JP2008178347A - Biodegradable herbicidal sheet - Google Patents

Abstract

The present invention provides a herbicidal sheet having biodegradability and having adhesion to the ground while maintaining required light-shielding properties and water permeability.
SOLUTION: A long fiber mainly composed of a polylactic acid polymer is used as a constituent fiber, and the constituent fibers are three-dimensionally entangled to form an integrated nonwoven fabric. The load at 10% elongation measured according to JIS L 1906 is 100 N / 5 cm width or less.
[Selection figure] None

Description

  The present invention relates to a biodegradable herbicidal sheet.

  In recent years, greening has been actively performed in many places including parks, residential land and roads. At the same time, various herbicidal measures are taken to prevent weeds from the viewpoint of maintaining aesthetics. As weeding means, manual weeding and herbicides have been used, but in recent years, various kinds of herbicidal sheets have been used as a means of suppressing the growth of weeds due to problems such as labor costs and effects on the surrounding environment. It has come to be used. For example, a resin sheet that is not biodegradable but made of polyethylene terephthalate, a metal sheet, a paper sheet, or the like has been proposed.

  Of these, non-biodegradable resin sheets and metal sheets are not decomposed in the soil surface or in the soil. Disposal may cause environmental pollution. On the other hand, the paper sheet has a problem that it has a low strength and thus is easily torn during construction, and has poor water permeability and rainwater accumulates.

As a herbicidal sheet for solving such problems, Patent Documents 1 and 2 propose a herbicidal sheet composed of a nonwoven fabric made of a biodegradable thermoplastic aliphatic polyester. Since these herbicidal sheets have biodegradability, it is possible to reduce the trouble of collection and the influence on the surrounding environment.
JP-A-11-229260 JP 2005-229862 A

  However, the herbicidal sheet of Patent Document 1 has room for improvement in strength / elongation, light shielding properties, water permeability, and the like. The herbicidal sheet of Patent Document 2 is an improved version of the herbicidal sheet of Patent Document 1, but it is made non-woven by thermally bonding constituent fibers to each other. Therefore, it cannot be said that the adhesion to the ground is sufficient. Therefore, when it is laid in a place where there are a lot of unevenness due to stones, etc., or in a place where the ground is inclined, the performance as a weedproof sheet may not be fully exhibited.

  For the purpose of solving such a point, the present inventors have conducted intensive studies in order to have a light-shielding property, water permeability, and adhesion to the ground in a biodegradable herbicidal sheet. . In order to improve the light-shielding property, it is conceivable to increase the basis weight of the sheet, but there is a problem that if the basis weight is simply increased, the sheet becomes stiff and water permeability and flexibility are extremely lowered.

  An object of the present invention is to provide a herbicidal sheet having biodegradability and having a required light shielding property and water permeability and having adhesion to the ground.

  In order to achieve the above-described object, the present invention has the following features.

  (1) A long fiber mainly composed of a polylactic acid-based polymer is used as a constituent fiber, and the constituent fiber is formed by a nonwoven fabric integrated by three-dimensional entanglement, and is measured according to JIS L 1906. A biodegradable weedproof sheet characterized in that the load at 10% elongation is 100 N / 5 cm width or less.

  (2) The biodegradable herbicidal sheet according to (1), wherein the light shielding ratio measured in accordance with JIS L 1055 is 95% or more.

(3) The single yarn fineness of the long fiber is 1 to 15 dtex, the L * value measured according to JIS Z 8729 is 40 or less, and the basis weight is 100 to 300 g / m ^2. The biodegradable herbicidal sheet of (2).

(4) The tensile strength is 250 to 850 N / 5 cm width, the penetration resistance is 10 N or more, and the water permeability measured according to JIS A 1218 is 2.0 × 10 ^{−2 to} 1.5 × 10 ^−1. The biodegradable herbicidal sheet according to any one of (1) to (3), which is cm / sec.

  The herbicidal sheet of the present invention is formed of a non-woven fabric integrated with three-dimensional entanglement of constituent fibers made of fibers mainly composed of a biodegradable polylactic acid-based polymer. Since the load at the time of% elongation is 100 N / 5 cm width or less, it has flexibility while maintaining the required light-shielding properties and water permeability, and therefore it should be a herbicidal sheet with adhesion to the ground. Can do.

