JP3213362U - Barrier felt material for decontamination site - Google Patents

Abstract

In a decontamination material accumulation site, a large-format shielding felt material laid inside the accumulation site in order to prevent leakage of contents and prevent contamination outside the field. SOLUTION: An upper mat member 3 containing 50% or more of short fibers having a fineness of 0.8 to 6.6 dt, an intermediate layer 2 which is a nonwoven fabric, needle felt or woven fabric, and short fibers having a fineness of 0.8 to 6.6 dt. By polymerizing the lower mat member 5 containing 50% or more and integrating the whole with a needle punch, the upper mat member 3 having a basis weight of 400 to 700 g / m2, the intermediate layer 2 having a basis weight of 200 to 420 g / m2, and a basis weight of 1100 A three-layer structure of the lower mat member 5 of 1400 g / m 2 is formed. [Selection] Figure 1

Description

  The present invention relates to a large-format shielding felt material laid on the inner side of a decontamination collection site in order to prevent leakage of contents and prevent contamination outside the site.

  In temporary depots and final disposal sites for decontamination work, generally a large amount of decontamination material generated during decontamination work is individually stored in flexible container bags, and then a protective sheet material made of needle felt is grounded together with a water shielding sheet material. Laying on top, stacking many container bags in this place, and covering the whole with shielding sandbags, and then covering the stacked items with light shielding sheet material, prevents deformation of each flexible container bag and leakage of contents Yes. A flexible container bag is a bag-like wrapping material for storing and transporting earth and sand, powder and granular cargo, and is generally called a FIBC (registered trademark) or FIBC bag, which is a strong chemical fiber such as polyethylene or polypropylene. It consists of a bag-like sheet woven with yarn, and a durable suspension belt that supports the entire bag is sewn on the top.

  The decontaminated materials produced in the decontamination work are mixed with various soils with different levels of contamination by radioactive substances. Those with a high level of contamination need to be stored and processed in flexible container bags. For those with a relatively low degree, it is possible to lay a barrier felt material together with a waterproof sheet material on the inner wall of the ground that has been dug down, and to fill the decontamination material directly into this. The method of putting decontaminated materials directly into the collection site eliminates the need to store them in a large number of flexible container bags, making it quicker and cheaper. On the other hand, there is a high risk of radioactive materials leaking out and contaminating the vicinity of the collection site. Therefore, it is necessary to select appropriate physical properties for the shielding felt material spread on the inner wall of the ground.

  As a protection sheet for civil engineering, there is a light shielding sheet disclosed in Japanese Patent Application Laid-Open No. 2000-157947. This light shielding sheet is formed by sequentially laminating a specific light-resistant cloth sheet, a light-resistant fiber web, a reinforcing material cloth sheet, and a cushion material. Therefore, the upper two layers of the light-resistant material in all four layers are very expensive. In addition, the civil engineering sheet disclosed in Japanese Patent Application Laid-Open No. 2005-223017 adheres the air / water permeability control sheet and the light transmitting sheet with a heat-sealing film. The manufacturing process is complicated because it requires heat shrinkage in warm water and has an adhesion process through a heat-sealing film. Moreover, since these sheets are not specified for vertical and horizontal dimensions, it is necessary to weld a large number of sheets when laying them in a large stacking field or the like, even if a plurality of sheets can be welded. The welding work requires a lot of time and labor.

  The present applicant has already proposed Utility Model Registration Nos. 3131316 and 321080 as a light shielding cover material or a protective sheet material for laying used in the temporary storage for decontamination work on these sheets, By integrating polyester fiber wraps with a needle punch, the burner flame does not ignite the felt material when a large number of felt materials are welded in a line shape vertically and horizontally with a burner. The light-shielding cover material disclosed in Utility Model Registration No. 3201316 is relatively thin and used alone, and is not preferable as the shielding felt material in terms of strength. On the other hand, the protective sheet material disclosed in Utility Model Registration No. 3210080 is not used alone, and is similar to the above-described shielding felt material in that it is laid together with a water-shielding sheet material such as polyvinyl chloride.

