JP6353757B2 - Sediment evacuation prevention sheet and earth and sand filling bag using the same - Google Patents

Description

  TECHNICAL FIELD The present invention relates to a sediment-sucking prevention sheet that prevents dredged sediment deposited in the vicinity of an estuary from being sucked into the sea when dredging, and a sediment-filling bag body using the same.

  In recent years, in the event of a typhoon or heavy rain, there has been an increase in the amount of sediment that flows from the mountain side to the estuary. In such a place, the water depth becomes shallow, and the river is likely to be flooded or flooded easily. Therefore, civil engineering work (Shun-Setsu) is being carried out to remove the sediment deposited near the river mouth. However, if dredging near the river mouth, the seaweed beds where seaweed grows are destroyed, fish may escape and become unable to settle, and damage to nearby fisheries may occur.

  Under these circumstances, in order to prevent the marine environment from deteriorating when dredging, the creation of tidal flats and seaweed beds, such as putting dredged soil in a bag and sinking it to the seabed, or arranging it on the coast, has been carried out. Various studies have also been made on bags filled with clay. For example, Patent Document 1 describes a bag made of coconut fibers in which at least one of waste wood chips and coal molten ash or converter slag is packed. This sack material is degenerated over 10 years in the sea by coconut fiber, so iron ions eluted from coal melt ash or converter slag filled inside and the fulvic acid in the waste wood chips humated The obtained iron fulvic acid serves as a nutrient for seaweed and achieves water environment conservation. Patent Document 2 describes a bag body that can allow trace elements such as iron, phosphate, and silicate eluted from slag to flow into the sea. In this bag, the slag filled inside elutes the above trace elements into the sea, improves the algae effect, greens the seabed, and breeds fish and shellfish. Patent Document 3 describes a bag-packed dewatering bag in which non-corrosive fiber portions such as polyester fiber filament yarns and corrosive fiber portions such as rayon fiber filament yarns are alternately repeated. This bag body facilitates the growth of plants by corrosive fibers corroding and the bag body having a mesh structure.

JP 2005-034140 A Japanese Utility Model Publication No. 6-55342 Japanese Patent Laid-Open No. 10-018261

  However, the bag body described in Patent Documents 1 and 2 does not provide a substance that can serve as a nutrient for seaweed, and the bag body needs to be filled with contents that can serve as a nutrient for seaweed. . Further, Patent Document 3 is intended to facilitate vegetation by preventing the growth of plants by partially corroding the bag body to form a mesh structure, and does not provide plant nutrients. It was.

  In order to solve the above-mentioned conventional problems, the present invention provides a sediment-sucking prevention sheet capable of providing a substance that can serve as nutrients for aquatic organisms such as algae, seaweeds, and shellfish, and a sediment-filling bag using the same. Provide the body.

The present invention is a regenerated cellulose fiber with respect to the total weight of the nonwoven fabric sheet comprises 10 to 50 wt%, is composed of synthetic fibers with 50 to 90 wt% including nonwoven sheet as other textiles, the regenerated cellulose fibers, the amino acid compound amino acid and / or a plurality of amino acids are formed by connecting a free, non-woven fabric sheet is a initial tensile strength is 10 N / 5 cm or more, to satisfy at least one of the following (I) ~ (II) The present invention relates to a sheet for preventing sediment suction.
(I) The residual ratio of tensile strength after regenerated cellulose fiber decomposition is 50% or more.
(II) The tensile strength after decomposition of the regenerated cellulose fiber is 70% or more of the initial tensile strength × (100−mass content of regenerated cellulose fiber) / 100.
The present invention is also composed of a nonwoven sheet containing 10 to 50% by mass of regenerated cellulose fiber with respect to the total mass of the non-woven sheet and 50 to 90% by mass of synthetic fiber as the other fiber. An amino acid and / or an amino acid compound formed by linking a plurality of amino acids, the non-woven fabric sheet is a laminated non-woven fabric sheet including two or more fiber layers, and at least one fiber layer includes the amino acid and / or plural A first fiber layer containing a regenerated cellulose fiber containing an amino acid compound formed by linking the amino acids, wherein at least one of the fiber layers is a second fiber layer made of synthetic fibers. Regarding the sheet.

  The present invention also relates to a bag for filling earth and sand characterized by sewing the above-mentioned earth and sand sucking prevention sheet. The present invention preferably relates to an earth and sand sucking prevention sheet and an earth and sand filling bag composed of a net-like material.

