JP2004232132A - Heat-resistant fabric - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a heat-resistant fabric excellent in mechanical properties without impairing the properties inherent in fluororesin-based fiber and in finer dust trappability. <P>SOLUTION: The heat-resistant fabric, including the fluororesin-based fibers and heat-resistant high-strength fibers, is obtained by laminating these fibers with a scrim followed by undergoing needlepunching and high-pressure water jet treatment to fibrillate at least part of the fluororesin-based fibers and entangle them on the heat-resistant high-strength fibers. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

【００３４】
上記のように得られた耐熱性布帛の物性を表１に示す。表１の結果から明らかなように、比較例１〜６の布帛はいずれも捕集効率が低いことがわかる。また、フッ素樹脂系繊維の割合が１００％である比較例２の布帛は、布帛強度が低い上に、ウォータージェットパンチ処理することでさらに布帛強度が低下し、バグフィルターとしての使用は好ましくないことが分かる。
【００３５】
さらにまた、フッ素樹脂系繊維の混率が少ない比較例５の布帛では、ウォータージェットパンチ処理を実施しても捕集効率が向上せず、好ましくないことがわかる。
【００３６】
これらに対して実施例１〜３の布帛は、捕集効率がいずれも高く、高い布帛強度と通気量とを維持していることから、バグフィルター用に好適に用いることが可能である。
【００３７】
【発明の効果】
布帛表面のフッ素樹脂系繊維がフィブリル化して耐熱性の高強度繊維と絡合することで、フィルターとして用いたときの捕集効率が高い耐熱性布帛を得ることができる。また、フッ素樹脂系繊維がフィブリル化する反面、耐熱性の高強度繊維はフィブリル化しないので、布帛強度の低下が小さく、機械強度の高い耐熱性布帛を得ることができる。[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a heat-resistant cloth that can be suitably used for a filter, particularly a bag filter, and a method for producing the same.
[0002]
[Prior art]
Fluororesin-based fibers are widely used in industrial materials because of their excellent heat resistance, chemical resistance, electrical properties, and low coefficient of friction. Among them, due to its excellent chemical resistance and heat resistance, it is widely used for bag filters for waste incinerators. In bag filters for waste incinerators, felt composed of fluororesin-based fibers, double woven fabrics of glass fibers, etc. are mainstream, but other heat-resistant fibers such as aromatic aramid, polyphenylene sulfide, polyimide or Bag filters using felts such as polyparaphenylenebenzoxazole are also on the market.
[0003]
In the bag filter using the above-mentioned heat-resistant fiber, a bag filter having higher dust collection efficiency is required at present. In particular, from December 2002, based on the Law Concerning Special Measures against Dioxins, each incinerator must maintain a low concentration of dioxin emission, and there is a strong demand for a bag filter with higher collection efficiency. Furthermore, for example, in a gasification melting treatment furnace, a bag filter capable of collecting dust having a small particle size with higher efficiency is required.
[0004]
Therefore, a method has been proposed in which a microporous film of a fluororesin is attached to the felt surface of the heat-resistant fiber and dust is collected with high efficiency by the microporous film (for example, see Patent Document 1). Although this method can certainly increase the collection efficiency of dust having a small particle size of about 0.5 μm or less, the adhesion between the microporous film of the fluororesin and other materials is poor, so that it is easy to peel off, especially When the dust accumulated on the surface of the felt is blown off with compressed air, a physical impact is applied, and the impact may cause a problem of peeling of the fluororesin microporous film. In addition, a felt to which a microporous membrane made of a fluororesin is adhered has a low initial air permeability, and thus has good dust releasability, but has a disadvantage of increasing pressure loss during use.
[0005]
Also, a method has been proposed in which a web of fluorine fibers is laminated on a felt surface of heat-resistant fibers, entangled with a water jet punch, and integrated (for example, see Patent Document 2). In one method described in this patent document, that is, a method in which a web of fluorine fibers is directly entangled with a base fabric, in the case of a felt for a bag filter in which the total weight of the felt exceeds 500 g / m ² , the entanglement of the fibers is reduced in thickness. It is not appropriate because the felt strength cannot be increased because the direction does not sufficiently occur. Therefore, in another method described in this patent document, a plurality of manufacturing steps including a step of processing felt, a step of laminating a web of fluorine fibers on the surface of the felt, and a step of entanglement and integration of both are further performed. In addition, when used for a bag filter, the felt and fluorine fiber web can be separated by physical impact when hitting a backwash pulse. Is not preferred. Furthermore, fluorine fibers are excellent in chemical resistance and heat resistance, but have low mechanical strength because of their low strength, even when used alone for felt.