JP 2000-157947 A Japanese Patent Laid-Open No. 2005-223017 Utility Model Registration No. 3201316 Utility Model Registration No. 3210080

  The protective sheet material disclosed in Utility Model Registration No. 3210080 prevents deformation of the container bag containing the decontaminated material and leakage of the contents in the temporary storage area of the decontamination work, and at the same time protects the lower water shielding sheet material Therefore, the decontamination product in the container bag does not come into direct contact with the protective sheet material during storage. On the other hand, in the decontamination collection site excavated in the ground, when the decontamination product is put into the accumulation site as it is, the decontamination product to which the radioactive material is attached is the shielding felt material on the inner periphery and bottom surface of the accumulation site. You will be in direct contact. This decontaminated material contains sludge-like paste-like waste, broken cement, concrete, and asphalt pieces, and also includes pointed pillars or reinforcing bars. If pointed pillars or reinforcing bars are stabbed into the barrier felt material on the inner and bottom surfaces of the accumulation field, holes will be formed in the barrier felt material, and liquid decontamination will leak out of the accumulation field, causing a pollution accident. There is a fear.

  In order to prevent leakage of liquid decontamination material, it is only necessary to make the structure of the shielding felt material so that it does not have a hole even if it is pierced with a pointed pillar or reinforcing bar. It is desirable to increase the resistance value. Penetration resistance values are tested according to ASTM D 4833-00, measured with a tensile / compression tester equipped with an autograph recorder using a hard steel rod with a diameter of 8 ± 0.1 mm. As a result of various measurement experiments, it was possible to predict that the penetration resistance value necessary for preventing hole opening was 3000 N or more. When the penetration resistance value is 3000 N or more, even if a pointed pillar or rebar pierces the shielding felt material, it cannot penetrate the shielding felt material, so that no hole is formed in the shielding felt material, resulting in a liquid decontamination product. Can be estimated not to leak out of the collection site.

Conventionally, in order to increase the penetration resistance value of the felt material to 3000 N or more, it is estimated that it becomes possible to use three 10 mm-thick needle felts (nonwoven fabrics) in a stacked manner and the total thickness of the three felt materials to be 30 mm. Yes. Generally, a needle felt having a thickness of 10 mm and a weight per unit area of 1000 g / m ² has a penetration resistance value of about 1000 N per sheet. On the other hand, a single needle felt having a total thickness of 30 mm cannot be manufactured using a commercially available needle punching machine when it has such a high weight per unit area.

  In order to increase the penetration resistance value of the needle felt material to 3000 N or more, if three 10 mm thick felt materials are laid, the work time will be greatly extended by performing the laying work three times each time. In order to enable accurate overlapping, it is necessary to limit the width and length of the needle felt material. In addition, since the number of carry-in to the site is tripled, the work of transporting the felt material is greatly increased. In order to stack three needle felt materials and extend them according to the size of the accumulation field, it is necessary to weld each felt material layer. Therefore, it takes a lot of time and labor for the welding work. End up.

  The present invention has been proposed in order to improve the above-mentioned problems that occur when an existing needle felt material is used as a cut-off felt material in an accumulation field, and a mat material even though the penetration resistance value is 3000 N or more. Therefore, it is an object of the present invention to provide a shielding felt material for a decontamination collection site that is easy to lay, transport and lengthen as a whole and has a reduced total cost. Another object of the present invention is that it is a single layer and is lighter, thinner and more flexible than the needle felt material used in three sheets, so it can be easily fitted to the ground shape of the depot, and is used for decontamination sites. It is to provide felt material.

The shielding felt material for decontamination material collection site according to the present invention is a large sheet having a width of 2.5 to 7 m and a length of 30 to 180 m, and includes 50% or more of short fibers having a fineness of 0.8 to 6.6 dt. An intermediate layer which is a mat material, a non-woven fabric, a needle felt or a woven fabric, and a lower mat material containing 50% or more of short fibers having a fineness of 0.8 to 6.6 dt are polymerized and integrated with a needle punch. Blocking felt material of the present invention is to form the upper mat material having a basis weight 400~700g / ^{m 2,} an intermediate layer having a basis weight 200~420g / ^{m 2,} a three-layer structure of the lower mat material having a basis weight 1100~1400g / ^{m 2} The penetration resistance value is 3000 N or more.

