JP2020020131A - Rolling screen and screen for rolling screen - Google Patents

Abstract

To provide a rolling screen and a screen for the rolling screen capable of suppressing the generation of moire effect when translucent parts of front and rear screens are overlapped.SOLUTION: In a rolling screen capable of elevating and lowering a first screen 5a and a second screen 5b arranged in parallel in the front-rear direction, each of the first screen 5a and the second screen 5b includes a lace portion 8 and a drape portion 9 arranged alternately in the elevating/lowering direction. Regions constituting each of the lace portions 8 are configured to be differentiated in fabric texture. The first screen 5a and the second screen 5b are switched between a light shielding state in which the lace portion 8 of the first screen 5a and the drape portion 9 of the second screen 5b overlap with each other, and a light transmitting state in which the lace portions 8 and the drape portions 9 of the first screen 5a and the second screen 5b overlap with each other. The lace portions 8 which are overlapped when relatively moving between the light shielding state and the light transmitting state indicate an overlapped relationship between different fabric textures.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a roll screen and a screen for a roll screen, in which a plurality of screens are suspended and supported in a superimposed state, and the amount of light to be taken into a room can be adjusted by adjusting the manner of overlapping the screens.

  There is a roll screen capable of adjusting the amount of light to be taken indoors by relatively moving vertically overlapping screens vertically (see Patent Document 1). In such a roll screen, a lace portion that partially transmits light, and a drape portion that blocks light are alternately formed in stripes on the screen, and the screen is suspended and supported in a state of being overlapped double. ing. Then, by operating the operation means, the front and rear screens are relatively moved in the vertical direction, and the degree of overlap between the lace portion and the drape portion is adjusted, so that the amount of collected light can be adjusted.

JP 2018-3541A

  By the way, since the lace portion of each screen has the same structure (for example, fabric structure), moire (interference fringes) may be generated when the front and rear screens are relatively moved.

  The present invention has been made to solve the above problems, and an object of the present invention is to provide a roll screen and a roll screen screen that can suppress the occurrence of moire that occurs when the front and rear screens overlap. is there.

  A roll screen for solving the above-mentioned problem is a roll screen capable of moving up and down a first screen and a second screen arranged in the front-rear direction, wherein each of the first screen and the second screen is alternately arranged in an ascending and descending direction. A lace portion and a drape portion are arranged side by side, and the regions constituting each of the lace portions are configured such that the tissues are different in the regions, and the first screen and the second screen are the first screen. The lace portion of the screen and the drape portion of the second screen are switched to a light-shielding state where they overlap, and the lace portion of the first screen and the second screen and a translucent state where the drape portions overlap each other, The lace parts overlapping when relatively moving between the light-shielding state and the light-transmitting state have different tissues. Part overlap.

  In the above-mentioned roll screen, in a region constituting each of the lace portions, the structure may be composed of a weft element and a transelement, and the density of the weft element may be gradually different in the elevating direction.

  In the above-mentioned roll screen, in a region constituting each of the lace parts, the structure may be constituted by a weft element and a transelement, and the weft element may be arranged so as to fluctuate irregularly.

In the roll screen, the structure is, for example, a dough structure.
In the above-mentioned roll screen, the first screen and the second screen are formed of one continuous screen, and the continuous screen is folded back at a weight bar disposed at a lower end portion, whereby the first screen is formed. And the second screen.

  In the above-mentioned roll screen, when the drape portion has a lower light transmittance than the lace portion, the regions constituting each of the drape portions are also configured so that the tissues are different in the region, and the light-shielding is performed. The drape portions that overlap when relatively moving between the state and the light-transmitting state may also have different tissue portions overlapping.

  A roll screen screen for solving the above-mentioned problems is a roll screen screen configured by folding a first screen and a second screen in a roll screen, which are arranged in the front-rear direction, wherein the first screen and the second screen are arranged. A lace portion and a drape portion are alternately arranged in the direction in which the screen moves up and down, and regions constituting each of the lace portions are configured such that the tissues are different in the regions.

  ADVANTAGE OF THE INVENTION According to this invention, generation | occurrence | production of a moire at the time of the translucent part of the front and back screen overlapping can be suppressed.

