JP2010017934A - Nonwoven base fabric for reinforcement having sheet of reinforcing fiber filament - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a nonwoven base fabric for reinforcement which does not cause problems such as opening of the mesh even if stitched and formed with a stitching thread. <P>SOLUTION: The nonwoven base fabric for reinforcement is formed by: keeping a sheet of reinforcing fiber filaments, consisting of reinforcing fiber filaments 1 nearly parallelly arrayed, and an auxiliary fiber material 2, that is stacked on the sheet so as to make an angle to the array direction of the reinforcing fiber filaments, retained in shape by stitching threads; and bonding the auxiliary fiber material with the sheet of the reinforcing fiber filaments. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a reinforcing nonwoven fabric having a reinforcing fiber yarn sheet.

  The reinforcing non-woven base fabric is used as a fiber reinforced plastic (FRP) by being compounded with a resin, or used by being stuck to a concrete or mortar surface.

  As such a non-woven base fabric, for example, a reinforced fiber yarn sheet in which a large number of reinforcing fiber yarns such as carbon fibers are aligned is retained with polyester fiber stitching yarns in a direction perpendicular to the alignment direction is disclosed. ing. (For example, patent document 1).

  However, the conventional reinforcing non-woven base fabric retained by the stitch yarn is open or twisted when tension is applied to the non-woven base fabric. “Opening” is also referred to as “missing”, and is a phenomenon in which the interval between reinforcing fibers arranged at a predetermined interval is disturbed. “Twist” is a phenomenon in which the reinforcing fibers arranged with linearity meander and the linearity is lost. For example, when resin processing is performed on a non-woven base fabric, steps such as resin impregnation, drying and winding are performed on the non-woven base fabric. Opening occurs. Further, when the FRP is formed using a non-woven base fabric, tension is applied to the non-woven base fabric, for example, at the time of sheet wiping, resulting in an opening. Even when the nonwoven fabric is directly wrapped around concrete or the like, tension is applied and an opening occurs.

When the opening as described above occurs, the content distribution of the reinforcing fiber in the reinforcing fiber plastic becomes non-constant, resulting in a lack of strength uniformity and stability.
JP 2006-347111 A

  The present invention has been made in view of the above circumstances, and provides a reinforcing non-woven base fabric that does not cause problems such as mesh opening even if it is a reinforcing non-woven base fabric formed by stitching with stitch yarns. With the goal.

  The object is to form a reinforcing fiber yarn sheet composed of reinforcing fiber yarns arranged substantially parallel to each other, and an auxiliary fiber material laminated on the sheet at an angle with the alignment direction of the reinforcing fiber yarns. This is achieved by a reinforcing non-woven base fabric in which the auxiliary fiber material and the reinforcing fiber yarn sheet are fixed.

  The nonwoven fabric for reinforcement of the present invention has a configuration in which a laminate of a fiber reinforced sheet and an auxiliary fiber material is retained by stitching yarns.

  The fiber reinforced sheet constituting the reinforcing non-woven base fabric of the present invention is composed of reinforcing fiber yarns arranged substantially in parallel.

  The reinforcing fiber yarn may be an inorganic fiber yarn or an organic fiber yarn, and may be untwisted or sweet-twisted.

  As the inorganic fiber yarn, a multifilament of inorganic fiber is mainly used. As the inorganic fiber, for example, carbon fiber, glass fiber, boron fiber, steel fiber, or a mixed fiber thereof can be used. The thickness of the fiber yarn may be about 1K to 24K for carbon fiber and about 30 to 5000 tex for glass fiber. The thickness of the inorganic fiber yarn is appropriately set depending on the intended use and required strength. Usually, the carbon fiber is about 3K to 12K, and the glass fiber is about 100 to 3000 tex.

  As organic fiber yarns, multifilaments of organic fibers are mainly used. Examples of organic fibers include high-strength polyethylene fibers, aramid fibers, polyvinyl alcohol fibers, nylon fibers, polyester fibers, polyarylate fibers, PBO (polyphenylenebenzobisoxazole) fibers, natural fibers such as hemp, or mixed fibers thereof. Can be used. The thickness of the fiber yarn may be about 1 to 3000 dtex for high-strength polyethylene fibers and about 1 to 3000 dtex for aramid fibers. The thickness of the organic fiber yarn is also set as appropriate depending on the application and required strength, but is usually 50 to 1500 dtex for high-strength polyethylene fibers and 50 to 2000 dtex for aramid fibers. .

