JP4830480B2 - Polyester woven and knitted fabric for fused net reinforcement - Google Patents

Description

The present invention relates to a polyester woven fabric or knitted fabric for a fused network reinforcing material capable of easily producing a polyester fused network reinforcing material having a bursting strength superior to that of the conventional one, and a rupture superior to the conventional one easily obtained thereby. The present invention relates to a polyester fused net reinforcing material having strength .

  Polyester woven and knitted fabrics are currently widely used in clothing applications, and in recent years, they are also widely used in industrial material applications such as car interior materials such as car seats and seat belts.

  In recent years, the demand for water treatment membranes has been increasing from the viewpoint of securing water resources, but from the viewpoint of the strength of membrane materials, water treatment membranes consisting only of synthetic resin films cannot provide strength that can withstand practical use. It has been put into practical use by forming a composite film with a base fabric made of fibers. Among them, a fused network made of a polyester woven or knitted fabric is excellent in terms of uniformity of quality and cost, and is particularly frequently used.

  However, it is also a fact that the polyester woven and knitted fabric for the fused network and the fused network made thereof have problems in productivity and quality due to the difficulty of the production process.

  In general, a polyester woven or knitted fabric for a fusion network is required to have a bursting strength as a woven or knitted fabric because a heat treatment for the fusion is performed when forming the fused network. Moreover, since it is necessary to permeate | transmit a liquid when using for a water treatment film | membrane etc., it is not suitable even if the structure | tissue of a weave or knitting is too fine.

  In order to solve this problem, a blended yarn of nylon and low-melting polyester has been proposed (for example, see Patent Document 1). However, in order to use nylon and polyester together, a process of blending after spinning a multifilament is performed. Cost is high and handling is difficult.

  In addition, polyester fusion yarns in which polyester multifilaments are fused from the beginning have also been proposed (for example, see Patent Document 2), but in this case, quality control in the process of producing the fusion yarn is difficult, Also, it is not desirable in terms of cost. In addition, there are many portions of the fusion network that are fused in the state of the initial yarn, and when this is further fused as a woven or knitted fabric, there are too many fusion points, so the bursting strength of the network is high. It is not preferable because it greatly decreases.

As described above, the conventional technology has not yet obtained a sufficient product satisfying the bursting strength of the multifilament manufacturing process, quality control, and the resulting woven or knitted fabric and the fusion network obtained therefrom.
JP 54-15021 A (first page) JP 2000-303287 A (page 2)

The present inventors have strong rupture better than conventional, and the liquid intensively studied the transmitted causing performance sustainable fusing network reinforcement for polyester woven or knitted fabric, a polyester woven ablative destination network reinforcing material of the present invention It has reached a knitted fabric and a fused net reinforcing material using the same. That is, an object of the present invention is to provide a polyester woven or knitted fabric for a fused network reinforcing material and a fused network reinforcing material that have an excellent bursting strength and can maintain the performance of permeating liquid such as a water treatment membrane. There is to do.

In order to solve the above problems, the present invention adopts the following configuration. A woven or knitted fabric composed of mixed yarns of two different polyester multifilament yarn groups A and B having a difference in boiling water shrinkage of 10 to 50%, and the boiling water shrinkage of the mixed yarn is 10 to 30 %, When the woven or knitted fabric of 10 cm square is observed in a state where it is pulled with a force of 2 N in both the longitudinal and transverse directions, the contact points between the multifilaments are 0.4 to 32 pieces / mm ² , and the porosity is 0.7 to A polyester woven or knitted fabric for a fused net reinforcement characterized by being 15%.

Further, the fusion network of the present invention is a fusion network composed of polyester multifilaments, and the multifilaments when observed in a state where the fusion network of 10 cm square is pulled with a force of 2N in both the vertical and horizontal directions. The contact point is 0.5 to 40 pieces / mm ² , and the porosity is 0.5 to 10%.

By using the polyester woven or knitted fabric for the fused network reinforcing material of the present invention, it is possible to obtain a fused network reinforcing material that has superior bursting strength and can maintain the performance of allowing liquid such as a water treatment membrane to pass through.