In the shielding felt material according to the present invention, the upper mat material and the lower mat material are preferably made of polyester fiber or flame retardant fiber not containing flammable fiber. The intermediate layer is preferably made of a polyester long fiber spunbonded nonwoven fabric. The upper mat member and the lower mat member are preferably composed of 50 to 90% polyester short fibers having a fineness of 0.8 to 6.6 dt and 10 to 50% polyester short fibers having a fineness of 4.4 to 11 dt. Further, the upper mat material has a thickness of 2 to 4 mm and a density of 0.10 to 0.35 g / cm ³ , the intermediate layer has a thickness of 1 to 3 mm and a density of 0.06 to 0.42 g / cm ^3, and the lower mat material has A thickness of 5 to 7 mm and a density of 0.15 to 0.28 g / cm ³ are preferable.

  Since the penetration felt value according to the present invention has a penetration resistance value of 3000 N or more, even if a pointed pillar material or a reinforcing bar is mixed in a decontaminated material containing damaged cement, concrete, asphalt pieces, etc. In addition, they do not pierce the shielding felt material on the inner periphery and bottom surface of the accumulation field, so that the shielding felt material is not perforated, and liquid decontamination material does not leak out of the accumulation field. Since the shielding felt material according to the present invention is a comparatively thin and light long single layer, it is easy to fit the ground shape of the accumulation place even if the wall laying area is large in large-scale construction of the accumulation place. The laying work and transportation are also easy.

  In the shielding felt material according to the present invention, as an upper and lower side mat material, a polyester fiber or a flame retardant fiber wrap is integrated with a needle punch, and the intermediate layer does not contain flammable fibers such as cotton and rayon, The barrier felt material itself exhibits a flameproof function, and when a large number of felt materials are welded in a line vertically and horizontally with a burner to produce a vast shield felt material, the flame of the burner ignites the shield felt material. The risk of doing this can be avoided reliably. Further, when the shielding felt material of the present invention is used, the welding length can be considerably shortened compared with the conventional felt material, and the labor required for this welding work can be saved as much as possible.

It is a schematic sectional drawing which shows the interruption | blocking felt material which concerns on this invention. It is a schematic sectional drawing which shows an example of the accumulation field which spread | interrupted the felt felt material with the water shielding sheet material on the inner wall and bottom wall of the ground dug down. It is a schematic plan view which shows the state at the time of laying the barrier wall material obtained by welding the shield felt material of this invention, and the water-proof sheet material on the bottom face of an accumulation field. It is a schematic plan view which shows the state at the time of laying the barrier wall material obtained by welding another barrier felt material of this invention and the water-proof sheet material on the bottom face of an accumulation field.

  Referring to the drawings, the shielding felt material 1 shown in FIG. 1 is composed of an upper mat material 3 and a lower mat material 5 which are arranged above and below an intermediate layer 2 and are integrated by needling. . The shielding felt material 1 is fitted to the ground shape of the accumulation field 7 (FIG. 2), that is, the inner wall 8 and the bottom surface 10 and spread together with the water shielding sheet material 11, and an appropriate amount of the decontamination material 9 can be stored in the accumulation field. The shielding felt material 1 is a large sheet having an original fabric width of 2.5 to 7 m and an original fabric length of 30 to 180 m, and is larger than the existing felt material, so that the welding work at the time of laying is reduced. The length of 7 m and the length of the original fabric 180 m is the limit that can be produced with the current commercially available needle punching machine.

  In the shielding felt material 1, the mat members 3 and 5 are usually made of short fibers having a fiber length of 51 to 102 mm, and it is easy to obtain desired felt performance within the fiber length range. The mat members 3 and 5 are made of polyester fibers or other flame retardant fibers in addition to the intermediate layer 2, and polyester fibers are advantageous in terms of cost. Normal polyester fibers have a LOI value of about 20 to 21, whereas flame retardant fibers have a LOI value of 26 or more and are not included in the flame retardant fibers, but have some felt density and thickness. From the relationship, flameproof performance can be exhibited. Of course, it is also possible to use a commercially available flame resistant yarn or flame retardant fiber as the flame retardant fiber.

