JP3035580B2 - Shading material for controlling photoperiod reaction - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a light-shielding material which is suitably used mainly as a lining curtain for controlling a photoperiod reaction in house cultivation. [0002] As a cultivation method in an agricultural house, particularly in the cultivation of chrysanthemum, poinsettia, strawberry and the like, the photoperiodic response is controlled (mainly short-day treatment). A so-called shade cultivation method for cultivation is known. Shading for short-day treatment in this cultivation method is performed by a lining curtain in the house. [0003] As a light-shielding lining curtain in a house used in this shade cultivation method, 1) it must have a perfect light-shielding rate of 100%, 2) have moisture permeability, air permeability, and water permeability. In particular, it is desired that the temperature rise in the coating system by the curtain is small. Conventionally, as a light-shielding material used for such a lining curtain, a single-layer film in which a synthetic resin film such as soft vinyl chloride or polyethylene is kneaded with a pigment having high light-shielding properties such as aluminum powder or carbon black or the film is used. Or a film (metallized film) obtained by laminating a light-shielding material such as an aluminum foil or performing a grain surface treatment by aluminum vapor deposition or the like. However, since these light-shielding materials have almost no moisture permeability or air permeability, when they are used for lining curtains, the interior of the house, especially the coating system with the lining curtains, may be over-humidified. Water droplets that have condensed on the inner surface of the curtain in the early morning or the like may fall and cause pathological disorders such as decay of crops. Further, since the light-shielding material has no water permeability, water droplets that are condensed on the inner surface of the house and fall are likely to accumulate on the upper surface of the curtain. Opening and closing may not be smooth, and in extreme cases, the device may be broken down. Therefore, the operator needs to perform a draining operation on the curtain before starting the apparatus. [0007] Further, a light-shielding material in which a light-shielding microporous film is laminated on a light-shielding nonwoven fabric surface is also known. However, such a material has high moisture permeability and can prevent an over-humidified state. However, in order to obtain a desired light-shielding rate, it is necessary to make the nonwoven fabric thick and bulky. In addition, the workability such as opening and closing is reduced, and the pore diameter of the microporous film is small, so that the water permeability is small. As a result, dew water accumulates on the upper surface of the curtain, resulting in the above-described inconvenience. In recent years, it has also been proposed to use a woven or knitted fabric using a vapor-deposited tape obtained by slitting a synthetic resin film subjected to an aluminum vapor-depositing process as one of a warp and a weft as a light-shielding material (for example, JP-B-54-43177 and JP-B-7-11569. However, although this material has good infrared reflectivity, moisture permeability, air permeability, water permeability, etc., it is impossible to completely prevent light from leaking from gaps between constituent yarns specific to woven and knitted fabrics. It is not satisfactory as a lining curtain for shading in shade cultivation where complete shading is desired. For example, the minimum amount of light related to the growth of chrysanthemum is said to be several tens of lux, and the sunlight in summer is more than 100,000 lux, so that a light shielding rate of 99.99% or more is required. In a woven or knitted fabric using the above-described vapor-deposited tape, a required light-shielding rate cannot be obtained. On the other hand, when a sheet made of a woven or knitted fabric woven using black tape-like yarn having light absorbing and light shielding properties for at least one (mainly both) of the warp and the weft is used for the lining curtain, Although the light-shielding property is relatively high, there is a drawback that the sheet itself generates heat by absorbing sunlight, the temperature in the coating system increases, and the growth of the crop is affected. The present invention has been made in view of the above, and is a light-shielding material that can be suitably used as a light-shielding lining curtain for performing shade cultivation in an agricultural house, in particular, moisture permeability, air permeability, and water permeability. It is intended to provide a light-shielding material which can secure substantially perfect light-shielding properties and can appropriately control the photoperiod reaction. According to the present invention, there is provided:
In order to solve the above-mentioned problems, a woven or knitted fabric having moisture permeability, air permeability and water permeability is used. In the case of a woven or knitted fabric, it is impossible to eliminate 100% of light leakage due to its constitutional structure. Therefore, the light blocking rate is 99.99.