In the reinforcing fiber yarn sheet, the yarns are aligned substantially in parallel. As for the alignment method, there may be regular openings or dense alignment. Basis weight of the sheet, for example, organic fiber yarn sheet 10 to 1000 g / ^{m 2} approximately, inorganic fiber yarn yarn sheet, for example, carbon fibers sheet 10 to 2000 g / ^{m 2,} a glass fiber yarn sheet 10~3000g Adjust within the range of about / m ² . Regardless of whether there is a mesh opening or a close alignment, the size, interval, and arrangement of the openings are arranged regularly.

  In the present invention, “substantially parallel” is used in the sense that it does not have to be strictly parallel to the direction in which the yarn is aligned. In addition, the parallel disturbance that cannot be done in this way is used in the present invention based on the concept of parallelism.

  An auxiliary fiber material is laminated on the reinforcing fiber yarn sheet. The auxiliary fiber material is composed of a monofilament yarn or a multifilament yarn using a composite fiber.

  As the auxiliary fiber material used in the present invention, a multifilament yarn using a composite fiber composed of at least two or more polymers having different melting points is preferably used. A composite fiber is one in which the arrangement of each component in the cross-section exists as a parallel, core-sheath, wood grain, radiation, mosaic, sea island, nebula, and the like. A preferable structure is a two-component two-layer product from the viewpoint of productivity, shape retention and heat-fusibility, and a core-sheath structure. Preferably, it is a composite fiber having a sheath-core structure in which the sheath part is made of a polymer having a melting point lower than that of the core part. Note that the melting point difference is 20 ° C. or higher, preferably 30 ° C. or higher in consideration of productivity. If single-component fibers are used, they may break at the time of heat-sealing. It has never been done when the auxiliary fiber material is cut or deformed. Moreover, since the auxiliary fiber material is flattened by thermocompression bonding, the degree of unevenness in the thickness direction is reduced, and the flatness is excellent. A preferable filament yarn thickness is about 10 to 120 tex, and 20 to 100 tex is preferable in view of shape retention performance and FRP performance. Note that it is possible to use a monofilament yarn using a composite fiber composed of at least two polymers having different melting points.

  Among the composite fibers, from the viewpoint of shape retention performance and productivity, the olefin polymer is preferred as the material for both the low melting point polymer and the high melting point polymer. Particularly preferred is a combination of polypropylene polymer as the high melting point polymer and polyethylene or low melting point polypropylene as the low melting point polymer, that is, a combination of polyolefin polymers in a narrow sense. Preferable structures and materials specifically exemplified are a core-sheath structure and are polypropylene (core part) / polyethylene (sheath part) and polypropylene (core part) / low melting point polypropylene (sheath part).

  The auxiliary fiber material is laminated at an angle with the direction in which the reinforcing fiber yarns are aligned. “At an angle” with respect to the aligning direction of the reinforcing fiber yarns means not parallel to the aligning direction of the reinforcing fiber yarns. The angles are laminated so that the narrow angle formed by the reinforcing fiber yarn and the auxiliary fiber material is larger than 0 degree and smaller than 90 degrees. Preferably, the angle is 15 to 85 degrees, more preferably 20 to 60 degrees. If the angle is too large, it will be difficult to produce a nonwoven fabric, although the effect will not change. Moreover, when the angle is too small, the effect which suppresses an opening and a twist will become thin.

  The auxiliary fiber materials are aligned substantially in parallel. The alignment method may be a regular mesh or may be closely aligned, and is adjusted in the range of 0.2 to 15 lines / inch. When the reinforcing nonwoven fabric of the present invention is used for fiber reinforced plastics, an olefin-based heat-sealed multifilament yarn is used as an auxiliary fiber material, preferably with a basis weight adjusted to about 0.5 to 3 / inch. You just have to do it. Regardless of whether there is a mesh opening or a close alignment, the size, interval, and arrangement of the openings are arranged regularly.