  The mat members 3 and 5 are made of at least two kinds of polyester fibers or flame-retardant fibers having different finenesses, and preferably contain 50% or more of short fibers having a fineness of 0.8 to 6.6 dt. For example, in the mat members 3 and 5, 50 to 90% of polyester fibers of 0.8 to 6.6 dtex and 10 to 50% of polyester fibers of 4.4 to 11 dtex are blended, and another short fiber is blended. It is also possible. At this time, when the polyester fiber of 0.8 to 6.6 dtex is 50 to 90%, the barrier felt material 1 can be imparted with appropriate airtightness and flexibility, and becomes easy to bend. Even if pillar materials or reinforcing bars are mixed, it is difficult to make a hole and it is easy to fit the ground shape of the accumulation place 7. Moreover, when the polyester fiber of 4.4-11 dtex is 10 to 50%, the tensile strength of the shielding felt material 1 can be increased and a certain durability can be imparted. At this time, if the fineness of the polyester fiber is less than 0.8 dtex, a problem is likely to occur in the durability of the shielding felt material 1. On the other hand, if the fineness exceeds 11 dtex, the shielding felt material 1 becomes hard, It is difficult to fit the ground shape, and the workability of laying the felt material is lowered.

Regarding both mat members 3 and 5, the upper mat member 3 has a thickness of 2 to 4 mm and a basis weight of 400 to 700 g / m ² , and the lower mat member 5 has a thickness of 5 to 7 mm and a basis weight of 1100 to 1400 g / m ^2. However, it is of course possible to reverse the upper and lower sides. If the thickness of the upper mat member 3 is 2 mm or the basis weight is less than 400 g / m ² , it is difficult to increase the penetration resistance value of the shielding felt material 1 to 3000 N or more. Is 7 mm or the weight per unit area exceeds 1400 g / m ² , the shielding felt material 1 becomes too thick and the construction work becomes difficult. For the fiber density, the upper mat member 3 0.10~0.35g / cm ^3, when the lower mat material 5 is 0.15~0.28g / cm ³ preferred.

  The polyester fiber used for the mat materials 3 and 5 may be a cation-dyeable polyester fiber having a sulfonic acid group introduced to improve the color development of the yarn, and a cationic dye is bonded to the introduced sulfonic acid group dyeing seat. Let In this case, the polyester fiber can be dyed into two or more colors together with the disperse dye. The polyester fiber may be a latently crimped polyester fiber. Polyester fibers are manufactured by a melt spinning method in which a molten polymer is extruded from a pore die and cooled, so that two types of polymers are simultaneously extruded from the same pore to form a two-component composite fiber, The cross-sectional shape may be modified or hollowed.

  Latently crimped polyester fibers are produced by spinning two-component polyester fibers that differ in heat shrinkage during composite fiber formation. The latent crimped fiber is linear in the same manner as a normal yarn after spinning. When heat is applied to the obtained yarn, the yarn is crimped and becomes a slightly stretchable yarn. In addition, by making the fibers hollow, it is possible to make a cut-off felt material having a small apparent specific gravity and being bulky and light, and in atypical cross section, a triangular cross section can give a texture similar to silk. When the latently crimped polyester fiber is added to the shielding felt material 1, the stretchability and elastic recovery of the mat can be improved.

  The mat members 3 and 5 are substantially made of polyester fiber or flame retardant fiber without adding bristles (collected recycled cotton such as old clothes). A part of other fibers such as acrylic, nylon and PP may be added to the mat members 3 and 5 as long as the flameproof performance is not lowered. Moreover, you may produce the gray and green cut-off felt material 1 which is easy to harmonize with a natural scenery by adding a gray color or green short fiber to part or all. In this case, the polyester fiber is preferable from the viewpoint of flame retardancy, light resistance, tensile strength and cost, and a skin film having a more suitable outer surface and touch feeling can be further bonded at room temperature or by heat treatment.