The polyester woven or knitted fabric for the fused network reinforcing material of the present invention is a woven or knitted fabric made of polyester multifilaments, and the multifilament is observed when the 10 cm square knitted fabric is observed with a 2N force in both the longitudinal and lateral directions. The contact point between them is 0.4 to 32 pieces / mm ² , and the porosity is 0.7 to 15%. When the contact point is less than 0.4 pieces / mm ² , the mesh of the woven or knitted fabric is coarse, which is not suitable for practical use as a net when a fused net is used. That is, when bonded to a film, problems such as the film biting into the mesh and forming large irregularities occur. Further, when the number of contact points is more than 32 pieces / mm ² , the mesh of the woven or knitted fabric is too fine. Therefore, when a fused net is used, the mesh is too fine, and there are many points that are fused due to friction at the contact point during the fusion treatment. Since it is too much and the bursting strength is remarkably lowered, it is not suitable for practical use as a net. Preferably 1-15 / mm ^2. Further, when the porosity is less than 0.7%, it is only a simple woven or knitted fabric, and does not have the performance as a net as a fused net. That is, in applications such as filtration membranes, when bonded to a film, the eyes are too fine, and the role of the membrane, that is, the mass transfer between the front and back of the membrane becomes difficult. When the porosity is greater than 15%, the woven or knitted fabric is coarse, and the bursting strength in the case of a fused network is lowered, which is not suitable for practical use as a network. Preferably it is 0.7 to 10%.

It is preferable that the polyester multifilament constituting the polyester woven or knitted fabric for the fused net reinforcement of the present invention is a mixed yarn in which the polyester multifilament is composed of two different yarn groups A and B. In the case of a single type of multifilament, the heat treatment temperature for forming the fusion network needs to be a temperature at which the multifilament can be fused, so that the fusion proceeds excessively and the bursting strength as the fusion network is increased. May decrease.

In the two different polyester multifilament yarn groups A and B constituting the polyester woven or knitted fabric for the fused net reinforcement of the present invention, the difference in melting point between the yarn groups A and B is preferably 10 to 80 ° C. When the difference in melting point is less than 10 ° C., the heat treatment temperature when forming the fused network needs to be close to the melting point of the yarn group having a low melting point among the yarn groups A and B, so that the fusion is excessive. In some cases, the bursting strength of the fused network may decrease. When the difference in melting point exceeds 80 ° C., the melting point of the yarn group having a low melting point among the yarn groups A and B becomes extremely low, or the melting point of the yarn group having a high melting point becomes extremely high. In this case, the bursting strength in the case of using a fused network may be reduced, and in the latter case, the texture in the case of using a woven or knitted fabric and the fused network may be hardened. From these viewpoints, the difference in melting point between the yarn groups A and B is more preferably 20 to 60 ° C.

In two different polyester multifilament yarn groups A and B constituting the polyester woven or knitted fabric for the fused net reinforcement of the present invention, the ratio of the single yarn (single filament yarn) fineness of the yarn groups A and B is 3: 7 to 7: 3 is preferable. When the ratio of the single yarn fineness is outside the range of 3: 7 to 7: 3, the yarn group having a small single yarn fineness may cause yarn breakage when forming the fused network, which may be a defect of the fused network.

In the two different polyester multifilament yarn groups A and B constituting the polyester woven or knitted fabric for the fused net reinforcement of the present invention, the difference in boiling water shrinkage between the yarn groups A and B is 10 to 50%. There is a need . When the difference in boiling water shrinkage is less than 10%, in the multifilament yarn groups A and B, the filaments constituting each of them easily align in parallel. Since it becomes difficult to generate a landing point, it is not preferable. Further, if the difference in boiling water shrinkage exceeds 50%, the yarn length difference due to the shrinkage difference between the yarn groups A and B becomes too large during the heat treatment for forming the fused network, and therefore the yarn group having a small shrinkage rate. yarn length ing and disadvantages to become jump out fuse network in a loop longer.

Moreover, the entanglement degree of the mixed yarn which consists of two different polyester multifilament yarn groups A and B which constitute the polyester woven or knitted fabric for the fused net reinforcement of the present invention should be 5 to 50 / m. preferable. When the degree of entanglement is less than 5 / m, the processability of weaving or knitting when forming a polyester woven or knitted fabric for a fused network may be lowered. In addition, when it exceeds 50 pcs / m, the above-mentioned process passability is not a problem, but since there are many contact points between filaments, there are too many fusion points when the fusion network is used, Burst strength may decrease.