%, Preferably 99.997% or more. As a result of various studies and studies, the following invention has been achieved. The present invention provides a photoperiod reaction which solves the above-mentioned problems.
A light-shielding material for control, red and external reflective and made of a light-shielding property to the excellent textile fabric sheet (A), the sheet (B) consisting of knitted fabric which is excellent in light absorption and the light-shielding and by comprising superposing It is characterized by. The superposed sheets (A) and (B) are bonded at both ends or at an appropriate interval in the width direction or the length direction in order to secure moisture permeability and air permeability. It is preferable that they are partially connected by an adhesive means. In addition, the two sheets can be joined by other joining means such as suturing, or the two sheets superimposed at the stage of use can be joined. The sheet (A) in the light-shielding material is,
It is a woven or knitted fabric woven using a tape-like thread having excellent infrared reflectivity and light-shielding properties and a tape-like thread having excellent infrared reflectivity. The sheet (B) uses a tape-like thread having excellent light-absorbing properties and light-blocking properties. knitting der organization that has been weaving Te Ru. And the light shielding material of the light blocking ratio in the state where superposed both sheets (A) (B) is obtained by 99.99% or more. According to the light-shielding material of the present invention, since the superposed sheet (A) and sheet (B) are both woven and knitted, the entire surface can be formed into a single film or sheet. On the other hand, it possesses moisture permeability, air permeability, and water permeability specific to woven and knitted fabrics. Therefore, when this light-shielding material is used for a light-shielding lining curtain in shade cultivation, the inside of the coating system by the curtain does not become over-humidified or high-temperature, and dew condensation occurs on the inner surface of the curtain, There is no danger of dew condensation accumulating on the top surface. In addition, a sheet (A) having good infrared reflectivity and light shielding properties and a sheet (B) having good light absorbing properties and light shielding properties are provided.
Because of the double structure, a higher light blocking ratio can be obtained than when the sheets (A) and (B) are used alone. In particular, when the sheet (A) is used with the outer side used, it is possible to prevent the incidence of infrared rays from outside the coating system, to reflect heat rays (infrared rays), and to make the gap between the constituent yarns specific to the woven or knitted fabric. Even if light leaks from the light absorbing member, the leaked light is absorbed by the light absorbing sheet (B) inside. As a result, this kind of light-shielding material can have a very high light-shielding rate while having moisture permeability and air permeability. By using the sheet (B) inside, the sheet (B) absorbs less heat rays (infrared rays), and the sheet (B) itself can be prevented from generating heat. [0021] Thus, as in the present invention, the light blocking ratio of 99.99% or more, also becomes readily possible to 99.997% was subject or if necessary, photoperiod in the shade cultivation
A light-shielding material that can be suitably used as a light-shielding curtain for reaction control can be obtained. As the woven or knitted material used as the sheet (A) and the sheet (B) in the light-shielding material, a tape-like yarn excellent in infrared reflectivity and light-shielding property or a tape-like thread excellent in light absorption and light-shielding property can be used. Although it is also possible to configure by raschel knitting together with the fine thread, a woven fabric having a plain weave structure or the like is preferable in terms of ease of production and light shielding properties. In the above-mentioned light-shielding material, the tape-like yarn constituting the sheet (A) having excellent infrared reflectivity and light-shielding properties is made of a synthetic resin film as a base material and is metallized by a metal vapor deposition layer or a metal foil layer (metal). A tape obtained by slitting a surface-treated film is preferably used, and a tape-like yarn having excellent infrared reflectivity is white obtained by slitting a synthetic resin film formed by kneading a white pigment and forming a film. Tape is preferably used. The sheet (A) may be a woven or knitted fabric woven by using only one of these tape-like yarns, but is preferably used in combination as described below in practice. According to a fourth aspect of the present invention, in the light-shielding material, the sheet (A) uses a tape-like yarn made of a film grained by the metal deposition layer or the metal foil layer as one of a warp and a weft. It is characterized by comprising a woven or knitted fabric woven by using the white tape-like yarn as the other of the warp and the weft. A tape-like yarn made of a film whose surface has been grained by a metal vapor-deposited layer or a metal foil layer is excellent in infrared reflectivity and also in light-shielding properties as compared with a white tape-like yarn. On the other hand, a white tape-like thread is inferior to a silver-faced tape-like thread in light-shielding properties, but has a higher infrared reflectivity than a silver-faced tape-like thread, and is less expensive to manufacture. Therefore, by weaving these tape-like yarns into warp and weft yarns in a plain weave structure or the like, the two tape-like yarns are alternately present on the sheet surface, and both the infrared reflectiveness and light-shielding properties are provided over the entire surface. The sheet (A) excellent in the above can be easily manufactured and obtained at low cost. Further, depending on the combination of the sheet (A) and the sheet (B), as described above, 99.99% or more, and even 99.99% or more.