The intermediate layer 2 is a fiber material such as a nonwoven fabric, needle felt, or woven fabric. When the intermediate layer 2 is a woven fabric, it may be any of plain weave, oblique weave, satin weave, and the intermediate layer itself is required to have flame retardancy. However, polyester, polypropylene, vinylon, aramid fiber or the like can be used, and is preferably made of polyester fiber from the viewpoint of strength and price. If a spunbonded nonwoven fabric of polyester long fibers is used as the intermediate layer 2, needling is possible even if it is as dense as 1 to 3 mm in thickness and 200 to 420 g / m ² in weight, and it is also a shielding felt material. It is preferable for increasing the penetration resistance value of 1. Even when needle felt is used, it is desirable that the physical properties are substantially the same.

As the other intermediate layer 2, a woven fabric of polyester fiber can be used. However, if the basis weight is around 180 g / m ² , the penetration resistance value of the felt material becomes around 3000 N, and further, during the needling. Care must be taken because needle breakage increases. In addition, inexpensive woven fabrics of polypropylene fibers may be used as the intermediate layer 2 because they are not related to light resistance. However, if the basis weight is around 75 g / m ² , the penetration resistance value does not reach 3000 N. It is necessary to superimpose 3 sheets or to select one having a higher basis weight or thickness.

Intermediate layer 2 is, in the case of spunbonded filament nonwoven fabric, the basis weight thickness in 1~3mm is the 200~420g / ^{m 2,} and preferably is basis weight 300 g / ^{m 2} or more, for blocking felt material 1 As a result, the penetration resistance value can be increased to 3000 N together with the mat members 3 and 5 regardless of the ground shape and geology of the accumulation field 7. In the intermediate layer 2, if the thickness is 1 mm or the basis weight is less than 200 g / m ² , the mat layers 3 and 5 are weak as the support layer, whereas if the thickness is 3 mm or the basis weight exceeds 420 g / m ² , the intermediate support is provided. It becomes too thick as a layer, and the shielding felt material 1 becomes difficult to bend during construction. Regarding the fiber density, the intermediate layer 2 is preferably 0.06 to 0.42 g / cm ³ .

  The shielding felt material 1 has a width of 2.5 to 7 m, preferably a width of 3.5 to 7 m, and is considerably wider than a general needle felt material having a width of 2 m. When the mat width is less than 2.5 m, the advantage of reducing the welding work is less than that of a conventional felt material having a width of 2.5 m or less. For example, when laying on the bottom surface 10 of the stacking field 7 having a width of 20 m, if the mat width is 3.5 m as shown in FIG. 3, the number of welding wires 12 is reduced to five, and the mat width is 2 as shown in FIG. When it is 0.5 m, there are seven welding wires 12 in the vertical direction. On the other hand, if the mat width is 3.5 to 7 m, the number of welding lines can be further reduced, and if the mat width exceeds 7 m, the existing large needle punching machine cannot be manufactured.

  The shielding felt material 1 has a length of 30 to 180 m, preferably 85 to 180 m, and is very long compared to a general needle felt material having a length of less than 20 m. If the mat length is less than 30 m, the number of cases in which the welding work in the horizontal direction is required when laying the stacking field 7 increases. For example, when laying on the bottom of an accumulation field having a length of about 85 m, if the mat length is 85 m as shown in FIG. 3, there is no need to weld in the lateral direction, and the mat length is as shown in FIG. When it is 30 m, there are two welding wires 14 in the lateral direction. On the other hand, when the mat width is 85 to 180 m, it is advantageous when constructing a larger accumulation field, and when the length exceeds 180 m, The winding diameter of the mat becomes too large, making it difficult to carry the truck.

  The shielding felt material 1 is formed by polymerizing the upper mat material 3, the intermediate layer 2, and the lower mat material 5 made of polyester fiber or flame retardant fiber, and entangles the whole with only a needle punch so as to be integrated. It is relatively flexible as a whole. If necessary, the shielding felt material 1 is resistant to the short fibers constituting the mat materials 3 and 5 in order to attach a thin woven cloth on the surface or to improve the light resistance and light shielding property of the shielding felt material. It is also possible to knead an oxidizing agent or an ultraviolet absorber, or to apply or spray a resin solution such as an antioxidant on the surface.