FIG. 2 is a front view of the roll screen according to the first embodiment. FIG. 2 is a cross-sectional view of the roll screen according to the first embodiment. The principal part perspective view which shows the relationship between a 1st screen, a 2nd screen, and a weight bar. The principal part top view of the screen for roll screens used for a 1st screen and a 2nd screen. (A) is a diagram showing a light transmitting state, and (b) is a diagram showing a light blocking state. FIG. 4 is a side view showing a gear mechanism of the operation device in the roll screen according to the first embodiment. (A) And (b) is a figure which shows operation | movement of a gear mechanism. FIG. 5 is an essential part plan view of the screen for a roll screen in which the weft in each translucent section is crossed with the warp so that the density gradually increases from the upper end to the lower end, contrary to the example of FIG. 4. The principal part top view of the sheet | seat for screens used for the 1st screen and 2nd screen in 2nd Embodiment. FIG. 13 is a perspective view of a main part of a roll screen according to a third embodiment.

Hereinafter, a roll screen to which the present invention is applied will be described with reference to the drawings.
[First Embodiment]
As shown in FIGS. 1 and 2, the roll screen of the first embodiment is a dimmable roll screen. In the roll screen, a support bracket 3 is attached to both ends of a frame 2 attached to an attachment surface such as a window frame via an attachment bracket 1, and two first winding pipes 4 a and a second support pipe 3 are attached to the support bracket 3. The two winding pipes 4b are rotatably supported. As an example, the first screen 5a is located outside the room, and the second screen 5b is located inside the room.

  The first take-up pipe 4a as the first take-up shaft and the second take-up pipe 4b as the second take-up shaft are supported by the support bracket 3 at predetermined intervals in the up-down direction and in the front-rear direction. It is supported with a slight offset. The upper edge of the first screen 5a is attached to the first take-up pipe 4a located on the upper side and the outdoor side, and the upper end of the second screen 5b is attached to the second take-up pipe 4b located on the lower side and the indoor side. The rim is attached. The first screen 5a and the second screen 5b are suspended from the first take-up pipe 4a and the second take-up pipe 4b in a state of being superimposed on each other.

  As shown in FIG. 3, the lower edges of the first screen 5a and the second screen 5b are attached to a weight bar 6, and both ends of the weight bar 6 are supported by a bottom cover 7 opening upward. The first screen 5a and the second screen 5b are guided upward from inside the bottom cover 7 to the opening thereof.

  In each of the first screen 5a and the second screen 5b, a lace portion 8 as a light-transmitting portion that transmits light and a drape portion 9 as a light-shielding portion that shields light are vertically arranged at equal intervals. . The first screen 5a and the second screen 5b are one continuous screen, and are arranged so as to be arranged in the front-rear direction of the roll screen by being folded back by the weight bar 6. The roll screen screen 11 which is the raw material of the continuous screen shown in FIG. 4 is, for example, a fabric structure such as a woven fabric, a knitted fabric, or a nonwoven fabric impregnated with a resin. In the fabric structure, when the soft fabric is impregnated with the resin, the fibers are less likely to be unraveled and wrinkles are less likely to occur, so that expansion and contraction of the fabric can be suppressed. As a result, a fabric having excellent flatness or flatness and excellent shape stability can be obtained. Further, the fabric structure can be added with flameproofing performance by incorporating a flameproofing agent. The fabric structure may be plain or may have a pattern. Further, the fabric structure may be embroidered fabric or the like.

  As shown in FIG. 5A, the first screen 5a and the second screen 5b can take in external light from the lace portion 8 in a transmissive state where the lace portion 8 overlaps, as shown in FIG. 5B. As described above, when the lace portion 8 and the drape portion 9 of the first screen 5a and the second screen 5b overlap with each other, the light enters a light-shielding state in which external light is blocked. The drape portion 9 is formed such that the width in the up-down direction is wider than the width of the race portion 8 in the same direction. This ensures that the drape portion 9 closes the race portion 8 in the light-shielded state.

  The fabric design is composed of a warp 12 as a warp element and a weft 13 as a weft element. The weft is passed between the warps, the position of the warp is adjusted with a reed, the weft is pushed in, and the warp 12 and the weft 13 are formed. Are interwoven (see FIGS. 3 and 4). In the region of each lace portion 8, the density of the weft yarns 13 is varied depending on the position so that the texture is different in the region.

  In the screen 11 for a roll screen shown in FIG. 4, in each lace portion 8, the weft 13 crosses the warp 12 so that the density gradually decreases from the upper end to the lower end. Therefore, in each of the race portions 8, there is no portion having the same density in the vertical direction. As shown in FIG. 3, the roll screen screen 11 is arranged so as to be lined up in the front-rear direction of the roll screen by being folded back by the weight bar 6. Therefore, each lace portion 8 of the first screen 5a is a mesh crossing the warp 12 so that the weft 13 gradually decreases in density from the upper end to the lower end. On the other hand, each lace portion 8 of the second screen 5b is a mesh crossed by the warp 12 so that the weft 13 gradually increases in density from the upper end to the lower end.