  The present invention uses a regenerated cellulose fiber containing an amino acid and / or an amino acid compound in which a plurality of amino acids are linked to the earth and sand sucking prevention sheet and the earth and sand filling bag, so that the earth and sand sucking prevention sheet and the earth and sand filling bag itself Can provide amino acids and / or amino acid compounds in which a plurality of amino acids are linked to aquatic organisms such as algae, seaweeds and shellfish (hereinafter referred to as algae). Therefore, when dredging prevention sheet and earth filling bag are used to prevent the earth and sand from being sucked out during dredging, algae and the like are propagated on the earth and sand sucking prevention sheet and earth filling bag itself, Easy to adhere.

FIG. 1A is a schematic perspective view of an earth and sand suction preventing sheet according to an embodiment of the present invention, and FIG. 1B is a partial cross-sectional view thereof. FIG. 2 is a schematic front view of a bag for earth and sand filling according to an embodiment of the present invention. FIG. 3 is a schematic perspective view of a bag for filling earth and sand according to another embodiment of the present invention. 4A is a front view of a bag for filling earth and sand according to another embodiment of the present invention, FIG. 4B is a front view of an inner bag of the bag for filling earth and sand, and FIG. 4C is a bag for filling earth and sand. It is a front view of an outer bag. FIG. 5 is an explanatory view showing a state in which a sediment filling body in which dredged soil is filled in a river is arranged.

  The earth and sand sucking prevention sheet of the present invention can be used to prevent dredging of dredged earth and sand accumulated in the vicinity of the river mouth after dredging and prevent deterioration of the marine environment. The earth and sand suction preventing sheet includes regenerated cellulose fibers containing an amino acid and / or an amino acid compound formed by linking a plurality of amino acids (hereinafter also referred to as “amino acid etc.”). Since the regenerated cellulose fiber has high hydrophilicity and easily retains moisture, the above earth and sand suction prevention sheet is easy to grow algae and the like. In particular, since the regenerated cellulose fiber contains amino acids that are nutrients such as algae, algae and the like are proliferated and attached to the sediment prevention sheet itself, and the algae become a place for spawning and growing small fish. It is possible to prepare an underwater environment where fish can easily settle. In addition, when the regenerated cellulose fiber is corroded, amino acids that serve as nutrients such as algae can be released. In the following, unless otherwise indicated, the regenerated cellulose fiber means a regenerated cellulose fiber containing an amino acid and / or an amino acid compound formed by linking a plurality of amino acids. In the present invention, “a plurality of amino acids” means two or more amino acids.

  The earth-and-sand suction prevention sheet is comprised with the nonwoven fabric sheet which contains regenerated cellulose fiber 10 mass% or more and 90 mass% or less of another fiber with respect to the whole mass of a nonwoven fabric sheet. The other fibers are not particularly limited, but are preferably synthetic fibers. Since the synthetic fiber is hardly corroded, the tensile strength can be maintained even when the regenerated cellulose fiber is corroded. Preferably, the said nonwoven fabric sheet contains 10-50 mass% of regenerated cellulose fibers with respect to the whole mass of a nonwoven fabric sheet, and contains 50-90 mass% of synthetic fibers. More preferably, it contains 15 to 45% by mass of regenerated cellulose fiber and 55 to 85% by mass of synthetic fiber. More preferably, it contains 15 to 40% by mass of regenerated cellulose fiber and 60 to 85% by mass of synthetic fiber.

  Although the said regenerated cellulose fiber is not specifically limited, It is preferable to contain 1-50 mass% of amino acids etc. with respect to 100 mass% of cellulose, More preferably, it contains 3-40 mass%, More preferably, 4-30 mass% Including. When the content of amino acids and the like is within the above range, algae and the like grow and adhere easily while maintaining the strength as a fiber.

  The regenerated cellulose fiber is not particularly limited, but from the viewpoint of durability, the fineness is preferably 0.1 to 100 dtex, more preferably 0.3 to 50 dtex, and 0.5 to 30 dtex. Is more preferable, and 0.5 to 20 dtex is particularly preferable. The regenerated cellulose fiber is not particularly limited, but considering the card passing property, the fiber length is preferably 25 to 65 mm, more preferably 28 to 60 mm, and further preferably 35 to 55 mm. preferable.

  The amino acid is not particularly limited, alanine, arginine, asparagine, aspartic acid, cystine, cysteine, glutamine, glutamic acid, glycine, histidine, isoleucine, leucine, lysine, methionine, phenylalanine, proline, serine, threonine, tryptophan, tyrosine, Examples include valine.