  In order to manufacture the shielding felt material 1, the mat material is cross-laminated to a predetermined thickness with a cross wrapper after carding, and the intermediate layer 2 is interposed between the obtained mat materials 3 and 5. Next, the upper and lower mat members 3 and 5 stacked in a cross manner are needle-punched from the upper and lower directions with a needle punching machine, and the whole is intertwined and integrated. In this needle punching, for example, it is desirable to carry out with a high needle density using a normal rocking needle.

  Since the penetration resistance value of the shielding felt material 1 is 3000 N or more, if it is laid together with the water shielding sheet material 11 on the inner wall 8 and the bottom surface 10 of the accumulation field 7, the decontaminated material containing damaged cement, concrete pieces, etc. Even if pillar materials or reinforcing bars with sharp points are mixed and they pierce the blocking felt material 1 on the inner wall 8 and the bottom surface 10 of the accumulation field 7, no holes are formed in the blocking felt material. Since there is no hole in the shielding felt material 1 after laying, liquid decontamination material does not leak out of the accumulation field from the accumulation field 7.

  The shielding felt material 1 includes mat materials 3 and 5 of polyester fiber or flame retardant fiber and an intermediate layer 2, and since it has a tensile strength of 140 N / 5 cm or more, it is difficult to break during use. Since the layer 2 is interposed, the breaking strength and the dimensional stability are improved. Further, even if the shielding felt material 1 is about 8 to 14 mm in thickness as a sheet for decontamination collection site and is relatively light and thin, wear, damage and deterioration hardly occur under normal use conditions. It is easy to fit the ground shape, and its laying work and transportation are easy.

Next, this invention is demonstrated based on an Example. For the upper mat material, white polyester fiber having a fineness of 3.3 dt and a fiber length of 51 mm is 40% by weight, black polyester fiber having a fineness of 3.3 dt and a fiber length of 64 mm is 30% by weight, black having a fineness of 6.6 dt and a fiber length of 64 mm 30% by weight of polyester fiber is used. After blending the three kinds of short fibers, carding is performed through a card machine, and the whole is cross-stacked with a cross wrapper, whereby a polyester fiber 100 having a thickness of 3 mm, a basis weight of 500 g / m ² and a density of 0.167 g / cm ³ is obtained. % Of the upper mat member 3 is obtained.

For the lower mat material, 40% by weight of white polyester fiber having a fineness of 3.3 dt and a fiber length of 51 mm, 30% by weight of black polyester fiber having a fineness of 3.3 dt and a fiber length of 64 mm, and a fineness of 6.6 dt and a fiber length of 64 mm 30% by weight of black polyester fiber is used. After blending the three kinds of short fibers, carding is performed through a card machine, and the whole is cross-laminated with a cross wrapper, whereby a polyester fiber 100 having a thickness of 6 mm, a basis weight of 1200 g / m ² and a density of 0.200 g / cm ³ is obtained. % Lower mat material 5 is obtained.

Further, as the intermediate layer 2, polyester fiber long fiber spunbond (trade name: Acster Mantle, manufactured by Toray Industries, Inc.) is used. The intermediate layer 2 has a thickness of 2 mm, a basis weight of 300 g / m ² , and a density of 0.150 g / cm ³ . The tensile strength of the intermediate layer 2 is 785 N / 50 mm in both length and width, and the elongation is 50 to 55% in both length and width.

Next, after the intermediate layer 2 is disposed between the upper mat member 3 and the lower mat member 5, the fibers are entangled by needle punching from above and below with a large needle punching machine, and the whole is integrated, At this time, the needle density is increased to sufficiently entangle the fibers. The obtained shielding felt material 1 becomes a single layer as shown in FIG. 1 and has an original fabric width of 3.7 m × an original fabric length of 85 m, a thickness of 11 mm, a basis weight of 2000 g / m ² , and a density of 0.182 g. / Cm ³ . Since the shielding felt material 1 is integrated only by a needle punch and is a non-heat-treated product, the whole is relatively flexible.

  The physical property requirement values for the shielding felt material 1 are as shown in Table 1 below. Since the penetration resistance value of the shielding felt material 1 is 3390N, the penetration resistance value conforms to 3000N or more. Moreover, the result of a flameproof performance test is as Table 2, and it is clear that the shielding felt material 1 has heat resistance.