A light-shielding material having a light-shielding rate of 997% or more can be easily obtained. [0027] The tape-like yarn made from films grain of the, as claimed in claim 5, subjected to a metal deposition process such as aluminum synthetic resin film, further provided with a synthetic resin film on the deposition layer A deposition tape obtained by slitting a deposition film can be suitably used. This vapor deposition tape is formed, for example, by depositing a metal such as aluminum to a thickness of 300 to 700 angstroms on the surface of a uniaxially stretched synthetic resin film of 10 μm to 50 μm formed by a known production method. Extrusion lamination, using a vapor-deposited film laminated with a synthetic resin film having a thickness of 10 μm to 40 μm by a known lamination method such as extrusion lamination or a known coating method such as dipping, and slit the vapor-deposition film into a tape having a required width. It is obtained by doing. The thickness of the metal vapor-deposited layer, the thickness of the base film and the thickness of the synthetic resin film are appropriately set according to light-shielding properties, weaving properties, strength in use, and the like. With this vapor-deposited tape, the vapor-deposited layer is protected by being sandwiched between the base film and the synthetic resin film, and when the tape is slit from the vapor-deposited film, when weaving, and further during use, the vapor-deposited layer is peeled off. There is no danger of damaging or damaging, and good infrared reflectivity and light shielding properties can be maintained. The white tape-like yarn is a synthetic resin film formed by kneading a white pigment such as titanium oxide.
For example, 2-1 to 100 parts of synthetic resin base resin
A synthetic resin film formed by kneading 5 parts of a white pigment to form a film is used as a material, and this can be obtained by slitting the film into a tape having a required width. As the above-mentioned white pigment, in addition to the above-mentioned titanium oxide, a white pigment having a high infrared reflectance such as aluminum powder, alumina, zinc sulfide, zinc oxide, lead white, and white carbon can be used. Although not a white pigment, calcium carbonate can also be used. This white tape-like yarn is used by stretching the synthetic resin film of the material uniaxially in the longitudinal direction of the tape, heat-setting the tape slit as described above, and thermally shrinking the tape. According to a sixth aspect of the present invention, there is provided a vapor-deposited film in which a tape-like yarn made of a grained film is formed by depositing aluminum on a high-density polyethylene film and further laminating a medium-density polyethylene film on the vapor-deposited layer. This is a vapor-deposited tape obtained by slitting, wherein the white tape-like yarn is a tape obtained by slitting a high-density polyethylene film formed by kneading a white pigment and forming a film. By using high-density polyethylene or medium-density polyethylene as a constituent material of the sheet (A), processing such as film formation becomes easy. That is, high density polyethylene is easy to form a film, and medium density polyethylene is soft and easy to laminate. That is, the sheet (A) can be manufactured at low cost. As a tape-like thread made of a film having a grain surface, a metal foil such as aluminum having a thickness of 5 μm to 30 μm is laminated on a synthetic resin film as a base material by a known means, instead of the above-described vapor deposition. Further, if necessary, a multi-layer composite film in which a synthetic resin film is laminated may be used as a material, and a tape obtained by slitting this into a tape having a required width may be used. This tape also has excellent infrared reflectivity and light shielding properties due to the metal foil. As the base film and the synthetic resin film, it is preferable to use a polyethylene resin film as described above, but other synthetic resin films can also be used. In the light-shielding material of the present invention, the tape-like yarn constituting the sheet (B) having excellent light-absorbing and light-shielding properties is a synthetic resin film formed by kneading a black pigment such as carbon black, for example, 2 to 15 parts of a black pigment is kneaded with 100 parts of the synthetic resin base resin to form a synthetic resin film having excellent light absorbing and light shielding properties, which is slit into a tape having a required width. The obtained black tape can be suitably used.