  As shown in FIGS. 1 and 2, an operation device 16 is attached to one of the support brackets 3, and an endless ball chain 17 is hung from the operation device 16. By operating the ball chain 17, the first winding pipe 4a and the second winding pipe 4b are rotated at the same speed in the same direction, so that the first screen 5a and the second screen 5b can be moved up and down at once. ing.

  When the ball chain 17 is pulled in the opposite direction after the first screen 5a and the second screen 5b are lifted and lowered, only the lower second winding pipe 4b is rotated only to a predetermined angle, and the first screen 5a and the second screen 5b are rotated. The relative movement operation of the second screen 5b in the up-down direction is enabled.

  As shown in FIGS. 1 and 7A and 7B, a pulley 19 is rotatably supported in a case 18 of the operating device 16, and a ball chain 17 is mounted on the pulley 19. The pulley 19 is rotated in the forward and reverse directions by operating the ball chain 17.

  The ball chain 17 is formed in an endless shape, and has regulating members 17a and 17b for regulating the range of elevation of the first screen 5a and the second screen 5b. When the first screen 5a and the second screen 5b are pulled up to the upper limits, the regulating member 17b comes into contact with the back side of the case 18, and further operation of the ball chain 17 in the same direction is prevented. When the first screen 5a and the second screen 5b are lowered to the lower limit, the regulating member 17a contacts the front side of the case 18 and further operation of the ball chain 17 in the same direction is prevented.

  As shown in FIG. 6, a drive gear 21 is integrally formed with the pulley 19, and a transmission gear 22 meshing with the drive gear 21 is rotatably supported by the case 18. The transmission shaft 23 of the second winding pipe 4b is inserted through the center of the drive gear 21, and a torsion coil spring 24 as an urging member is wound around the transmission shaft 23. The transmission shaft portion 23 has a cylindrical portion around which the torsion coil spring 24 is wound, and a distal end portion engaged with the second winding pipe 4b is fitted to the second winding pipe 4b so as to be relatively non-rotatable. I agree.

  The drive gear 21 is formed with two transmission pieces 25 protruding in the vicinity of the ends 24 a and 24 b of the torsion coil spring 24 at a distance, and the transmission piece 25 is formed on the end 24 a based on the rotation of the drive gear 21. , 24b, the rotation of the drive gear 21 is transmitted to the second winding pipe 4b. Therefore, when the pulley 19 is rotated, the second winding pipe 4b is rotated almost simultaneously.

  Above the case 18, a driven gear 26 meshing with the transmission gear 22 is rotatably supported by the case 18. The driving gear 21 and the driven gear 26 have the same number of teeth, and the driven gear 26 is rotated at the same speed in the same direction as the driving gear 21 based on the rotation of the driving gear 21.

  A transmission shaft 27 of the first winding pipe 4a is inserted through the center of the driven gear 26, and a torsion coil spring 28 as an urging member is wound around the transmission shaft 27. This transmission shaft portion 27 also has a cylindrical portion around which the torsion coil spring 28 is wound, and a distal end portion which engages with the first winding pipe 4a is fitted to the first winding pipe 4a so as to be relatively unrotatable. I agree.

  A transmission piece 29 is formed on the driven gear 26 so as to protrude on the rotation trajectory of the ends 28 a and 28 b of the torsion coil spring 28, and the transmission piece 29 is moved to the ends 28 a and 28 b based on the rotation of the driven gear 26. The rotation of the driven gear 26 is transmitted to the first winding pipe 4a.

  Therefore, when the driven gear 26 rotates in the direction of arrow A from the state shown in FIG. 7A, the rotation of the driven gear 26 is in the range of approximately 270 degrees until the transmission piece 29 abuts on the end 28a. It is not transmitted to the winding pipe 4a. Similarly, when the driven gear 26 rotates in the direction of arrow B from the state shown in FIG. 7B, the rotation of the driven gear 26 is in the range of approximately 270 degrees until the transmission piece 29 abuts on the end 28b. It is not transmitted to one winding pipe 4a.