  The obtained shielding felt material 1 has an original fabric width of 3.7 m × an original fabric length of 85 m, and a winding weight of one piece is 629 kg. As shown in FIG. 3, the shielding felt material 1 includes six shielding felt materials 1 in the five vertical directions so that they can be laid on the bottom surface 10 of the accumulation field 7 having a width of about 20 m × length of about 85 m. Are bonded together in parallel with each other and are laid on the water-impervious sheet material 11. When the shielding felt material 1 is laid on the inner wall 8 and the side surface 10 of the stacking field 7, the welding length is shortened as a whole, and the efficiency and safety of the felt material laying work can be greatly improved. The use of the large-size blocking felt material 1 can greatly shorten the time required for several days, which was necessary with conventional needle felt materials. Including the work efficiency is greatly improved.

  Since the penetration resistance value of the shielding felt material 1 is 3390 N, when the barrier felt material 1 is laid on the inner wall 8 and the bottom surface 10 of the collection field 7 together with the water shielding sheet material 11, it is first applied to a decontaminated material containing damaged cement or concrete fragments. Even if a sharp pillar material or a reinforcing bar is mixed and pierces the barrier felt material 1 on the inner wall 8 and the bottom surface 10 of the accumulation field 7, no hole is formed in the shield felt material. Since a hole is not opened in the shielding felt material 1 after laying, liquid decontamination material does not leak out of the accumulation field from the accumulation field 7.

  In order to compare with the shielding felt material 1 manufactured in Example 1, the manufacturing examples of the felt material in which the penetration resistance value reaches around 3000 N will be listed. These felt materials are not merely comparative examples, but it can be estimated that they can be used as the shielding felt material of the present invention by slightly increasing the amount of fiber and the thickness of the intermediate layer or both mat materials.

Modification 1
The mat members 3 and 5 manufactured in Example 1 are used. The intermediate layer is a woven fabric of 180 g / m ² polyester fiber (high strength base fabric for civil engineering, manufactured by Ayaba Industries). This intermediate layer is disposed between the upper mat member 3 and the lower mat member 5, and the fibers are entangled by needle punching from above and below to integrate the whole. At this time, the fiber density is increased by increasing the needle density. Engage well. The obtained needle felt material is a single layer having a thickness of about 10 mm and a basis weight of 1880 g / m ² . Since needle breakage is likely to occur during needling, caution is required for mass production.

  The penetration resistance value of the shielding felt material 1 is 3020N, and it barely fits the penetration resistance value of 3000N or more, but there is a possibility that it will drop below 3000N when the basis weight of each layer touches the lower limit. It is desirable to ensure that the penetration resistance value is 3000 N or more by appropriate processing such as an increase in basis weight or the use of two base fabrics.

Modification example 2
The mat members 3 and 5 manufactured in Example 1 are used. The intermediate layer is a woven fabric of 75 g / m ² polypropylene fiber. This intermediate layer is disposed between the upper mat member 3 and the lower mat member 5, and the fibers are entangled by needle punching from above and below to integrate the whole. At this time, the fiber density is increased by increasing the needle density. Engage well. The obtained needle felt material is a single layer having a thickness of about 9 mm and a basis weight of 1775 g / m ² .

  The penetration resistance value of the shielding felt material 1 is 2930N, which does not conform to the penetration resistance value of 3000N or more. However, the penetration resistance value can be increased to 3000N or more by appropriate treatment such as increasing the weight per unit or using two pieces of fabric. There is.

Modification example 3
For the upper and lower mat members, 40% by weight of white polyester fibers having a fineness of 17 dt, 30% by weight of black polyester fibers having a fineness of 6.6 dt, and 30% by weight of polyester fibers of various colors are used. After blending the three kinds of short fibers, carding is performed through a card machine, and the whole is cross-stacked with a cross wrapper. The upper mat material has a basis weight of 500 g / m ² and the lower mat material has a basis weight of 1200 g / m ² .

The intermediate layer is a long fiber spunbond of polyester fibers having a basis weight of 300 g / m ² as in Example 1. The intermediate layer is disposed between the upper mat member and the lower mat member, and the fibers are entangled by needle punching in the vertical direction to integrate the whole. The obtained needle felt material is a single layer having a thickness of about 15 mm and a basis weight of 2000 g / m ² .