  The amino acid compound formed by linking the plurality of amino acids is not particularly limited, and natural proteins can be used. Examples of natural proteins include gelatin, collagen, casein, soy protein, milk protein, sericin, fibroin and the like. The amino acid compound formed by linking the plurality of amino acids is not particularly limited, but it is preferable to use casein or milk protein. Casein may contain any of alpha casein, beta casein, and carper casein, and preferably contains carper casein. Milk protein is mainly composed of alpha-casein, beta-casein, and carpercasein. Especially, the highly water-soluble kappa casein acts as an amphiphile to form micelles, which stabilizes milk protein in water. Can be supplied as For this reason, when milk protein, especially casein, is used as an amino acid compound formed by linking a plurality of amino acids, amino acids and the like may be dissolved in water, and an environment in which algae and the like are attached to the soil by the sediment prevention sheet is easy to grow. Become. As the amino acid compound formed by linking a plurality of amino acids, it is preferable to use milk and / or skim milk containing milk protein. As the regenerated cellulose fiber containing an amino acid compound formed by linking a plurality of amino acids, for example, rayon fiber “Mire” (trade name) kneaded with skim milk powder from Daiwabo Rayon Co., Ltd. can be used.

  The said synthetic fiber is not specifically limited, For example, a polyester fiber, a nylon fiber, a polyethylene fiber, a polypropylene fiber, a polyvinyl chloride fiber etc. can be used. Polyester fibers are preferably used from the viewpoint of high tensile strength and little change in performance even when water is sucked. As said polyester fiber, a polyethylene terephthalate fiber can be used, for example.

  Although the said synthetic fiber is not specifically limited, From a durable viewpoint, it is preferable that a fineness is 0.1-100 dtex, It is more preferable that it is 0.3-50 dtex, It is 0.5-30 dtex Further preferred is 0.5 to 20 dtex. The synthetic fiber is not particularly limited, but considering the card passing property, the fiber length is preferably 25 to 100 mm, more preferably 30 to 90 mm, and further preferably 35 to 70 mm. .

  In the nonwoven fabric sheet, the form of the nonwoven fabric is not particularly limited, but is preferably a needle punched nonwoven fabric from the viewpoint of excellent tensile strength. A needle punched nonwoven fabric can be obtained by needle punching a fiber web obtained by mixing the regenerated cellulose fiber and the synthetic fiber.

  The nonwoven fabric sheet is a laminated nonwoven fabric sheet including two or more fiber layers, wherein at least one fiber layer is a first fiber layer containing regenerated cellulose fibers, and at least one fiber layer is made of synthetic fibers. A two-fiber layer is preferred. Even when the regenerated cellulose fiber of the first fiber layer is corroded, the shape of the sheet can be maintained by the second fiber layer made of synthetic fiber superior in corrosion resistance compared to the first fiber layer, and the durability is high. high. In the laminated nonwoven fabric sheet, the form of the nonwoven fabric is not particularly limited, but is preferably a needle punched nonwoven fabric from the viewpoint of excellent tensile strength. After laminating a fiber web composed only of regenerated cellulose fibers or a fiber web composed of regenerated cellulose fibers and synthetic fibers and a fiber web composed only of synthetic fibers, a laminated nonwoven fabric sheet is obtained by needle punching treatment. be able to. The laminated nonwoven fabric sheet may include other fiber layers in addition to the first fiber layer and the second fiber layer. Two or more other fiber layers may be provided. The fibers contained in the other fiber layers are not particularly limited, and may include natural fibers and / or synthetic fibers.

  The earth and sand suction prevention sheet may be composed only of a non-woven sheet, and may include a net-like material as necessary. For example, the nonwoven fabric sheet and the net-like material can be laminated and used. The nonwoven fabric sheet and the net-like material may not be integrated, but preferably the nonwoven fabric sheet and the net-like material are laminated and integrated. When the nonwoven fabric sheet is laminated with the net-like material, excellent tensile strength can be obtained due to the reinforcing effect of the net-like material. Lamination integration of a nonwoven fabric sheet and a net-like object can be performed using a hook ring, for example. The net-like material is as described in the description of the earth and sand filling bag described later, and for example, a synthetic resin net, a natural fiber net, and a metal net can be used. In particular, when submerged in water, a metal net that is relatively heavy is preferable from the viewpoint of facilitating settling and stabilization. If it is necessary to handle on the site or be folded when transported, a synthetic resin net is required. In the case where it is desired that the net-like material rots and decomposes after construction, a natural fiber net is preferred.

