useful for applications such as blinds using a double screen.

1 Roll screen 2 Mounting frame 2a, 2b Support member 2c Fixing part 3 Operation code 4 Screen 4a Screen shading part 4b Screen transmission part 5 Bottom rail 6 Operation plate member 7 Support shaft 8 Support plate 9 Winding Pipe 10 Operation pulley 11 Fixed shaft 12, 13, 14 Cord guide part 15 Roller 16 Support shaft 23 Rotation receiving part 27 Rotating shaft hole 31 Drive gear 32 Transmission gear 33 Driven gear 40 Movable fin 50 Fixed bar 60 Operation unit 61 Projection piece 80 Fabric holder

Claims (15)

A roll screen that allows the double screen to move relative to the vertical direction.
The double screen is formed by folding one screen.
A take-up pipe that attaches one side of the screen and suspends and supports it so that it can be taken up.
A fixing means for attaching and supporting the other side of the screen folded back from the take-up pipe via a hanging weight member and supporting the screen above the take-up pipe.
It is provided with an operation means for performing an operation of making the double screen relatively movable in the vertical direction.
The operating means
An operation plate or operation unit that always operates as a pendulum during operations that allow the double screen to move relative to the vertical direction.
The distance between the double screens configured to be relatively movable according to the pendulum movement is separated, and the distance between the double screens separated during the operation is always greater than the distance between the double screens separated during the operation when there is no operation in a stationary state without the pendulum movement. A mechanism that works to bring them closer together or in close contact with each other
A roll screen characterized by being equipped with. The roll screen according to claim 1, wherein the operation plate or operation unit in the operation means pendulums so that the interval between operations of the double screen is larger than the interval when the double screen is stationary. The operation plate or the operation unit in the operation means pendulums so that the double screens are brought into close contact with each other by their own weight when the operation is stopped, according to claim 1 or 2. The listed roll screen. The roll according to any one of claims 1 to 3, wherein the double screen is formed with a transmitting portion that partially transmits light and a light-shielding portion that blocks light. screen. The double screen is formed by folding one screen.
A take-up pipe that attaches one side of the screen and suspends and supports it so that it can be taken up.
It is provided with a support shaft that attaches and supports the other side of the screen that is folded back from the take-up pipe via a weight member.
Claims 1 to 4, wherein the operation plate or the operation unit in the operation means operates as a pendulum so as to change the positional relationship between the take-up pipe and the support shaft between the stationary state and the operation state. The roll screen according to any one of the above. The operation plate or operation unit in the operation means is engaged with an operation code for operating the opening / closing operation of the double screen, and the operation plate or operation in the operation means is caused by the tensile force of the operation code at the time of operation. The roll screen according to claim 5, wherein the unit is configured to have a force point that acts to rotate the double screen together with the support shaft in a direction in which the double screen is separated. The roll screen according to claim 5 or 6, wherein the support shaft is provided on the indoor side below the take-up pipe. The mechanism in the operating means separates the double screens according to the pendulum operation, and always brings the screens closer to or closer to each other than the distance between the double screens separated during the operation. other side, characterized in Rukoto configured as dough interval adjusting means operate on a roll screen according to any one of claims 1 to 4. The fabric spacing adjusting means includes movable fins that press the screens so that the double screens are separated by the pendulum operation of the operating unit, and the movable fins are rotatably suspended from the fixing means by a base shaft thereof. The roll screen according to claim 8, wherein the roll screen is lowered. The roll screen according to claim 9, wherein the movable fin has a length sufficient to close a gap between the fixing means and the winding means. The fabric spacing adjusting means includes a fixing bar that presses the screens so that the double screens are separated by the pendulum operation of the operating unit, and the fixing bar is fixed to a part of the operating unit. The roll screen according to claim 8, wherein the roll screen is characterized. The roll screen according to any one of claims 8 to 11, wherein the operation unit is provided with a rotation regulating means for regulating the rotation range of the pendulum operation. The roll according to any one of claims 8 to 12, wherein the operation unit has a code guide portion that guides the hanging of the operation code and supports the operation code so as to operate the pendulum. screen. The operation unit has an operation code by a ball chain in which a plurality of ball portions are connected.
The roll screen according to claim 13, wherein the cord guide portion is configured such that at least two consecutive ball portions are always in contact with each other and guided at a predetermined pitch. The fixing means has a dough retainer whose length can be adjusted by winding an end portion of the screen, and a fixing portion for detachably locking the dough retainer, according to claims 8 to 14. The roll screen according to any one of the above.

Images