This black tape is used by stretching the synthetic resin film of the material uniaxially in the longitudinal direction of the tape, heat-setting the tape slit as described above, and thermally shrinking the tape. The sheet (B) is woven using the black tape-like yarn as at least one of a warp and a weft. Among them, a woven or knitted fabric woven in a plain weave structure using the above-described black tape for both the warp and the weft is particularly preferable in terms of light shielding properties and ease of production. Examples of the black pigment include graphite, aniline lac, cyanine black, carbon black, and the like.
A black pigment such as acetylene black can be used. According to the invention of claim 8 , the sheets (A) and (B)
Is characterized in that it is a tape obtained by slitting a stretched synthetic resin film or a tape obtained by slitting an undrawn synthetic resin film and then performing uniaxial stretching. By stretching the tape-like yarn constituting the sheet and controlling the orientation of the film as described above,
The tape strength is improved and the tape elongation is suppressed. That is, by improving the tape strength, the strength and durability of the obtained sheet are improved, and troubles such as tape breakage during weaving can be prevented. In addition, since the tape elongation is suppressed, the handleability of the tape itself is improved, and the tension applied to the sheet during stretching does not change the tape driving density due to the elongation of the tape, maintaining a good light shielding rate for a long time It is possible to do. In addition, a tape-like yarn having infrared reflectivity and light-shielding property used for the sheet (A), for example, a tape made of a film silverized by a metal deposition layer or a metal foil layer, a white tape, or the sheet (B) The thickness and width of a tape-like yarn having light absorbing and light-shielding properties used for, for example, a black tape, can be appropriately set according to the light-shielding rate, strength, weaving density and the weaving state after weaving, and even the use mode. However, for example, the thickness is set in the range of 10 μm to several hundreds μm, and the width is set in the range of 1 mm to several tens mm. As the constituent material of the tape-like yarn used for the sheet (A) and the sheet (B), various resins such as a polyester resin in addition to a polyethylene resin can be used. It is preferable to add a weathering agent such as a UV absorber. Processing such as application of a dropping agent can also be performed. Embodiments of the present invention will now be described with reference to the drawings. FIG. 1 shows a light-shielding material according to an embodiment of the present invention, FIG. 2 is a plan view of a part of a sheet (A) made of a woven or knitted fabric having excellent infrared reflectivity and light-shielding properties, and FIG. FIG. 4 is a partial enlarged cross-sectional view, and FIG. 4 is a partial plan view of a sheet (B) made of a woven or knitted fabric having excellent light absorbing and light shielding properties. The sheet (A) is formed by slitting a synthetic resin film formed by kneading a white pigment and forming a film. The white tape (1) having excellent infrared reflectivity is used as a warp, and the synthetic resin film (base) is used as a base material. It is excellent in infrared reflectivity and light-shielding property obtained by slitting a three-layer vapor-deposited film in which a metal such as aluminum is deposited on 21) and a synthetic resin film (23) is provided on this vapor-deposited layer (22). It is woven with a plain weave structure using the vapor deposition tape (2) as a weft. Therefore, on the surface, a white tape (1) and a vapor deposition tape (2) which has been grained by a metal vapor deposition layer (21) appear alternately in the meridional direction and the weft direction. The sheet (B) uses black tapes (3) and (4), which are obtained by slitting a synthetic resin film formed by kneading a black pigment and formed into a film and having excellent light absorbing and light shielding properties, for the warp and the weft. It is woven in a plain weave structure. As shown in FIG. 1, the two sheets (A) and (B) are joined by welding means at required portions such as both ends and an intermediate portion in a state of being overlapped. Is constituted. (5) shows a connecting portion by the welding means. In the case of the figure, the sheet (A) has a larger number of wefts than the number of warps, and the sheet (B) has a larger number of warps than the number of wefts. Thereby, both sheets (A) superimposed on each other