  Specifically, for example, an earth and sand suction prevention sheet in which a nonwoven fabric sheet and a metal net are laminated and integrated can be used as a rooting material or a sink mat for a wave-dissipating block. FIG. 1 shows an earth and sand suction prevention sheet in which a nonwoven fabric sheet and a metal net are laminated and integrated. FIG. 1A is a perspective view of the earth and sand sucking prevention sheet of the embodiment, and FIG. 1B is a partial cross-sectional view of the earth and sand sucking prevention sheet as viewed from the direction of arrow 5. As shown in FIG. 1A and FIG. 1B, the earth and sand suction prevention sheet 1 includes a nonwoven fabric sheet 2 and a metal net 3, and the nonwoven fabric sheet 2 and the metal net 3 are laminated and provided at appropriate intervals. The hook ring 4 is integrated. Moreover, by disposing a non-woven sheet inside a rectangular parallelepiped basket made of a metal net, it can be used as a futon bowl that can be filled with fine earth and sand.

Non-woven fabric sheet is not particularly limited, it is preferable that the basis weight is 100 to 3000 g / m ^2, more preferably from 200~1500g / m ^2, further preferably 200 to 700 g / m ^2. When the basis weight is in the above range, sufficient tensile strength and durability are exhibited as an earth and sand suction prevention sheet.

  From the viewpoint of excellent durability, the nonwoven fabric sheet preferably has an initial tensile strength of 10 N / 5 cm or more, more preferably 300 N / 5 cm or more, and even more preferably 700 N / 5 cm or more. The upper limit of the initial tensile strength is preferably 2000 N / 5 cm or less, and may be 800 N / 5 cm or less when used by being laminated with a net-like material. In addition, the nonwoven fabric sheet preferably has an initial elongation of 20% or more, more preferably 50% or more, and even more preferably 100% or more. In the present invention, the initial tensile strength and initial elongation are measured as described later.

  The nonwoven fabric sheet preferably has a residual tensile strength after decomposition of regenerated cellulose fibers (hereinafter also referred to as deterioration) of 50% or more, more preferably 70% or more, and 80% or more. Further preferred. If the residual ratio of tensile strength after decomposition of the regenerated cellulose fiber is within the above range, the strength as a sheet can be maintained even if the regenerated cellulose fiber corrodes. In the present invention, the residual tensile strength after decomposition of the regenerated cellulose fiber is measured and calculated as described below.

  In the nonwoven fabric sheet, the tensile strength after decomposition of the regenerated cellulose fiber is preferably 70% or more of initial tensile strength × (100-mass content of regenerated cellulose fiber) / 100, more preferably 80% or more. preferable. The nonwoven fabric sheet having such tensile strength is obtained by needle punching a fiber web, and in particular, a fiber web composed only of regenerated cellulose fibers or a fiber web in which regenerated cellulose fibers and synthetic fibers are mixed, It can be obtained by laminating fiber webs composed only of synthetic fibers and performing needle punching.

<Measurement of initial tensile strength and initial elongation>
The initial tensile strength and initial elongation are measured by a tensile test according to JIS L 1096 8.12.1 A method (strip method) using an absolutely dry sample. Specifically, the earth and sand suction prevention sheet (nonwoven fabric sheet) is cut out to have a width of 5 cm and a length of 15 cm, and the cut nonwoven fabric sheet is dried for 60 minutes with a drier adjusted to 105 ° C. to obtain an absolutely dry sample. . Next, the absolutely dry sample was pulled with a tensile tester (Orientec Co., Ltd., product number “Tensilon UCT-1T”) at a sample width of 5 cm, a distance between gauges of 10 cm, a head speed of 200 mm / min, and the tensile strength and elongation were measured. , And initial tensile strength and initial elongation, respectively.
<Measurement of tensile strength after deterioration and elongation after deterioration>
An absolutely dry sample obtained by the same procedure as above was immersed in 70% sulfuric acid for 4 hours to melt the regenerated cellulose fiber, and the dissolved sample was washed with water, and then dried in a dryer adjusted to 105 ° C. for 60 minutes. dry. According to JIS L 1096 8.12.1 A method (strip method), the obtained deteriorated sample was subjected to a tensile tester (product number “Tensilon UCT-1T” manufactured by Orientec Co., Ltd.) with a sample width of 5 cm and a distance between gauges of 10 cm. Then, pulling at a head speed of 200 mm / min, measuring the tensile strength and the elongation, respectively, the tensile strength after degradation and the elongation after degradation, respectively.
<Remaining ratio of tensile strength after deterioration>
Based on the initial tensile strength obtained by the above measurement and the tensile strength after deterioration, the residual ratio of tensile strength after deterioration is calculated by the following formula.
Tensile strength remaining ratio after deterioration (%) = (Tensile strength after deterioration / initial tensile strength) × 100%