  By such an operation, after the first screen 5a and the second screen 5b are lifted and lowered collectively, the ball chain 17 is operated in the opposite direction to rotate the driving gear 21 in the opposite direction. Until is rotated approximately 270 degrees, the first winding pipe 4a is not rotated, and only the second winding pipe 4b is rotated.

  The first winding pipe 4a and the second winding pipe 4b include a spring motor for reducing the operation force when winding the first screen 5a and the second screen 5b, and the first screen 5a and the second screen 5b. A stopper device and the like for preventing the self-weight drop of the vehicle are accommodated.

  Next, the operation of the roll screen configured as described above will be described. When the first take-up pipe 4a and the second take-up pipe 4b are rotated in the direction of arrow C shown in FIG. 6 by operating the ball chain 17, the first screen 5a and the second screen 5b are moved to the first take-up pipe 4a. Then, the first screen 5a and the second screen 5b are lowered at the same speed from the second winding pipe 4b.

  At this time, the first screen 5a is connected to the first take-up pipe so that the first screen 5a and the second screen 5b descend in a light-shielded state in which the lace portion 8 and the drape portion 9 of the first screen 5a and the second screen 5b overlap. 4a, and the second screen 5b is attached to the second winding pipe 4b (see FIG. 5B). Further, the positional relationship between the transmission piece 29 of the driven gear 26 and the ends 28a and 28b of the torsion coil spring 28 at the time of descending is as shown in FIG. ing.

  After lowering the first screen 5a and the second screen 5b to desired heights, when the ball chain 17 is operated in the reverse direction (the direction of arrow D shown in FIG. 6), the driven gear 26 rotates in the direction of arrow B, and the transmission piece Until 29 reaches the position shown in FIG. 7A, the first winding pipe 4a is not rotated, and only the second winding pipe 4b is rotated. Then, the first screen 5a and the second screen 5b relatively move in the vertical direction, and the lace portions 8 of the first screen 5a and the second screen 5b enter a translucent state in which they overlap, and external light can be taken in (FIG. 5). (A)).

  When the ball chain 17 is further operated in the same direction from the light transmitting state, the first winding pipe 4a and the second winding pipe 4b are rotated at the same speed, and the first screen 5a and the second screen 5b are pulled up at the same speed. Can be

The roll screen of the first embodiment as described above can obtain the following effects.
(1-1) Each lace portion 8 of the first screen 5a is a mesh crossing the warp 12 so that the weft 13 gradually decreases in density from the upper end to the lower end. On the other hand, each lace portion 8 of the second screen 5b has a mesh in which the wefts 13 intersect with the warps 12 so that the density gradually increases from the upper end to the lower end. Therefore, while switching between the light-shielding state and the light-transmitting state, each race part 8 of the first screen 5a and each race part 8 of the second screen 5b relatively move in the vertical direction, but the parts having the same density are not moved. Almost no overlap. That is, in the lace section 8, the regular repetitive patterns hardly overlap. Thereby, it is possible to suppress the occurrence of moire in a portion where the lace portion 8 of the first screen 5a and the lace portion 8 of the second screen 5b overlap.

  (1-2) Since the first screen 5a and the second screen 5b are configured by folding one roll screen screen 11, separate roll screen screens are used for the first screen 5a and the second screen 5b. Thus, the number of parts can be reduced as compared with the case of performing the above. Moreover, the roll screen can facilitate the assembly process of the first screen 5a and the second screen 5b.

The roll screen according to the first embodiment can be further modified and implemented as follows, for example.
As shown in FIG. 8, the screen 11 for a roll screen may be a mesh in which the configuration of each lace portion 8 is intersected with the warp 12 so that the weft 13 gradually increases in density from the upper end to the lower end. . That is, in FIG. 8, the density of the weft 13 in the race portion 8 is reversed from that in the examples of FIGS. In this case, each lace portion 8 of the first screen 5a is a mesh crossed with the warp 12 so that the weft 13 gradually increases in density from the upper end to the lower end. On the other hand, each lace portion 8 of the second screen 5b is a mesh in which the weft 13 intersects with the warp 12 such that the density gradually decreases from the upper end to the lower end. Thus, the same effect as (1-1) and (1-2) can be obtained even if the configuration is the reverse of the configuration of the weft 13 of the race portion 8 shown in FIGS. 3 and 4.