  The biodegradable herbicidal sheet of the present invention needs to be formed of a nonwoven fabric composed of long fibers mainly composed of a polylactic acid polymer having biodegradation. By using such biodegradable fibers, the sheet after a certain period of time is almost completely decomposed by microorganisms, so that the trouble of removing the sheet and disposing of it can be saved, and the natural environment is contaminated. There is nothing.

  First, the polylactic acid polymer used for the herbicidal sheet of the present invention will be described. Examples of the polylactic acid-based polymer include poly-D-lactic acid, poly-L-lactic acid, a copolymer of D-lactic acid and L-lactic acid (D, L-lactic acid copolymer), and a melting point of 150 ° C. The above thing, or these blends are mentioned. When the melting point of the polylactic acid polymer is 150 ° C. or higher, it has high crystallinity, so that the cooling property during spinning is good, and a nonwoven fabric can be obtained satisfactorily by, for example, a spunbond method. Moreover, the crystal orientation of the polylactic acid polymer advances by high-speed spinning by the spunbond method, and the heat resistance, weather resistance, and mechanical strength of the resulting herbicidal sheet become excellent.

  When a copolymer is used as the polylactic acid polymer, the copolymerization ratio of D-lactic acid and L-lactic acid is determined so that the melting point of the copolymer is 150 ° C. or higher. For this purpose, in the D, L-lactic acid copolymer, the copolymerization ratio (molar ratio) is such that either L-lactic acid or D-lactic acid is 95 mol% or more and less than 100 mol%. . When the copolymerization ratio is out of the above range, the melting point of the copolymer becomes less than 150 ° C. or becomes amorphous, making it difficult to form the herbicidal sheet of the present invention.

  The fiber made of the polylactic acid polymer constituting the herbicidal sheet of the present invention is preferably an original fiber that is a fiber obtained by spinning a polymer previously kneaded with a pigment or the like. When such an original fiber is used, since the pigment is preliminarily contained in the fiber, dyeing by post-processing is not necessary, heat deterioration due to dyeing is eliminated, and the number of steps is reduced, so that the cost can be reduced. Furthermore, even if the fiber is made of a polylactic acid polymer that is difficult to be colored by dyeing after fiberization, good coloring can be obtained.

  The fibers used in the herbicidal sheet of the present invention may be copolymerized or blended with other polymers than the polylactic acid-based polymer as long as the object of the present invention is not impaired. Even those containing additives may be used.

  The nonwoven fabric forming the herbicidal sheet of the present invention needs to have a three-dimensional entangled structure between constituent fibers. Such a nonwoven fabric can be obtained by forming a web by a so-called spunbond method and subjecting the obtained web to, for example, needle punching, or winding the web and then performing needle punching. it can. By performing such a treatment, it is possible to form a non-woven fabric that retains its form by entanglement between constituent fibers even in the thickness direction. By using such a non-woven fabric, the intermediate load of the non-woven fabric is reduced, and it is easy to follow the unevenness of the ground when constructing the grassproof sheet, and can be laid in close contact with the ground.

  That is, the weedproof sheet of the present invention can be laid in close contact with the ground because the load at 10% elongation measured according to JIS L 1906 is 100 N / 5 cm width or less.

In the herbicidal sheet of the present invention, in order to make the load at 10% elongation measured according to JIS L 1906 be 100 N / 5 cm width or less, the constituent fibers of the nonwoven fabric forming the herbicidal sheet are tertiary. What is necessary is just to select the conditions for original entanglement suitably. For example, when the constituent fibers are three-dimensionally entangled by needle punching, the punch density is preferably 150 punch / cm ² or less. Moreover, the load at the time of 10% elongation shall be 100 N / 5 cm width or less also by adjusting suitably the speed which supplies a web to a needle punch machine, and the speed which discharges the nonwoven fabric after a punch process from a needle punch machine. be able to. In other words, these speeds are usually constant, but by setting the discharge speed slower than the supply speed, by forming a fiber with sufficient slack inside the nonwoven fabric, when pulling the weedproof sheet The stress can be set small. That is, the ratio of discharge speed / supply speed is set to less than 1. The lower limit of this ratio is suitably about 0.9.

The herbicidal sheet of the present invention preferably has a light shielding rate of 95% or more measured according to JIS L 1055. When the light shielding property is less than 95%, it becomes difficult to obtain a sufficient herbicidal effect. In the present invention, assuming that the constituent fibers of the nonwoven fabric have a three-dimensional entangled structure, the single yarn fineness of the constituent fibers is 1 to 15 dtex, the L * value of the weedproof sheet is 40 or less, and the basis weight of the weedproof sheet Is adjusted in the range of 100 to 300 g / m ² , whereby the light shielding rate can be 95% or more. Thereby, it is possible to obtain a sufficient herbicidal effect by suppressing the propagation of weeds.