  The earth and sand filling bag of the present invention is formed by sewing the earth and sand sucking prevention sheet into a bag shape. The bag for earth and sand filling can be used for emergency measures in case of flooding and civil engineering work by filling earth and sand inside. If it is used near the river or in the vicinity of the mouth of a river, it is preferable because moss and the like are likely to adhere to the bag body, and an underwater environment where fish can easily live can be quickly prepared. The shape of the earth and sand filling bag body may be appropriately determined depending on the purpose, and is not particularly limited, and examples thereof include a square shape, a cylindrical shape, a prism shape, an inverted cone shape, and an inverted pyramid shape. For example, when it is manually moved after filling with earth and sand, it may be a quadrangle having a length of 40 to 80 cm and a width of 30 to 60 cm. FIG. 2 is a schematic front view of the bag for earth and sand filling according to one embodiment of the present invention. The earth and sand filling bag body of the embodiment can be moved manually after the earth and sand are filled. As shown in FIG. 2, the earth and sand filling bag body 10 is a bag-like shape in which two earth and sand sucking prevention sheets 11 are overlapped, and three sides are sewn along the stitches 12. A closed string 13 for closing the inlet may be provided in the vicinity of the inlet of the earth and sand filling bag 10. Moreover, after filling with earth and sand, when making it move with heavy machines, such as a crane, a bottom face diameter may be 80-140 cm and a cylinder shape with a height of 80-140 cm. FIG. 3 is a schematic perspective view showing a state in which earth and sand filling bags according to another embodiment of the present invention are filled with earth and sand. The earth and sand filling bag according to the embodiment can be used when the earth and sand are moved by a heavy machine such as a crane after the earth and sand are filled. As shown in FIG. 3, the earth and sand filling bag 20 includes a cylindrical storage bag 21 formed by sewing an earth and sand suction prevention sheet, a reinforcing cloth 22 fixed to the storage bag 21 by sewing, and a reinforcement. A suspension belt 23 fixed to the cloth 22 by sewing is included. The storage bag 21 is filled with earth and sand.

  The earth and sand filling bag of the present invention is preferably composed of an earth and sand sucking prevention sheet and a net-like material disposed on the outer side thereof. For example, a synthetic resin net, a natural fiber net, or a metal net can be used as the net. Among them, a synthetic resin net is preferable from the viewpoint of flexibility, easy folding, and excellent handling.

  The earth and sand filling bag of the present invention is more preferably composed of the earth and sand suction preventing sheet and a synthetic resin net. The synthetic resin net is not particularly limited. For example, filament yarns, spun yarns made of synthetic fibers such as polyester fibers, nylon fibers, polyethylene fibers, polypropylene fibers, and polyvinyl chloride fibers, and processed yarns thereof are used as warps. And can be used as a weft. From the viewpoint of high strength and little change in physical properties even when water is sucked, the warp and weft constituting the synthetic resin net are preferably filament yarns made of polyester fibers, and filament yarns made of polyethylene terephthalate fibers. More preferably.

  As the metal net, a wire mesh, a welded wire mesh, an expanded metal or the like obtained by weaving, knitting, or twisting a metal wire can be used. The metal net may be a metal net coated with a vinyl chloride resin or a polyethylene resin, or a metal net plated with aluminum or the like.

  Although the said net-like thing is not specifically limited, It is preferable that the width | variety of a mesh is 1-150 mm, and it is more preferable that it is 3-100 mm. If the width of the mesh is 1 mm or more, algae and the like will not propagate and adhere to the sediment absorption prevention sheet. Moreover, sufficient tensile strength can be acquired as the width | variety of a mesh is 150 mm or less, and the transfer of the bag body for earth and sand filling is easy.