  The specific means for laminating the reinforcing fiber yarn and the auxiliary fiber material is not particularly limited, and a known method and apparatus can be used. For example, warp knitting as described in JP-A-2007-138361 The laminated body of the above-described aspect can be formed using a multi-axis insertion device having a mechanism.

  The laminate of the reinforcing fiber yarn sheet and the auxiliary fiber material configured as described above is stitched together with stitching yarns. Examples of stitching yarns include polyester fiber yarns, nylon fiber yarns, glass fiber yarns, aramid fiber yarns, polypropylene fiber yarns, polyphenylene sulfide fiber yarns, and the like, and polyester fiber yarns and nylon fiber yarns from the viewpoint of productivity and cost. Is preferred. The thickness of the stitching yarn is about 10 to 100 dtex, and 20 to 90 dtex is preferable from the viewpoint of workability in continuous production. Various known methods may be used for the stitching, and the laminated structure of the reinforcing fiber yarn sheet and the auxiliary fiber material is sewn so as not to be greatly deformed, deformed, or destroyed by carrying or carrying. It only has to be. In the present invention, such stitching is expressed as “shape retention”.

  The laminated body of the reinforcing fiber yarn sheet and the auxiliary fiber material retained as described above is heated and pressurized to fix the auxiliary fiber material to the reinforcing fiber sheet. The heating temperature is adjusted within the range of the melting point temperature on the low melting point side of the auxiliary fiber material and lower than the melting point on the high melting point side. The pressure is applied in order to ensure the fixing, and is not particularly limited.

  The reinforcing fiber yarn and the auxiliary fiber material may be fixed in a stage before the reinforcing fiber yarn and the auxiliary fiber material are stacked and retained by the stitching yarn. However, in this case, since a heating / pressurizing step is performed before shape retention with the stitching yarn, there is a problem that a normal multi-axis insertion machine cannot be used as it is. It is preferable that the fixing is performed after the shape-retaining is performed with the stitching yarn.

  The reinforcing non-woven base fabric obtained as described above may be used by laminating a plurality of such base fabrics. At that time, the plurality of laminated base fabrics may be sewn with stitching yarns. As another aspect, a plurality of non-woven base fabrics before the reinforcing fiber yarn and the auxiliary fiber material are fixed may be laminated, and the laminated body may be heated and pressurized to be laminated simultaneously with fixing. As another embodiment, a configuration in which a plurality of laminates of reinforcing fiber yarn sheets and auxiliary fiber materials are laminated and then shaped by stitching yarns and fixed may be used.

  The reinforcing non-woven base fabric of the present invention is produced continuously by laminating the reinforcing fiber yarn and the auxiliary fiber material, retaining the shape of the laminate with the stitching yarn, and fixing the auxiliary fiber material to the reinforcing fiber sheet. It is possible, and those skilled in the art can easily design such a manufacturing process with the above disclosure.

  The non-woven fabric for reinforcement of the present invention is used as a prepreg or FRP by being combined with a resin, or pasted on a concrete or mortar surface. The reinforcing non-woven base fabric of the present invention does not open or twist even when tension or load is applied during use. It is particularly useful in the case of producing a structure or a molded body that is used as a constituent element of the above, and the strength of the structure and the molded body can be stably obtained, and partial unevenness of strength can be prevented.

  The following were used as reinforcing fiber yarns, auxiliary fiber materials, and stitching yarns.

Reinforced fiber yarn: Carbon fiber yarn (trade name: Pyrofil: manufactured by Mitsubishi Rayon Co., Ltd.)
Fiber thread thickness: 12K

Auxiliary fiber material: Olefin-based heat-sealed multifilament yarn (trade name: heat-sealed pyrene, 680d)
The pyrene is a multifilament yarn, and each filament is composed of polypropylene having a melting point of 165 ° C. and a sheath having a melting point of 98 ° C., and has a thickness of 680 denier. 60 filaments. Specific gravity 0.93.