The density in each race portion 8 may not be changed gradually in the elevating direction, but may be changed stepwise in the elevating direction.
[Second embodiment]
As shown in FIG. 9, in the roll screen of the second embodiment, the configuration of the lace portion 8 that transmits light is different from that of the first embodiment, and the weft 13 intersects the warp 12 so as to fluctuate irregularly. It is a mesh. Also in the second embodiment, the first screen 5a and the second screen 5b are configured by one roll screen screen 11, and are arranged so as to be arranged in the front-rear direction of the roll screen by being folded back by the weight bar 6. ing.

The roll screen of the second embodiment as described above can obtain the effects listed below.
(2-1) Each lace portion 8 of the first screen 5a and the second screen 5b is formed of a mesh crossing the warp 12 so that the weft 13 fluctuates irregularly. Therefore, while switching between the light-shielding state and the light-transmitting state, each race part 8 of the first screen 5a and each race part 8 of the second screen 5b relatively move in the vertical direction, but the parts having the same density are not moved. No overlap. That is, in the lace section 8, regular repeated patterns do not overlap. Therefore, it is possible to suppress the occurrence of moire in a portion where the lace portion 8 of the first screen 5a and the lace portion 8 of the second screen 5b overlap.

[Third embodiment]
In the roll screen of the third embodiment, the first screen 5a and the second screen 5b are configured as separate screens. In this respect, the first screen 5a and the second screen 5b are different from the roll screen of the first embodiment in which one continuous screen is formed.

  As shown in FIG. 10, in the roll screen of the third embodiment, since the first screen 5a and the second screen 5b are separate sheets, the first weight bar 31 is arranged at the lower end of the first screen 5a, The second weight bar 32 is arranged at the lower end of the second screen 5b.

  When the roll screen screen 11 provided with the lace part 8 shown in FIG. 4 is used for the first screen 5a and the second screen 5b, it is used as follows. That is, in the first screen 5a, each lace portion 8 is configured so that the density of the warp yarns 12 gradually decreases from the upper end to the lower end. In this case, the second screen 5b is configured such that the first screen 5a is turned upside down so that the density of the warp yarns 12 gradually increases from the upper end to the lower end of each lace portion 8. Thereby, the race part 8 of the first screen 5a and the race part 8 of the second screen 5b are in the same state as the race part 8 of the first screen 5a and the race part 8 of the second screen 5b of the first embodiment. .

  Contrary to this, in the first screen 5a, each lace portion 8 is configured so that the density of the warp yarns 12 gradually increases from the upper end to the lower end, and the second screen 5b is arranged above and below the first screen 5a. The same effect can be obtained by configuring each of the lace portions 8 so that the density of the warp yarns 12 gradually decreases from the upper end to the lower end.

  When the roll screen screen 11 having the lace portion 8 shown in FIG. 9 is used for the first screen 5a and the second screen 5b, it is used as follows. The lace portion 8 of the screen 11 for a roll screen shown in FIG. 9 is used for the first screen 5a and for the second screen 5b because the weft 13 intersects the warp 12 so as to fluctuate irregularly. There is no difference with the case. In this case, the screen sheet can be used for the first screen 5a and the second screen 5b irrespective of the vertical direction.

The roll screens of the first to third embodiments can be further modified and implemented as described below, for example.
In the case where a sheet with a dough texture is used for the first screen 5a and the second screen 5b, yarns of various thicknesses may be used for the weft 13 in each lace portion 8. Even with such a configuration, it is possible to prevent the regularly repeated patterns from overlapping each other in the lace portion 8 of the first screen 5a and the lace portion 8 of the second screen 5b, thereby suppressing the occurrence of moire. it can.

  -The 1st screen 5a and the 2nd screen 5b may not be a sheet | seat of a cloth | tissue structure, but may be a synthetic resin sheet which is not a cloth | texture (it is not a cloth | textile). In this case, both the lace portion 8 and the drape portion 9 are formed by printing. For example, the drape unit 9 can be configured by performing solid printing using low-brightness color ink. The lace portion 8 can be configured by printing the mesh (the pattern of the warp 12 as the warp element and the weft 13 as the weft element) of the first and second embodiments.

  The first screen 5a may move with respect to the second screen 5b to switch between the light transmitting state and the light blocking state, or the second screen 5b may move with respect to the first screen 5a as described above. Alternatively, both the first screen 5a and the second screen 5b may move in directions opposite to each other.