Further, the boiling water shrinkage of the mixed yarn comprising two different polyester multifilament yarn groups A and B constituting the polyester woven or knitted fabric for the fused net reinforcement of the present invention needs to be 10 to 30%. There is . If boiling water shrinkage is less than 10%, shrinkage less entanglement of filaments constituting the polyester multifilament upon formation of the fused network for small, have such suitable for practical use as a network. In addition, when the boiling water shrinkage rate exceeds 30%, the shrinkage is large, so that the filaments constituting the polyester multifilament are too entangled in the fusion network, and the bursting strength as the fusion network is lowered. The

The mixed yarn comprising the two different polyester multifilament yarn groups A and B constituting the polyester woven or knitted fabric for the fused net reinforcement of the present invention is a yarn in which the yarn groups A and B are discharged from the same nozzle. Polyester multifilaments obtained by spinning and mixing strips are preferred. The present invention is not limited to this, but the mixed yarns in which the yarn groups A and B are discharged from the same base and spun and mixed are discharged after the yarn groups A and B are discharged from the separate base. Compared to the mixed fiber, the yarn groups A and B are entangled, which is preferable in terms of generating a fusion point when forming a fusion network.

The polyester woven or knitted fabric for the fused network reinforcing material of the present invention can be applied to plain woven fabric, satin weaving fabric and the like as woven fabrics, and the knitted fabric can be any of flat knitting, warp knitting and circular knitting. However, it is not limited to these.

Polyester fused network reinforcement member of the present invention, a 10cm square said fusing network reinforcement longitudinal contact points of the multi-filaments of when observed both laterally in a state of pulling with a force of 2N 0.5 to 40 it is preferably pieces / mm ^2. When the contact point is less than 0.5 pieces / mm ² , the mesh of the fused network is rough, which is not suitable for practical use as a network. On the other hand, when the number of contact points is more than 40 / mm ^{2, the} mesh of the fused net is too fine, so that it is not suitable for practical use as a net. Preferably 1 to 20 / mm ^2.

Moreover, it is preferable that the fusion | melting net | network reinforcement material which consists of a polyester multifilament of this invention has a porosity of 0.5 to 10%. When the porosity is less than 0.5%, it does not have performance as a net. When the porosity is larger than 10%, the woven or knitted fabric is coarse, and the bursting strength in the case of a fused network is lowered, which is not suitable for practical use as a network. Preferably it is 1 to 10%.

In the polyester fused network reinforcing material of the present invention, 30 to 70% of the contact points between the polyester multifilaments are preferably fused. When the fusion point of the contact points of the polyester multifilaments is less than 30%, the fusion point is small, so that it may not be suitable for practical use as a net. Further, when the fusion point exceeds 70%, the bursting strength as a net may be greatly reduced because there are too many fusion points.

  The number of fusion points and the porosity of the above-mentioned fused network differ from the number of contact points and the porosity of the polyester woven or knitted fabric for the fused network because the fabric shrinks in the heat treatment step for forming the fused network. It is.

The use of the polyester fused net reinforcing material of the present invention is not limited, but in terms of being made of polyester having excellent corrosion resistance and chemical resistance, it is bonded to a net for materials or various films. It is particularly suitable for applications in which it is important that the bursting strength as a net, the number of meshes and the porosity are appropriate for mass transfer, such as filtration membranes and flow path materials.

Specific examples polyesters used in the production of fusion destination network reinforcement for polyester woven or knitted fabric or polyester fused network reinforcement member of the present invention, for example, polyethylene terephthalate, polypropylene terephthalate, polytetramethylene terephthalate, polyethylene-2,6-naphthalene Examples thereof include dicarboxylate, polyethylene-1,2-bis (2-chlorophenoxy) ethane-4,4′-dicarboxylate, and the like. The present invention is suitable for polyethylene terephthalate or polyester copolymers mainly containing ethylene terephthalate units, which are most commonly used.

  These polyesters may be copolymerized with various ester-forming derivatives as long as the objects and effects of the present invention are not impaired.

  In addition, these polyesters include a matting agent such as titanium dioxide, various functional particles such as silicon oxide and kaolin, as well as an anti-coloring agent, a stabilizer, and an antioxidant as long as the objects and effects of the present invention are not impaired. You may contain additives, such as an agent.

  As the polyester having a low melting point, various copolymerized polyesters can be used, and polyesters obtained by copolymerizing 2,2-bishydroxyethylphenylpropane are particularly suitable.