  Based on FIG. 4, the earth and sand suction prevention sheet | seat and the earth and sand filling bag body comprised with the synthetic resin net | network are demonstrated. Specifically, FIG. 4A is a schematic front view of the earth and sand filling bag body, FIG. 4B is a front view of an inner bag of the earth and sand filling bag body, and FIG. 4C is a view of the earth and sand filling bag body. It is a front view of an outer bag. As shown in FIG. 4A, the earth and sand filling bag 100 includes an inner bag 110 and a synthetic resin outer bag 120 disposed outside the inner bag 110. The inner bag 110 is an earth and sand suction prevention sheet formed in a bag shape. An inner bag can be obtained by sewing the earth and sand suction prevention sheet into a bag shape. The synthetic resin outer bag 120 is a synthetic resin net formed in a bag shape. The synthetic resin outer bag 120 can be obtained by sewing the synthetic resin net into a bag shape. That is, the earth and sand filling bag body 100 includes a bag-like earth and sand sucking prevention sheet 110 and a bag-like synthetic resin net 120 disposed outside the bag-like earth and sand sucking prevention sheet 110. Both the inner bag 110 and the synthetic resin outer bag 120 have an inverted conical shape. Since the synthetic resin outer bag 120 is composed of a synthetic resin net, it does not prevent the algae and the like from growing and adhering to the earth and sand suction prevention sheet. Moreover, when the regenerated cellulose fiber in the earth and sand suction prevention sheet corrodes, it does not prevent that an amino acid is discharge | released in water. As shown in FIG. 4A and FIG. 4B, a total of six closing strings 111 for closing the inlets are arranged at regular intervals on the front and back surfaces of the inlet part of the bag-like earth and sand suction prevention sheet 110. Yes. The number and arrangement of the closed strings are not limited to the above and can be determined as appropriate. As shown in FIGS. 4A and 4C, the fixed mouth portion of the bag-shaped synthetic resin net 120 has two fixed mouth restricting ropes 121 around the fixed mouth portion, and a front surface and a back surface. One in the middle part is connected to each other. As shown in FIG. 4B, the bag-shaped earth and sand suction preventing sheet 110 is made larger than the bag-shaped synthetic resin net 120 only by the hatched portion. As shown in FIG. 4A, the bag-shaped earth and sand sucking prevention sheet 110 and the bag-shaped synthetic resin net 120 are fixed by hook-and-loop fasteners 130 on the front and back surfaces. The fixing of the bag-shaped earth and sand suction prevention sheet 110 and the bag-shaped synthetic resin net 120 is not limited to a hook-and-loop fastener, and may be performed by other means, for example, sewing. 4A to 4C show an inverted conical earth and sand filling bag body, but the shape of the earth and sand filling bag body of the embodiment is not particularly limited, and may be a cylinder, a prism, or an inverted pyramid. There may be. The size of the earth and sand filling bag of the embodiment is not limited, and can be appropriately determined according to the purpose. In the case of a cylindrical shape or an inverted conical shape, the diameter (maximum width) of the circle is preferably 200 to 400 cm, and the height is preferably 30 to 100 cm. The bag body for earth and sand filling of this embodiment can be moved with heavy machines, such as a crane, after filling with earth and sand.

  As shown in FIG. 5, after dredging, the dredged sand filling bag 200 filled with dredged sand is disposed in the river to prevent the dredged sand 300 deposited near the estuary from being sucked into the sea. be able to. In addition, since the inner bag of the earth and sand filling bag body 200 is composed of an earth and sand sucking prevention sheet containing regenerated cellulose fibers containing amino acids and the like, algae and the like are propagated and easily attached to the earth and sand sucking prevention sheet itself, Algae, etc. become a place for spawning and nurturing small fish, and it is possible to prepare an underwater environment where fish can easily settle after dredging. In addition, the submarine environment can be adjusted by sinking to the bottom of the sand filling bag body filled with dredged soil. 5 shows a state in which many of the earth and sand filling bags 200 are exposed from the sea surface, it may be a state in which many of the earth and sand filling bags 200 are immersed in seawater.

  Although not shown in the figure, after dredging, the sediment prevention sheet is placed in the river, and the sediment prevention sheet is secured with sand bags, etc., to prevent the dredged sediment deposited near the river mouth from being sucked into the sea. May be. Since the earth and sand sucking prevention sheet contains regenerated cellulose fibers containing amino acids and the like, algae and the like are proliferating and adhering to the earth and sand sucking prevention sheet itself, and the algae become a place for spawning and growing small fish. It is possible to prepare an underwater environment where fish can live easily.

  Hereinafter, the present invention will be described more specifically with reference to examples. In addition, this invention is not limited to the following Example.