  If the single yarn fineness of the fiber is less than 1 dtex, the fiber is too thin to achieve the above-mentioned light shielding rate, and the operability is easily impaired in the yarn making process, and the decomposition rate when using a weedproof sheet is too fast. The herbicidal effect tends to be temporary. On the other hand, if the single yarn fineness exceeds 15 dtex, this time, the fiber is too thick to not only achieve the above-mentioned light shielding rate, but also the spun yarn is inferior in cooling property and the flexibility of the resulting nonwoven fabric is impaired. This will interfere with workability when used as a grass sheet. Therefore, the single yarn fineness is more preferably 2 to 12 dtex, and still more preferably 3 to 8 dtex.

If the basis weight of the weedproof sheet is less than 100 g / m ² , the basis weight is not sufficient, so that the above-described shading rate cannot be achieved, and, for example, operability is impaired when three-dimensional entanglement is performed using a needle punch. become. On the other hand, if the basis weight exceeds 300 g / m ² , the basis weight is too large, the decomposition rate when the sheet is biodegraded becomes too slow, and the manufacturing cost of the sheet becomes high.

  In addition, the single yarn fineness of the polylactic acid-based polymer fiber is closely related to the basis weight of the herbicidal sheet. For example, when the single yarn fineness is thin, it becomes a dense sheet even with the same basis weight. Since the mechanical strength decreases rapidly, it is difficult to maintain a sufficient herbicidal effect. Further, when the mechanical strength of the fiber itself is low, it is necessary to increase the single yarn fineness and the basis weight in order to obtain a certain strength as a sheet. The weedproof sheet having a basis weight within the above range may be obtained in one step, or may be obtained by laminating two or more nonwoven fabrics.

  The herbicidal sheet of the present invention preferably has an L * value of 40 or less measured according to JIS Z 8729, for example, by using the original fiber. The L * value represents the lightness, and as the L * value approaches 100, the lightness becomes high and white, while on the other hand, the lightness becomes low and black as the L * value approaches 0. By making the L * value of the herbicidal sheet 40 or less, the light shielding property of the herbicidal sheet can be improved, and the growth of weeds can be hindered by making it difficult to transmit light below the herbicidal sheet. Examples of the method for setting the L * value of the herbicidal sheet to 40 or less include selecting a black pigment such as carbon black. In addition, other pigments may be added according to the laying location, aesthetics, and the like, and the chromaticity may be selected as appropriate to obtain a color such as brown or green. The herbicidal sheet of the present invention preferably has an a * value measured in accordance with JIS Z 8729 in the range of +2 to +10 and a b * value of +2 to +15 as the color tone. By being in this range, it is possible to obtain a weedproof sheet that suppresses the growth of weeds and does not impair the surrounding beauty.

  According to the present invention, by adjusting the single yarn fineness, L * value, and basis weight of the herbicidal sheet of the polylactic acid-based polymer fiber within the above ranges, not only the light shielding rate but also the degradation rate when the sheet biodegrades. Can be controlled.

  In this invention, it is preferable that the tensile strength of the vertical direction (MD direction) of a weedproof sheet is 250 N / 5cm width or more and 850 N / 5cm width or less. If the tensile strength in the longitudinal direction is not 250 N / 5 cm width or more, it is difficult to say that the grass has a practical mechanical strength as a weedproof sheet, and it tends to be broken during construction and tends to be inferior in workability. If the tensile strength in the vertical direction is not 850 N / 5 cm width or less, the sheet becomes hard and impractical as a weedproof sheet. The tensile strength refers to a value measured by a method described later according to JIS L 1906.

  The weedproof sheet of the present invention preferably has a tear strength of 5N or more in consideration of the actual use situation.

The water permeability coefficient of the herbicidal sheet of the present invention is preferably 2.0 × 10 ⁻² cm / sec or more and 1.5 × 10 ⁻¹ cm / sec or less. When the water permeability coefficient is 2.0 × 10 ⁻² cm / sec or more, water due to rainfall or the like can be quickly permeated in the thickness direction of the weedproof sheet without accumulating on the surface of the weedproof sheet. Moreover, when planting using a herbicidal sheet, a sufficient water | moisture content can be replenished to a plant and also spraying of liquid manure is possible. Moreover, when the upper limit of a water-permeability coefficient is 1.5 * 10 < ^-1 > cm / sec or less, it can suppress that the space | gap between the fibers which comprise the sheet becomes too wide, and can maintain light-shielding property. In addition, a water-permeable coefficient is controllable by providing a hydrophilic oil agent to a herbicidal sheet.