The gap between the constituent yarns specific to the fabric of (B) is slightly shifted. By making the driving densities of the two sheets different as described above, the transmission of light from the gap can be mutually shielded, which is preferable. This light-shielding material is used, for example, as a light-shielding curtain in shade cultivation in an agricultural house, with the sheet (A) being on the outside. In this case, the sheets (A) and (B) made of a woven or knitted fabric are used. Due to the double structure of (2), it has moisture permeability, air permeability, and water permeability, has a substantially perfect light blocking rate, and can prevent a rise in temperature in the coating system. That is, since the sheet (A) is excellent in infrared reflectivity and light-shielding property, infrared rays from outside the coating system can be reflected by the sheet (A) to prevent light transmission, and the sheet (A) The leaked light can be absorbed by the inner sheet (B) having excellent light absorbing and light shielding properties, and the light shielding rate as a light shielding material can be greatly increased. Further, even if the sheet (B) on the inner side has a light absorbing property, since the amount of sunlight absorbed is small, the heat generation can be suppressed, and the temperature rise in the coating system can be prevented. (Example) First, 4 parts by weight of a rutile type titanium oxide pigment and 2 parts by weight of a benzophenone-based UV absorber were added to form a film having a thickness of 25 μm.
After slitting a uniaxially stretched high-density polyethylene (HDPE) film having a width of 8 mm into a tape having a width of 8 mm, this was heat-set and thermally contracted to obtain a white tape. Next, a uniaxially stretched 25 μm thick HDPE film formed by adding 2 parts by weight of a benzophenone UV absorber was formed.
One side of the film was subjected to aluminum vapor deposition with a thickness of 500 angstroms, a medium-density polyethylene film having a thickness of 15 μm to which 2 parts by weight of a benzophenone-based UV absorber was added was laminated on the surface of the vapor deposited layer, and then slit into a 3 mm wide tape. Then, a vapor deposition tape was obtained. Then, using the white tape as a warp,
The sheet (A) shown in FIG. 2 was woven with a plain weave structure by using the above-mentioned vapor-deposited tape as a weft at a driving density of 12 pieces / inch.
I got On the other hand, a 25 μm thick uniaxially stretched HDPE film formed by adding 5 parts by weight of carbon black into a film was slit into a width of 6 mm, and then this was heat-set and thermally shrunk to obtain a black tape. Then, this black tape was used as a warp for 1
Weaving was performed in a plain weave structure using a driving density of 2 yarns / inch and a driving density of 10 yarns / inch as weft to obtain a sheet (B) shown in FIG. The sheet (A) and the sheet (B) were overlapped, welded at required portions such as both ends, and joined together to obtain a light-shielding material of the present invention shown in FIG. . When the light-shielding ratio of the obtained light-shielding material was measured, the light-shielding ratio was 99.997% or more. The moisture permeability was 1000 g / m ² · day or more. When a water drop was dropped on the surface of the light-shielding material and observed, it was quickly absorbed and no water was collected. The light transmittance of each of the aluminum-deposited tape, the white tape and the black tape was measured by a spectroscope. The respective transmittances were as follows: (1) Aluminum-deposited tape: 1.0 to 1 0.5 (2) White tape: 3.0 to 10.0 (3) Black tape: 0 to 0 The transmittance of the laminate of the aluminum-deposited tape and the white tape was almost 0. Table 1 below shows light-shielding materials (Examples) obtained as described above and other light-shielding materials (Comparative Examples 1 to 4).