The fibers used in Examples and Comparative Examples are shown.
(Fiber A)
Regenerated cellulose fiber containing amino acids and the like: Rayon fiber containing skim milk powder having a fineness of 1.4 denier (1.56 dtex) and a cut length of 38 mm (trade name “Millet”, manufactured by Daiwabo Rayon Co., Ltd., 100% by mass of cellulose) Including 5% by weight of skim milk powder)
(Fiber B)
Synthetic fiber: Polyethylene terephthalate fiber having a fineness of 6 denier (6.67 dtex) and a cut length of 51 mm

Example 1
80 parts by mass of fiber A and 120 parts by mass of fiber B were mixed to prepare a fiber web (hereinafter referred to as a mixed cotton web) having a basis weight of 200 g / m ² . Next, a fiber web (hereinafter referred to as a PET web) having a basis weight of 200 g / m ² made only of the fibers B was produced. Thereafter, the blended cotton web and the PET web were laminated and subjected to needle punching to obtain the nonwoven fabric sheet of Example 1. The obtained nonwoven fabric sheet contained 20% by mass of regenerated cellulose fiber containing amino acids and the like, and the basis weight was 400 g / m ² .

(Example 2)
80 parts by mass of fiber A and 140 parts by mass of fiber B were blended to prepare a blended cotton web having a basis weight of 220 g / m ² . Next, a PET web having a basis weight of 200 g / m ^{2 made} of only fiber B was prepared. Thereafter, the blended cotton web and the PET web were laminated and subjected to needle punching to obtain a nonwoven fabric sheet of Example 2. The obtained nonwoven fabric sheet contained 19% by mass of regenerated cellulose fibers containing amino acids and the like, and the basis weight was 420 g / m ² .

(Example 3)
60 parts by mass of fiber A and 100 parts by mass of fiber B were blended to prepare a blended cotton web having a basis weight of 160 g / m ² . Next, a PET web having a basis weight of 200 g / m ^{2 made} of only fiber B was prepared. Thereafter, a blended cotton web and a PET web were laminated and subjected to needle punching to obtain a nonwoven fabric sheet of Example 3. The obtained nonwoven fabric sheet contained 16.7% by mass of regenerated cellulose fibers containing amino acids and the like, and the basis weight was 360 g / m ² .

(Comparative Example 1)
A PET web having a basis weight of 300 g / m ² consisting only of the fiber B was prepared, and this was subjected to needle punching treatment to obtain a nonwoven fabric sheet of Comparative Example 1. The obtained nonwoven fabric sheet did not contain regenerated cellulose fibers containing amino acids and the like, and the basis weight was 300 g / m ² .

  The initial tensile strength and initial elongation of the nonwoven fabric sheets of Examples and Comparative Examples, the tensile strength after deterioration, and the elongation after deterioration were measured as follows. Moreover, the residual tensile strength ratio after deterioration was calculated as described below. These results are shown in Table 1 below.

<Initial tensile strength and initial elongation>
The initial tensile strength and initial elongation were measured by a tensile test according to JIS L 1096 8.12.1 A method (strip method) using an absolutely dry sample. Specifically, the earth and sand suction prevention sheet (nonwoven fabric sheet) was cut out to have a width of 5 cm and a length of 15 cm, and the cut nonwoven fabric sheet was dried for 60 minutes with a drier adjusted to 105 ° C. to obtain an absolutely dry sample. . Next, the absolutely dry sample was pulled with a tensile tester (Orientec Co., Ltd., product number “Tensilon UCT-1T”) at a sample width of 5 cm, a distance between gauges of 10 cm, a head speed of 200 mm / min, and the tensile strength and elongation were measured. , And initial tensile strength and initial elongation, respectively.
<Tensile strength after deterioration and elongation after deterioration>
An absolutely dry sample obtained by the same procedure as above was immersed in 70% sulfuric acid for 4 hours to melt the regenerated cellulose fiber, and the dissolved sample was washed with water, and then dried in a dryer adjusted to 105 ° C. for 60 minutes. Dried. According to JIS L 1096 8.12.1 A method (strip method), the obtained deteriorated sample was subjected to a tensile tester (product number “Tensilon UCT-1T” manufactured by Orientec Co., Ltd.) with a sample width of 5 cm and a distance between gauges of 10 cm. The tensile strength was measured at a head speed of 200 mm / min, and the tensile strength and elongation were measured. The tensile strength after degradation and the elongation after degradation were measured, respectively.
<Remaining ratio of tensile strength after deterioration>
Based on the initial tensile strength obtained by the above measurement and the tensile strength after deterioration, the residual ratio of tensile strength after deterioration was calculated by the following formula.
Tensile strength remaining ratio after deterioration (%) = (Tensile strength after deterioration / initial tensile strength) × 100%

  The residual tensile strength after deterioration of the nonwoven fabric sheets of Examples 1 to 3 was 85% or more, and it was found that the strength as a sheet could be maintained even when the regenerated cellulose fiber was corroded.