Next will be described a method for manufacturing a fusion destination network reinforcement for polyester woven or knitted fabric or polyester fused network reinforcing material of the present invention. Although the example of the ultrafine fiber using a polyethylene terephthalate is described as a specific example, it is not limited to this.

  Polyester multifilaments are usually (1) a process in which the polyester is melted, weighed, filtered and discharged, (2) a process in which the discharged polyester filament is cooled by cooling air, and then (3) the polyester filament that has been taken out. (4) A process of drawing or drawing false twisting of the polyester fiber obtained in some cases.

In obtaining the polyester multifilament constituting the fusion destination network reinforcement for polyester woven or knitted fabric or polyester fused network reinforcing material of the present invention is carried out by a conventional method for out of the above process (1). As for (2), since the spinneret of the present invention allows the cooling air to pass through, the cooling air is blown from one direction, or an annular cooling device is used, and the cooling air is centered from the entire circumferential direction surrounding the yarn. Any of the methods of spraying toward The following processes (3) and (4) may be performed according to a conventional method.

Hereinafter, the present invention will be described more specifically with reference to examples. In addition, the physical-property value in an Example was measured by the method described below.
(1) Intrinsic viscosity of polymer IV
Measurement was performed at 25 ° C. using orthochlorophenol as a solvent.
(2) Number of contact points In a state where the woven or knitted fabric of 10 cm square was pulled with a force of 2 N in both the longitudinal and lateral directions, the woven or knitted fabric or the fusion net was observed with an optical microscope and observed in 1 mm square. The value obtained by counting the number of contact points between different multifilaments was defined as the number of contact points (pieces / mm ² ).
(3) Number of fusion points The 10 mm square of the woven or knitted fabric was pulled with a force of 2N in both the vertical and horizontal directions, and the fusion net was magnified and observed with an optical microscope. A value obtained by counting the number of fusion points between the multifilaments was defined as the number of fusion points (pieces / mm ² ). At this time, as a method for discriminating from the fusion point, the fusion point was determined by connecting the surface of the single yarn to the intersecting single yarn.
(4) Porosity In a state where the woven or knitted fabric of 10 cm square is pulled with a force of 2N in both the longitudinal and lateral directions, the woven and knitted fabric is enlarged and observed with an optical microscope, and the portion without multifilament observed in 1 mm square is observed. The ratio was defined as porosity (%).
(5) Melting point of multifilament 10 mg of each sample of multifilament is precisely weighed and sealed using an aluminum open pan and pan cover, and a nitrogen flow is measured using a differential scanning calorimeter (Perkin Elmer, DSC7 type). Then, the temperature was raised from 20 ° C. to 285 ° C. at a rate of 16 ° C./min, and the melting point peak temperature observed in the middle was taken as the melting point.
(6) Single filament fineness of multifilament 100 m of each sample of multifilament was sampled, and the measured weight was calculated by the following formula as Wg.
Single yarn fineness (dtex) = W × 100 / (number of multifilament single yarn)
(7) Boiling water shrinkage of multifilament Each sample of multifilament was wound up 10 times with a casserole machine, a sample length S1 (cm) before treatment was measured by applying a load of 0.09 cN / dtex, and 100 ° C. Treat in boiling water for 15 minutes. This was air-dried for 8 hours or more, and then a treated sample length S2 (cm) was measured by applying a load of 0.09 cN / dtex, and calculated from the following formula.
Boiling water shrinkage rate = {(S1-S2) / S1} × 100
(8) Entanglement degree of blended yarn Entanglement measuring device Using an ENTANGLEMEMENT TESTER R2071 manufactured by ROTHSCHILD, an average value obtained by measuring 30 times at a yarn feeding tension of 15 cN, a trip level of 15.5 cN, and a yarn speed of 1.25 m / min is entangled. Degree (month / m).
(9) Bursting strength of knitted fabric and fused net Measured in accordance with “6.16.2 B method” in JIS standard L1096-1999 “General textile test method” was performed three times, and the average value was defined as kPa unit. The things that burst are powerful.
(10) Thread breakage during weaving When weaving, the number of times the multifilament thread breaks while obtaining a 100 m woven fabric was determined to be 3 times or more, x, 2 times or more, and 1 or less.