  According to the JIS-L 1055A method, the light-shielding portion formed by the drape portion 9 may be defined as a region having a light-shielding rate of 99.40% or more according to JIS-L1055A. Depending on the structure of the fabric structure, there are first to third grades (first grade: 99.99% or more of light shielding rate, second grade: 99.80% to less than 99.99%, third grade: 99.40 of light shielding rate) % Or more and less than 99.80%). Therefore, it has some translucency in any grade. Even if the drape portion 9 is of the first to third grade, if the drape portion 9 of the first screen 5a and the drape portion 9 of the second screen 5b have a regularly repeating structure, moire may occur. Further, when a region having a light blocking ratio lower than the third-class light blocking ratio is used as the drape portion 9, moire is more likely to occur. Therefore, the drape portion 9 of the first screen 5a and the drape portion 9 of the second screen 5b may be configured so that the tissues are different in the region.

  That is, in the first screen 5a, in addition to the lace portion 8, the drape portion 9 also varies the density of the weft 13 depending on the position. For example, in the case of the roll screen shown in FIG. 3, each drape portion 9 in the first screen 5a intersects with the warp 12 such that the density of the weft 13 gradually decreases from the upper end to the lower end. Each drape 9 in the second screen 5b crosses the warp 12 so that the density of the weft 13 gradually increases from the upper end to the lower end. As shown in FIG. 9, the drape portion 9 of the first screen 5a and the drape portion 9 of the second screen 5b cross the warp 12 so that the weft 13 fluctuates irregularly.

  According to the above configuration, even when the drape portion 9 has a light transmitting property, the drape portion 9 overlaps with each other, or the drape portion 9 and the race portion 8 overlap with each other, the occurrence of moire is suppressed. be able to.

  Note that the definitions of the light-blocking portion formed by the drape portion 9 and the light-transmitting portion formed by the race portion 8 are not limited to the above-described definitions based on the light blocking ratio.

  DESCRIPTION OF SYMBOLS 1 ... Mounting bracket, 2 ... Frame, 3 ... Support bracket, 4a ... 1st winding pipe, 4b ... 2nd winding pipe, 5a ... 1st screen, 5b ... 2nd screen, 6 ... Weight bar, 7 ... Bottom Cover, 8 Lace, 9 Drape, 11 Screen for roll screen, 12 Gradual warp, 12 Warp, 13 Weft, 15 Fabric element, 16 Operating device, 17 Ball chain, 18 Case , 19 ... pulley, 21 ... drive gear, 22 ... transmission gear, 23 ... transmission shaft, 24 ... coil spring, 24a ... end, 24b ... end, 25 ... transmission piece, 26 ... driven gear, 27 ... transmission shaft Part, 28: coil spring, 28a: end, 28b: end, 29: transmission piece, 31: first weight bar, 32: second weight bar.

Claims (7)

In a roll screen capable of vertically moving the first screen and the second screen arranged in the front-rear direction,
Each of the first screen and the second screen includes a lace portion and a drape portion alternately arranged in a vertical direction,
The regions constituting each of the lace portions are configured such that the tissue is different in the regions,
The first screen and the second screen are in a light-shielding state in which the lace portion of the first screen and the drape portion of the second screen overlap, and the lace portions of the first screen and the second screen and It switches to a translucent state where the drape parts overlap,
A roll screen in which the lace portions that overlap when relatively moving between the light-shielding state and the light-transmitting state overlap portions of different tissues. 2. The roll screen according to claim 1, wherein, in a region constituting each of the lace portions, the texture is constituted by a weft element and a transelement, and the density of the weft element gradually varies in the elevating direction. 2. The roll screen according to claim 1, wherein, in a region configuring each of the lace portions, the tissue is configured by a weft element and a transelement, and the weft elements are arranged so as to fluctuate irregularly. The roll screen according to claim 2, wherein the structure is a dough structure. The first screen and the second screen are configured by one continuous screen,
The roll screen according to any one of claims 1 to 4, wherein the continuous screen forms the first screen and the second screen by being folded back at a weight bar disposed at a lower end. In the case where the drape portion has a lower translucency than the lace portion,
Furthermore, the region configuring each of the drapes is also configured such that the tissue is different in the region,
The roll screen according to any one of claims 1 to 5, wherein the drape portions that overlap when moving relatively between the light-shielding state and the light-transmitting state also have different tissue portions. . A roll screen screen configured by folding a first screen and a second screen that are arranged in parallel in the front-rear direction of the roll screen,
A lace portion and a drape portion alternately arranged in the direction in which the first screen and the second screen are moved up and down;
A screen for a roll screen, wherein an area constituting each of the lace portions is configured to have a different tissue in the area.