  Moreover, when using the nonwoven fabric sheets of Examples 1 to 3 and Comparative Example 1, a sample of 10 cm in length and 15 cm in width was prepared, put together with seaweed and moss in a water tank, and observed at a temperature of about 20 ° C. for 30 days. Compared with the nonwoven fabric sheet of Comparative Example 1, the nonwoven fabric sheets of Examples 1 to 3 were observed to adhere about twice as much as algae.

  The earth-and-sand sucking prevention sheet and the earth-and-sand filling bag body using the same according to the present invention can be used for preventing dredging of dredged sand by placing it in a river where dredged sand has accumulated after dredging. Moreover, it can be used to provide a place for spawning and growing small fish by breeding and adhering algae by arranging it in a river where dredged soil has accumulated.

DESCRIPTION OF SYMBOLS 1,11 Sediment suction prevention sheet 2 Nonwoven fabric sheet 3 Metal net 4 Hook ring 10, 100 Sediment filling bag body 12 Seams 13, 111 Closed string 20, 200 Sediment filling bag body 21 filled with earth and sand Storage bag (bag shape) Sediment suction prevention sheet formed on
22 Reinforcement cloth 23 Suspension belt 110 Inner bag (Sediment suction prevention sheet formed in a bag shape)
120 Synthetic resin outer bag (synthetic resin net formed in a bag shape)
121 Fixed mouth squeeze rope 130 Hook and loop fastener 300

Claims (7)

Regenerated cellulose fibers with respect to the total mass of the nonwoven fabric sheet comprises 10 to 50 wt%, is composed of synthetic fibers with 50 to 90 wt% including nonwoven sheet as other textiles,
The regenerated cellulose fiber contains an amino acid compound formed by linking amino acids and / or a plurality of amino acids ,
The nonwoven fabric sheet has an initial tensile strength of 10 N / 5 cm or more and satisfies at least one of the following (I) to (II):
(I) The residual ratio of tensile strength after regenerated cellulose fiber decomposition is 50% or more.
(II) The tensile strength after decomposition of the regenerated cellulose fiber is 70% or more of the initial tensile strength × (100−mass content of regenerated cellulose fiber) / 100. Comprises 10 to 50 mass% ck cellulose fibers relative to the total mass of the nonwoven fabric sheet is constructed of synthetic fibers with 50 to 90 wt% including nonwoven sheet as other fibers,
The regenerated cellulose fiber contains an amino acid compound formed by linking amino acids and / or a plurality of amino acids,
The nonwoven fabric sheet is a laminated nonwoven fabric sheet including two or more fiber layers, and at least one fiber layer includes regenerated cellulose fibers containing an amino acid compound formed by linking the amino acid and / or a plurality of amino acids. A sheet for preventing soil and sand sucking out, wherein the sheet is one fiber layer, and at least one of the fiber layers is a second fiber layer made of synthetic fiber . The earth and sand suction prevention sheet according to claim 2, wherein the nonwoven fabric sheet has an initial tensile strength of 10 N / 5 cm or more and satisfies at least one of the following (I) to (II).
(I) The residual ratio of tensile strength after regenerated cellulose fiber decomposition is 50% or more.
(II) The tensile strength after decomposition of the regenerated cellulose fiber is 70% or more of the initial tensile strength × (100−mass content of regenerated cellulose fiber) / 100. The sediment-preventing sheet according to any one of claims 1 to 3, wherein the amino acid compound formed by linking the plurality of amino acids is casein and / or milk protein. The sediment-preventing sheet according to any one of claims 1 to 3, wherein the amino acid compound formed by linking the plurality of amino acids is milk and / or skim milk powder.   The bag for earth and sand filling formed by sewing the earth-and-sand suction prevention sheet of any one of Claims 1-5.   A bag for earth and sand filling comprising the earth and sand sucking prevention sheet according to any one of claims 1 to 5 and a net-like material.

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