  The penetration resistance of the nonwoven fabric in which the constituent fibers of the present invention are three-dimensionally entangled is preferably 10 N or more when measured by the method described below. When it is 10 N or less, for example, a sufficient weed prevention effect may not be exhibited against strong weeds such as chigaya and reed that have strong budding power and a large stem diameter.

  The weedproof sheet of the present invention is formed of a nonwoven fabric, but at least one surface of the nonwoven fabric may be subjected to a surface smoothing treatment. The surface smoothing treatment is performed by passing a nonwoven fabric subjected to needle punching between a pair of flat rolls having a smooth surface. At this time, the surface of the nonwoven fabric can be smoothed by heating at least one of the rolls. Moreover, this can also adjust the thickness of a weedproof sheet. By applying a surface smoothing treatment to the nonwoven fabric, it is possible to prevent the vegetation extending from the ground from protruding from the outer surface of the weedproof sheet, and to provide a good weedproof effect. This surface smoothing treatment may be performed only on one side of the nonwoven fabric or on both sides.

  The fiber form of the fiber made of the polylactic acid polymer is not particularly limited, and the fiber cross section can be a hollow cross section, an irregular cross section, a parallel composite cross section, a multilayer composite cross section, in addition to a normal round cross section. Any cross-sectional shape of the fiber can be adopted depending on the purpose and use, such as a core-sheath type composite cross section and a split type composite cross section.

  Examples of the heterogeneous polymer combined with the polylactic acid polymer in the composite cross section include an aliphatic polyester copolymer having an aliphatic diol, an aliphatic dicarboxylic acid and an aliphatic hydroxycarboxylic acid as constituent components.

  Specifically, aliphatic diols include ethylene glycol, 1,3-propanediol, 1,4-butanediol, 1,5-pentanediol, 1,6 hexanediol, 1,4-cyclohexanediol, 1,4 -Cyclohexanedimethanol.

  Examples of the aliphatic dicarboxylic acid include oxalic acid, succinic acid, glutanic acid, adipic acid, sebacic acid, suberic acid, dodecanedioic acid and the like. You may use the acid anhydride which is these derivatives.

  Aliphatic hydroxycarboxylic acids include lactic acid, glycolic acid, 2-hydroxy-n-butyric acid, 2-hydroxycaproic acid, 2-hydroxyisocaproic acid, 2-hydroxy-3,3 dimethylbutyric acid, 2-hydroxy-3- Examples include methyl lactic acid, leucine acid, 3-hydroxybutyric acid, 4-hydroxybutyric acid, methylbutyric acid, caprolactone, and valerolactone. Of these, lactic acid is preferably used.

  In addition to the above-mentioned fiber cross-section, biodegradation when used as a herbicidal sheet by appropriately selecting a copolymerization ratio or a blend ratio of a polylactic acid polymer and a polymer other than the polylactic acid polymer The speed can be controlled, and a weedproof sheet having a biodegradation speed according to the purpose of use can be obtained.

  Below, the manufacturing method of the weedproof sheet of this invention is demonstrated. The long-fiber nonwoven fabric for constituting the herbicidal sheet of the present invention can be produced by three-dimensionally entanglement of fibers using a needle punch or the like with respect to what is efficiently produced by a so-called spunbond method. That is, the above-described polylactic acid polymer as a main component is heated and melted and discharged from a spinneret, and the obtained spun yarn is cooled using a conventionally known cooling device such as a horizontal spray or an annular spray. After that, it is pulled down with a suction device such as air soccer. Subsequently, after the yarn group discharged from the suction device is opened, it is deposited on a moving deposition device such as a conveyor comprising a screen to form a web. Next, partial temporary thermocompression bonding is performed on the web formed on the moving deposition apparatus using an embossing apparatus or an ultrasonic fusion apparatus. The web subjected to the temporary thermocompression bonding is subjected to a needle punching process, or once the web is wound up, the needle punching process is performed so that the constituent fibers of the web are entangled with each other. By carrying out also in the thickness direction, a nonwoven fabric having a shape maintained is formed.