Reference example 1
A homopolymer pellet of polyethylene terephthalate of IV0.66 obtained by a conventional method is dried according to a conventional method to make the moisture content 70 ppm or less. This dried pellet was melt-spun in accordance with a conventional method, and wound at 2500 m / min to obtain a polyester multifilament of 153 dtex and 36 filaments. This was heat-drawn at a drawing speed of 1000 m / min and a draw ratio of 1.83 times to obtain a polyester multifilament drawn yarn of 84 dtex and 36 filaments. Using this, a polyester woven fabric was produced with a plain weave structure with 16 warps per inch and 16 wefts. Table 1 shows the number of contact points, porosity, burst strength, and burst strength of the fusion network obtained by heat-treating the fabric at 210 ° C. with a heating roller.

Reference Examples 2-4, Comparative Examples 1-3
25 warps and wefts per inch ( Reference Example 2), 98 ( Reference Example 3) or 140 ( Reference Example 4), 12 (Comparative Example 1), 170 (Comparative Example 2), 200 A polyester fabric was obtained in the same manner as in Example 1 except that (Comparative Example 3) was used. Table 1 shows the number of contact points, the porosity, the burst strength, and the burst strength of the fusion network obtained by heat-treating the fabric at 210 degrees. It can be seen that for Reference Examples 2 to 4, the decrease in bursting strength when using the fused net is small compared to the bursting strength of the fabric, but for Comparative Examples 1 to 3, the decrease in bursting strength is significant.

Example 5
Homopolymer pellets of polyethylene terephthalate having an IV of 0.66 obtained by a conventional method and copolymerized polyethylene terephthalate obtained by copolymerizing 2,2-bishydroxyphenylpropane and isophthalic acid with respect to terephthalic acid, respectively, at 4 mol% and 7 mol%. Is dried according to a conventional method so that the moisture content is 70 ppm or less. Each dried pellet was melted separately, introduced into the same die, spun and blended by 18 filaments each, and in the same manner as in Example 1, from two types of polyester multifilament blended fibers of 42 dtex and 18 filaments, respectively. A drawn yarn was obtained. At this time, the polyester multifilament made of homopolymer is called multifilament A, and the polyester multifilament made of copolymerized polyethylene terephthalate is called multifilament B. Using this, a polyester woven fabric was produced with 100 warps per inch and 90 wefts. The number of contact points of the obtained woven fabric is 15 pieces / mm ² , the porosity is 10%, the melting points of single filaments A and B, single yarn fineness, boiling water shrinkage, entanglement of mixed yarn, boiling water Table 2 shows the shrinkage rate, the bursting strength of the fabric, and the bursting strength of the fused network obtained by heat-treating the fabric at 210 ° C.

Examples 6-9
The amount of copolymerization of 2,2-bishydroxyphenylpropane and isophthalic acid was adjusted, and the resulting multifilament B had a melting point of 248 ° C. (Example 6), 210 ° C. (Example 8) or 200 ° C. (Example 9). A polyester fabric was produced in the same manner as in Example 5, except that the melting point of the polyethylene terephthalate homopolymer was 265 ° C. (Example 7). The number of contact points of the obtained woven fabric is 15 pieces / mm ² , the porosity is 10%, the melting points of single filaments A and B, single yarn fineness, boiling water shrinkage, entanglement of mixed yarn, boiling water Table 2 shows the shrinkage rate, the bursting strength of the fabric, and the bursting strength of the fused network obtained by heat-treating the fabric at 210 ° C. In particular, it can be seen that the decrease in bursting strength when Example 7 is a fused network in the same manner as Example 5 is small.

Examples 10 and 11
A polyester fabric was produced in the same manner as in Example 5 except that multifilament B was 42 dtex, 36 filament (Example 10), or multifilament A was 42 dtex, 12 filament (Example 11). The number of contact points of the obtained woven fabric is 15 pieces / mm ² , the porosity is 10%, the melting points of single filaments A and B, single yarn fineness, boiling water shrinkage, entanglement of mixed yarn, boiling water Table 2 shows the shrinkage rate, the bursting strength of the fabric, and the bursting strength of the fusion network obtained by heat-treating the fabric at 210 degrees. It can be seen that the decrease in bursting strength when using a fused network is small.