  Stitching yarn: polyester fiber yarn with a thickness of 83 dtex

Example 1
Manufacture of reinforcing non-woven fabric In a multi-axis insertion device equipped with heating and pressure rollers, the reinforcing fiber yarns are aligned at an angle of + 75 ° with respect to the longitudinal direction of the nonwoven fabric and repeatedly hooked on the pins at both ends. The reinforcing fiber yarn was formed into a sheet shape. The reinforcing fiber yarn was driven at 10 pieces / inch.

  Further, the auxiliary fiber material is aligned at -75 ° with respect to the longitudinal direction of the nonwoven fabric, and repeatedly hooked on the pins at both ends, the auxiliary fiber material is aligned on the surface layer side of the reinforcing fiber yarn sheet, and driven at 1 / inch, An auxiliary fiber material was laminated on the fiber reinforced yarn.

  In a state where the reinforcing fiber yarn sheet and the auxiliary fiber material were laminated, the two layers were integrated with the stitching yarn to perform shape retention.

  Next, the laminated sheet thus held is niped from above and below with a pair of heating and pressure rollers (heating temperature: 100 ° C., linear pressure: 3 kg / cm) to melt and fix the low melting point component of the auxiliary fiber agent. And fixed to the reinforcing fiber yarn.

  About the nonwoven base fabric obtained above, processes, such as resin impregnation, drying, and winding, were added and the prepreg was produced. Further, FRP was produced by a sheet winding method. When the obtained prepreg and FRP were confirmed, the non-woven fabric for reinforcement was present without opening as shown in FIG. In FIG. 1, 1 is a reinforcing fiber yarn, 2 is an auxiliary fiber material, and 3 is a stitching yarn.

Comparative Example 2
As a comparison, a non-woven base fabric was prepared in the same manner as in Example 1 except that no auxiliary fiber material was used, and prepreg and FRP were prepared using the non-woven base fabric. As shown in FIG. 2, it was present in a state in which an opening was generated.

Examples 2-4
Non-woven fabrics were produced in the same manner as in Example 1 except that the reinforcing fiber yarns were changed to the following types of fiber yarns, and prepregs and FRPs were produced based on the nonwoven fabrics. The reinforcing non-woven fabric was present in the state shown in FIG. 1 with no openings as in the case of using carbon fibers.

・ Glass fiber: Nitto Boseki Roving 1150tex
・ Aramid fiber: Teijin's “Technora” 167tex
-Polyvinyl alcohol fiber: Kuraray "Vinylon" 200tex

The figure showing the structure of the nonwoven fabric for reinforcement in the prepreg and FRP which were manufactured in the Example. The figure showing the structure of the non-woven fabric for reinforcement in the prepreg and FRP manufactured in the comparative example

Explanation of symbols

1: Reinforcing fiber yarn 2: Auxiliary fiber 3: Stitching yarn

Claims (6)

  A reinforcing fiber yarn sheet composed of reinforcing fiber yarns arranged substantially parallel to each other and an auxiliary fiber material laminated on the sheet at an angle with the direction in which the reinforcing fiber yarns are arranged are retained by stitching yarns, A reinforcing non-woven base fabric in which a fiber material and a reinforcing fiber yarn sheet are fixed.   The reinforcing nonwoven fabric according to claim 1, wherein the reinforcing fiber is an inorganic fiber selected from carbon fiber, glass fiber, boron fiber, steel fiber, or a mixed fiber thereof.   Reinforcing fiber is an organic type selected from high-strength polyethylene fiber, aramid fiber, polyvinyl alcohol fiber, nylon fiber, polyester fiber, polyarylate fiber, PBO (polyphenylenebenzobisoxazole) fiber, hemp fiber, cotton fiber or mixed fiber thereof The reinforcing nonwoven fabric according to claim 1, which is a fiber.   The reinforcing nonwoven fabric according to any one of claims 1 to 3, wherein the auxiliary fiber material is composed of a composite fiber composed of at least two polymers having a difference in melting point.   A prepreg formed using the reinforcing nonwoven fabric according to any one of claims 1 to 4.   A fiber-reinforced plastic formed using the reinforcing nonwoven fabric according to any one of claims 1 to 5.

Images