At this time, it is important that the needle punching condition is 150 punch / cm ² or less for the purpose of setting the load at 10% elongation to 100 N / 5 cm width or less as described above. Is 20 punch / cm ² , and the range is preferably 20 to 150 punch / cm ² from the viewpoint of mechanical properties of the nonwoven fabric and entanglement between fibers. When the punch density is less than 20 punches / cm ² , the entanglement between the constituent fibers is insufficient, and the mechanical properties such as the tearing strength of the nonwoven fabric are not improved. Therefore, the nonwoven fabric is very weak and tends to be fluffy. If the punch density exceeds 150 punches / cm ² , it becomes difficult to set the load at 10% elongation to 100 N / 5 cm width or less as described above, and the fibers are sufficiently entangled with each other. However, mechanical properties such as tensile strength of the nonwoven fabric tend to be inferior. For this reason, the range of 20-60 punch / cm < ² > is more preferable.

  In the present invention, it is preferable that the spun yarn is drawn at a high speed of 1000 to 6000 m / min. When pulling the spun yarn, if the pulling speed is less than 1000 m / min, the oriented crystallization of the polymer does not proceed, the mechanical strength of the resulting non-woven fabric is reduced, or the biodegradation rate is excessively accelerated. To do. On the other hand, when the pulling speed exceeds 6000 m / min, the yarn-making property is abruptly deteriorated, and yarn breakage is likely to occur.

  Next, based on an Example, this invention is demonstrated concretely. However, the present invention is not limited to these examples. In the following examples and comparative examples, each characteristic value was measured by the following method.

(1) Weight per unit area (g / m ² ): 10 pieces each of 10 cm long × 10 cm wide sample pieces were prepared from the nonwoven fabric, and the mass (g) of each sample piece in the standard state was weighed, and the average value of the obtained values Was converted to unit weight per unit area to obtain the basis weight of the nonwoven fabric (g / m ² ).

(2) L * value, a * value, b * value: Color difference meter (manufactured by Minolta: Data processor DP-300, measuring head CR-310), and the basis weight of the sample at the measurement location is 300 g / m ² or more The sheet was folded so that At the time of measurement, the measurement points were changed and four points were measured, and the average values obtained were taken as L * value, a * value, and b * value. In addition, about the thing from which the form of the front and back of a sheet | seat differs, each surface measured two places, and those average values were made into L * value, a * value, and b * value.

  (3) Thickness (mm): Ten sample pieces were prepared and measured based on 6.5 of JIS L 1096.

  (4) Tear strength (N): Ten sample pieces were prepared and measured based on the single tongue method of JIS L 1096.

  (5) Tensile strength (N / 5 cm width) and tensile elongation (%): Measured according to the strip method described in JIS L 1906. That is, 10 sample pieces having a length of 20 cm and a width of 5 cm were prepared, and for each sample, a constant speed extension type tensile tester (Orientec Co., Ltd., Tensilon UTM-4-1-100) was used. The film was stretched at a pulling speed of 200 mm / min, and the average value of the obtained cutting load value (N / 5 cm width) in the machine direction (MD direction) was taken as the tensile strength. The elongation at break was also determined when measuring the tensile strength. That is, at the time of the above cutting, the average value of elongation at break was measured for each of the vertical direction (MD direction) and the horizontal direction (CD direction) of the herbicidal sheet, and a further average value of the two measured average values was broken. It was set as elongation (%).

  (6) Melting point (° C.): Measured with a differential scanning calorimeter DSC-7 manufactured by Perkin Elmer Co., Ltd. at a rate of temperature increase of 20 ° C./min. It was.

  (7) Melt flow rate (g / 10 min): Measured at 210 ° C. and 20.2 N based on ASTM-D1238 (L).

  (8) Fineness (decitex): The fiber diameter in the web state was measured with 50 microscopes, and the average value of fineness obtained by correcting the density was defined as fineness (decitex).

  (9) Light shielding rate (%): Measured by JIS L 1055.6A method.

(10) Permeability coefficient (cm / sec): Based on the constant water level test described in 3.1 (1) of JIS A 1218, assuming a water permeation area of 1 cm ² , a water level of 10 cm, and a water permeation time of 60 sec, the pressure load of JIS L 1908 is 2 kPa. The permeability coefficient was obtained using the thickness test result.

  (11) Penetration resistance (N): A sample is fixed on a sample stage having a through hole having a diameter of 10 mm, and a compression rod passing through the through hole is applied to the sample at a pressing speed of 10 mm / min using a compression tester. The value at the time of pressing and penetrating the sample was defined as the penetration resistance.