3 shows the comparison and evaluation of the light-shielding ratio with the above, and the evaluation of the temperature rise in the coating system. In Table 1, silver and white in the columns of the base material and the overlapping material are sheets woven using the aluminum vapor-deposited tape and the white tape of the above example for warp and weft, and white and white are only the white tape of the above example. , A sheet woven using warp and weft, black black indicates a sheet woven using only the black tape in the above example for the warp and weft, and the number in parentheses is between 1 inch between the warp and the weft. This shows the number of shots. [Table 1] The light shielding material (silver white / black black) of the above embodiment, a sheet woven using the black tape for warp and weft, and a sheet woven using the white tape for warp and weft are used. Superimposed materials (white / white / black / black: Table 1 above)
Comparative Example 3), and sheet 2 using the black tape
When the heat shielding effect was measured as described below for the material (black / black / black / black: Comparative Example 4 in Table 1) obtained by superposing the sheets, the result as shown in FIG. 5 was obtained. Measuring Method A box with a length × width × height of 200 × 200 × 100 (mm) painted in black is covered with a material to be measured, and 200 mm
An incandescent lamp was irradiated from above to measure the temperature in the box. As is clear from Table 1 and FIG. 5, Comparative Example 4 in which two sheets woven using a black tape were superposed has a high light-shielding rate, but a low heat-shielding effect from the outside. The effect of preventing a rise in temperature in the coating system cannot be obtained. In Comparative Example 2 in which a sheet woven using only a white tape and a sheet woven using only a black tape were superposed, the heat shielding effect was obtained by setting the white side to the outside. Although the effect of preventing the temperature rise is good, the light-shielding rate is rather low, and the light-shielding rate desired as a light-shielding curtain for shade cultivation cannot be obtained. Further, Comparative Example 3, in which two sheets woven by using an aluminum vapor-deposited tape and a white tape for the warp and the weft, are overlaid, has a low light-shielding ratio of 99.186%. This is 2
It is considered that the reflection of light is repeated between the sheets, and a part thereof is also leaked. On the other hand, the light-shielding material of the example had a light-shielding rate of 99.997%, and also satisfied the heat-shielding effect and the effect of preventing a rise in temperature in the coating system. Therefore, this light-shielding material can be used particularly suitably as a light-shielding curtain in shade cultivation. The light-shielding material of the present invention can be used for applications other than light-shielding curtains in shade cultivation. As described above, the light-shielding material of the present invention has a substantially perfect light-shielding rate desired as a light-shielding material for controlling the photoperiod reaction, and has high moisture permeability, water permeability and air permeability. Also, it has excellent heat shielding effect. Therefore, the light-shielding material of the present invention can be suitably used as a light-shielding curtain for controlling a photoperiod reaction in shade cultivation. In this use, the inside of the coating system does not become over-humidified, and the dew condensation water does not fall, so that it is possible to prevent the pathological disorder of the crop due to the over-humidity or the falling water. In addition, by using the sheet having infrared reflectivity with the side facing out, an excessive rise in temperature in the coating system can be suppressed.