Example 13 , Reference Examples 12, 14, 15
The amount of copolymerization of 2,2-bishydroxyphenylpropane and isophthalic acid was adjusted, and the resulting multifilament B had a boiling water shrinkage of 60% ( Reference Example 12), 50% (Example 13), 10% ( In the same manner as in Example 5, except that Reference Example 14) or 9% ( Reference Example 15) or the boiling water shrinkage of the polyethylene terephthalate homopolymer was 6% ( Reference Example 15), polyester A woven fabric was prepared. The number of contact points of the obtained woven fabric is 15 pieces / mm ² , the porosity is 10%, the melting points of single filaments A and B, single yarn fineness, boiling water shrinkage, entanglement of mixed yarn, boiling water Table 3 shows the shrinkage rate, the bursting strength of the fabric, and the bursting strength of the fusion network obtained by heat-treating the fabric at 210 degrees. It can be seen that the decrease in bursting strength when using a fused network is small.

Examples 16-18
Except for adjusting the entanglement imparting device during drawing and setting the entanglement degree of the resulting blended yarn to 3 / m (Example 16), 10 / m (Example 17) or 60% (Example 18). Produced a polyester fabric in the same manner as in Example 5. The number of contact points of the obtained woven fabric is 15 pieces / mm ² , the porosity is 10%, the melting points of single filaments A and B, single yarn fineness, boiling water shrinkage, entanglement of mixed yarn, boiling water Table 3 shows the shrinkage rate, yarn breakage during weaving, burst strength of the fabric, and burst strength of the fusion network obtained by heat-treating the fabric at 210 degrees. It can be seen that the decrease in bursting strength when using a fused network is small. Further, with respect to yarn breakage during weaving, the results of 17 and 18 were better than those of Example 16.

Example 19
Using a drawn yarn made of polyester multifilament mixed yarn obtained in the same manner as in Example 5, 20 warp yarns per inch and 16 weft yarns are made into a polyester fabric, and this is heat-treated at 200 ° C. A fused net was obtained. Table 4 shows the number of contact points, the porosity, the ratio of fusion points, and the burst strength.

Examples 20, 21 and Comparative Examples 4-6
110 (Example 20), 150 (Example 21), 15 (Comparative Example 4), 180 (Comparative Example 5), 250 (Comparative Example 6) warps and wefts per inch. A polyester fused network was obtained in the same manner as in Example 19 except for the above. Table 4 shows the number of contact points, the porosity, the ratio of fusion points, and the burst strength. As for Examples 20 and 21, the bursting strength when using the fused net is small, but it can be understood that the bursting strength is small for Comparative Examples 4 to 6.

Examples 22-24
A polyester fused network was obtained in the same manner as in Example 19 except that the temperature for heat treatment of the polyester fabric was 190 ° C. (Example 22), 180 ° C. (Example 23), or 225 ° C. (Example 24). Table 4 shows the number of contact points, the porosity, the ratio of fusion points, and the burst strength.

Claims (5)

A woven or knitted fabric composed of mixed yarns of two different polyester multifilament yarn groups A and B having a difference in boiling water shrinkage of 10 to 50%, and the boiling water shrinkage of the mixed yarn is 10 to 30 %, When the woven or knitted fabric of 10 cm square is observed in a state where it is pulled with a force of 2 N in both the longitudinal and transverse directions, the contact points between the multifilaments are 0.4 to 32 pieces / mm ² , and the porosity is 0.7 to A polyester woven or knitted fabric for a fused net reinforcement characterized by being 15%. The melting point difference between the yarn groups A and B is 10 to 80 ° C., the ratio of single yarn fineness is 3: 7 to 7: 3, and the entanglement degree of the mixed yarn is 5 to 50 / m. The polyester woven or knitted fabric for a fused net reinforcement according to claim 1, Polyester multifilament is a mixed yarn composed of two different yarn groups A and B, and the yarn groups A and B are polyester multifilaments obtained by spinning and mixing yarns discharged from the same base. The polyester woven or knitted fabric for a fusion net reinforcing material according to claim 1 or 2, wherein the polyester woven or knitted fabric is used for the fusion net reinforcing material . A fusion net reinforcing material made of polyester multifilament, and the contact point between the multifilaments when the 10 cm square of the fusion net is observed with a 2N force in both the vertical and horizontal directions is 0.5 to A polyester fused network reinforcing material characterized by 40 pieces / mm ² and a porosity of 0.5 to 10%. The polyester fused network reinforcing material according to claim 4, wherein 30 to 70% of the contact points between the polyester multifilaments is fused.