  (12) Biodegradability: When the nonwoven fabric is buried in aged compost maintained at about 58 ° C. and taken out after 3 months, the nonwoven fabric does not retain its form or retains its form. However, when the tensile strength exceeded 50% with respect to the initial strength value before burying, it was evaluated as “◯” because biodegradability was recognized. Otherwise, it was evaluated as “x” because no biodegradability was observed.

(13) Herbicidal effect: evaluated as follows.
○: There is no weed breeding and a sufficient weeding effect is recognized. ×: Weeds breed and no weeding effect is observed.

Example 1
When forming the herbicidal sheet, a long fiber nonwoven fabric was prepared by a spunbond method. First, in order to form long fibers, 80% by mass of polylactic acid (D / L = 1.4 mol% / 98.6 mol%) having a melting point of 168 ° C. and a melt flow rate of 65 g / 10 min. A master batch containing 20% by mass of bon black and kneaded was used. Then, the polylactic acid and the master batch are metered and melted so that the pigment is 0.7% by mass in the molten polymer, and the spinning temperature is 210 ° C. and the single hole discharge amount is 1.7 g using a spinneret. Melt spinning was performed under the conditions of / min.

  After the discharged yarn is cooled by a cooling device, it is continuously pulled and thinned at a pulling speed of 5000 m / min by an air soccer provided below the spinneret, and opened using a known opening machine, and moved on a screen conveyor. And collected as a web.

Next, this web was partially thermocompression-bonded through an embossing device composed of an embossing roll and a flat roll having a roll temperature of 110 ° C., and the basis weight composed of long fibers having a single yarn fineness of 3.3 dtex was 100 g / m. ^Two long fiber nonwoven webs were obtained. Two webs obtained were laminated and needle punched under the condition of 45 punches / cm ² to obtain a herbicidal sheet made of a long fiber nonwoven fabric having a thickness of 2.0 mm and a basis weight of 200 g / m ² . Table 1 shows the physical properties, herbicidal effect, and biodegradability of the obtained herbicidal sheet.

Example 2
Compared with Example 1, three webs obtained were laminated, and needle punching was performed on the laminated web having a basis weight of 300 g / m ² . Other than that was carried out similarly to Example 1, and obtained the weedproof sheet | seat of 300 g / m < ² > of fabric weights. Table 1 shows the physical properties, herbicidal effect, and biodegradability of the obtained herbicidal sheet.

  Both Examples 1 and 2 showed a high herbicidal effect. Moreover, since the load at the time of 10% expansion | extension was 100 N / 5cm width or less, it was confirmed that adhesiveness with the ground is high.

Comparative Example 1
Compared to Example 1, the roll temperature of the embossing device was set to 135 ° C. Needle punching was not performed. Other than that was carried out similarly to Example 1, and produced the nonwoven fabric of 200 g / m < ² > of fabric weights, and obtained the weedproof sheet. Table 1 shows the physical properties, herbicidal effect, and biodegradability of the obtained herbicidal sheet. Since the needle punching is not performed, the partial thermocompression bonding state by the partial thermocompression bonding apparatus composed of the embossing roll remains without being released by the needle punching process, so that the pressure welding is sufficiently effective. Compared with 2, the initial load was high, and the elongation decreased. For this reason, the sheet was hard, and when it was laid on the open ground, it was expected to be torn or difficult to follow the “bumps” on the open ground. Therefore, the effect of controlling grass growth (the herbicidal effect) was insufficient.

Claims (4)

  10% measured according to JIS L 1906, which is formed of a non-woven fabric formed by integrating three-dimensional entanglement of the constituent fibers with long fibers mainly composed of a polylactic acid-based polymer. A biodegradable weedproof sheet characterized by having a load at elongation of 100 N / 5 cm or less.   The biodegradable herbicidal sheet according to claim 1, wherein the light shielding rate measured in accordance with JIS L 1055 is 95% or more. Fineness of the long fibers is 1 to 15 dtex, the measured L * value according to JIS Z 8729 is not less than 40, claim 2 basis weight is characterized by a 100 to 300 g / ^{m 2} The biodegradable herbicidal sheet as described. The tensile strength is 250 to 850 N / 5 cm width, the penetration resistance is 10 N or more, and the water permeability measured according to JIS A 1218 is 2.0 × 10 ^{−2 to} 1.5 × 10 ⁻¹ cm / sec. The biodegradable weedproof sheet according to any one of claims 1 to 3, wherein