  The penetration resistance value of the shielding felt material 1 is 2740 N, and does not conform to the penetration resistance value of 3000 N or more. If appropriate treatment such as weight increase of the intermediate layer or the like is possible, the penetration resistance value may be 3000 N or more, but the weight of the lower mat material is a limit value in the mass production line.

Modification example 4
The upper and lower mat materials manufactured in Modification Example 3 are used. The intermediate layer is the same as in Modification Example 1. The intermediate layer is disposed between the upper mat member and the lower mat member, and the fibers are entangled by needle punching in the vertical direction to integrate the whole. The obtained needle felt material is a single layer having a thickness of about 12 mm and a basis weight of 1880 g / m ² .

  The penetration resistance value of the shielding felt material 1 is 2850N, and does not conform to the penetration resistance value of 3000N or more. If appropriate treatment such as weight increase of the intermediate layer or the like is possible, the penetration resistance value may be 3000 N or more, but the weight of the lower mat material is a limit value in the mass production line.

Modification example 5
The upper and lower mat materials manufactured in Modification Example 3 are used. The intermediate layer is the same as in Modification Example 2. The intermediate layer is disposed between the upper mat member and the lower mat member, and the fibers are entangled by needle punching in the vertical direction to integrate the whole. The obtained needle felt material is a single layer having a thickness of about 12 mm and a basis weight of 1775 g / m ² .

  The penetration resistance value of the shielding felt material 1 is 2270N, and does not conform to the penetration resistance value of 3000N or more. It is difficult to increase the penetration resistance value to 3000 N or more even if an appropriate treatment such as weight increase of the intermediate layer is performed.

Modification 6
The upper and lower mat materials manufactured in the modified example 3 are used, and the basis weight is 1000 g / m ² for both the upper and lower mat materials. Use the same middle layer as the second modification. Two intermediate layers are arranged between the upper mat member and the lower mat member, and the fibers are entangled by needle punching in the vertical direction to integrate the whole. The obtained needle felt material is a single layer having a thickness of about 15 mm and a basis weight of 2150 g / m ² .

  The penetration resistance value of the shielding felt material 1 is 2700 N, and does not conform to the penetration resistance value of 3000 N or more. If an appropriate treatment such as an increase in weight per unit area is possible, the penetration resistance value may be increased to 3000 N or more.

DESCRIPTION OF SYMBOLS 1 Barrier felt material 2 Intermediate | middle layer 3 Upper mat material 5 Lower mat material 7 Stacking place 12, 14 Welding wire

Claims (5)

An upper mat material, non-woven fabric, needle felt or woven fabric having a width of 2.5 to 7 m and a length of 30 to 180 m and comprising 50% or more of short fibers having a fineness of 0.8 to 6.6 dt An upper mat having a basis weight of 400 to 700 g / m ² by polymerizing a lower mat material containing 50% or more of short fibers having a fineness of 0.8 to 6.6 dt and integrating the whole with a needle punch wood, intermediate layer having a basis weight 200~420g / ^{m 2,} a basis weight 1100~1400g / ^m to form a three-layer structure of the lower mat member ^2, penetration resistance of at least 3000N dividing dyeing blocking felt material for the dump .   The shielding felt material according to claim 1, wherein the upper mat material and the lower mat material are made of polyester fiber or flame retardant fiber not containing flammable fiber.   The shielding felt material according to claim 1, wherein the intermediate layer is made of a spunbond nonwoven fabric of polyester long fibers.   The upper mat material and the lower mat material are composed of 50 to 90% polyester short fibers having a fineness of 0.8 to 6.6 dt and 10 to 50% polyester short fibers having a fineness of 4.4 to 11 dt. Cut-off felt material. The upper mat material has a thickness of 2 to 4 mm and a density of 0.10 to 0.35 g / cm ³ , the intermediate layer has a thickness of 1 to 3 mm and a density of 0.06 to 0.42 g / cm ^3, and the lower mat material has a thickness The shielding felt material according to claim 1, which has a density of 5 to 7 mm and a density of 0.15 to 0.28 g / cm ³ .

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