Further, since water does not accumulate on the upper surface of the curtain, there is no need for draining work when opening and closing the curtain, and a large load is not applied to the opening and closing device, which contributes to labor saving and automation of the work. The two sheets constituting the light-shielding material can be easily manufactured by weaving them in a plain weave structure or the like using a tape-like thread, and can be provided at low cost.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic perspective view showing a light shielding material according to an embodiment of the present invention, with a part thereof being cut away. FIG. 2 is a partial plan view showing a sheet made of a woven or knitted fabric having excellent infrared reflectivity and light shielding properties. FIG. 3 is an enlarged sectional view of a part of the above. FIG. 4 is a partial plan view showing a sheet made of a woven or knitted fabric having excellent light absorption and light shielding properties. FIG. 5 is a temperature measurement graph for comparing the heat shielding effect of the light shielding material. [Description of Signs] (A) Sheet having infrared reflectivity and light shielding (B) Sheet having light absorbing and light shielding (1) White tape (2) Evaporation tape (3) (4) Black tape (5) Joint

──────────────────────────────────────────────────続 き Continuing from the front page (72) Yoshihiro Sunayama 4-1, Nihonbashi-Kofunacho, Chuo-ku, Tokyo Heisei Polymer Co., Ltd. (72) Inventor Kiyoo Ishii 4-1, Nihonbashi-Kofunacho, Chuo-ku, Tokyo (72) Inventor Isamu Hagiwara 4-1 Nihonbashi Kobunacho, Chuo-ku, Tokyo Heisei Polymer Co., Ltd. (56) References JP-A-59-11124 (JP, A) JP-A-4- 133730 (JP, A) Jpn. Sho 62-4953 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , DB name) A01G 13/02

Claims (1)

(57) [Claims] [Claim 1] Tape-like yarn excellent in infrared reflectivity and light-shielding property
And tape-like yarn with excellent infrared reflectivity
Woven sheet (A) consisting of knitted, the light-absorbing and light-shielding properties
Ri Na and superposed and sheet made of woven the textile fabric using a tape-like thread (B) is excellent, both sheets (A) (B)
A light-shielding material for controlling a photoperiod reaction, wherein a light-shielding ratio in a state in which are overlapped is 99.99% or more . 2. Controlling photoperiod response in shade cultivation
The sheet (A) outside as a light-shielding curtain for
The photoperiod reaction according to claim 1, which is used for
Shading material for control . 3. A tape obtained by slitting a tape-like thread having excellent infrared reflectivity and light-shielding properties, obtained by slitting a film that has been grained with a metal deposition layer or a metal foil layer using a synthetic resin film as a base material. 3. A white tape obtained by slitting a synthetic resin film formed by kneading a white pigment and forming a tape-like yarn having excellent reflectivity.
A light-shielding material for controlling photoperiod reaction described in 1. 4. A sheet (A) wherein a tape-like yarn made of a film grained by a metal deposition layer or a metal foil layer is used as one of the warp and the weft, and a white tape-like yarn is used as the other of the warp and the weft. The light-shielding material for controlling photoperiod reaction according to claim 3, which is a woven or knitted fabric woven using the same. 5. A tape-like thread made of a film having a grain surface, obtained by subjecting a synthetic resin film to metal deposition such as aluminum and slitting a vapor-deposited film provided with a synthetic resin film on a vapor-deposited layer. The light-shielding material for controlling photoperiod reaction according to claim 3 or 4 , which is a deposited tape. 5. A tape-like thread made of a grained film is obtained by subjecting a high-density polyethylene film to aluminum vapor deposition, and further slitting a vapor-deposited film provided with a medium-density polyethylene film on a vapor-deposited layer. The tape for controlling a photoperiod reaction according to claim 3 or 4 , wherein the white tape-like thread is a tape obtained by slitting a high-density polyethylene film formed by kneading a white pigment .
The light-shielding material of. 7. A black tape obtained by slitting a synthetic resin film formed by kneading a black pigment such as carbon black with a tape-like yarn constituting the sheet (B) having excellent light-absorbing and light-shielding properties. The light-shielding material for controlling photoperiod reaction according to any one of claims 1 to 6 , wherein 8. A tape obtained by slitting a stretched synthetic resin film, wherein a tape-like yarn constituting the sheets (A) and (B) is provided.
The light-shielding material for controlling photoperiod reaction according to any one of claims 1 to 7 , which is a tape obtained by slitting an unstretched synthetic resin film and then performing uniaxial stretching.