[0006]
Further, as a method found by the inventors of the present invention, there is a method of improving the collection efficiency by fibrillating a fluororesin fiber by subjecting a cloth composed of the fluororesin fiber to a water jet punch treatment (for example, And Patent Document 3). The essence of the present invention is that the fluororesin fibers are fibrillated, the pore size of the fabric is reduced, the sieving and blocking effects are improved, and the collection efficiency is increased. Only the effect of the increase can occur.
[0007]
[Patent Document 1] Japanese Patent Application Laid-Open No. 2000-140588
[Patent Document 2] Japanese Patent Application Laid-Open No. 2000-61224
[Patent Document 3] Japanese Patent Application Laid-Open No. 2001-146633
[Problems to be solved by the invention]
In view of the background of the related art, the present invention is to provide a heat-resistant cloth that has excellent mechanical properties without impairing the properties of the fluororesin fiber, and that is excellent in collecting finer dust. is there.
[0011]
[Means for Solving the Problems]
The present invention employs the following means in order to solve such a problem. That is, it is characterized by including a fluororesin-based fiber and a heat-resistant high-strength fiber, wherein at least a part of the fluororesin-based fiber is fibrillated and entangled with the heat-resistant high-strength fiber. In addition, the method for producing such a heat-resistant fabric comprises laminating a web containing a fluororesin-based fiber obtained by an emulsion spinning method and a heat-resistant high-strength fiber, and a scrim made of a heat-resistant fiber, and performing needle punching. It is characterized by including a step of forming a felt, and a step of fibrillating the fluororesin-based fibers of the felt surface layer by subjecting the felt to a water jet punch treatment.
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
As the fluororesin fiber, any fiber may be used as long as 90% or more of the repeating structural units of the polymer are composed of a monomer containing one or more fluorine atoms in a main chain or a side chain. Although it is possible, a fiber composed of a monomer having a large number of fluorine atoms is more preferable. For example, a tetrafluoroethylene-hexafluoropropylene copolymer (FEP), a tetrafluoroethylene-perfluoroalkoxy group copolymer (ETFE) Alternatively, a tetrafluoroethylene-olefin copolymer (ETFE) or the like can be used. More preferably, polytetrafluoroethylene (PTFE) is used from the viewpoint of heat resistance or chemical resistance.
[0013]
A method for producing a fluororesin fiber is an emulsion spinning method (wet emulsion spinning method or matrix method) in which a matrix polymer and a fluororesin polymer are mixed to form an emulsion, and the emulsion is discharged from a molding die into a coagulation bath to form a fiber. Spinning method). The fineness of the fluororesin fiber can be used as long as it is within the range of 1 to 20 dtex. However, in order to achieve both the collection efficiency as a filter and the strength of the felt, the fluororesin within the range of 3 to 8 dtex is used. It is more preferable to use a system fiber.
[0014]
In addition, as the heat-resistant high-strength fiber, a general usable temperature is a fiber having a temperature of 120 ° C. or higher, a fiber having a higher strength than a fluororesin-based fiber, and a fiber which is not damaged by a physical impact of a water jet punch Can be used without any problems. Here, the usable temperature refers to a temperature at which the strength retention is 80% or more when the temperature is maintained at that temperature in air for 80 days. For example, aromatic aramid fiber, polyphenylene sulfide fiber, polyimide fiber, polyparaphenylene benzoxazole fiber and the like can be selected and used, but heat resistance, chemical resistance, glass fiber and carbon fiber having high strength are most preferable. It can be preferably used.
[0015]
The heat-resistant fabric of the present invention is composed of the above-mentioned fluororesin fiber and heat-resistant high-strength fiber, and at least a part of the fluororesin fiber is fibrillated to form a heat-resistant high-strength fiber. It is characterized by being entangled. By the fibrillation of the fluororesin fiber, the sieving effect as a filter is improved, and the collection efficiency of finer dust is improved.In addition, the heat-resistant high-strength fiber and the fibril of the fluororesin fiber are improved. Entanglement, the collection efficiency is further improved. This is an improvement that cannot be explained by the ordinary sieving effect alone, and its scientific mechanism has not been elucidated (this is referred to as “trapping efficiency plus α” in the present invention).
[0016]
Further, since the fiber strength of the fluororesin fiber is slightly lower, such as about 1.9 cN / dtex, the fabric strength of the fabric composed of only the fibrillated fluororesin fiber is small. However, the present invention uses a mixture of a fluororesin-based fiber and a heat-resistant high-strength fiber, so that the fluororesin-based fiber is fibrillated and the fiber strength is slightly reduced. As a result, it has been found that the fabric strength is kept high as a result.
[0017]
The heat-resistant fabric of the present invention is preferably configured by laminating a web and a scrim. The web refers to a web formed by passing short fibers having a fiber length in the range of several tens to several hundreds of mm through a card machine. The web retains the strength of the nonwoven fabric only by the entanglement of the fibers. In particular, taking a web of 100% fluororesin-based fibers as an example, the strength of the web is so small that the web alone cannot be handled. In such a case, the strength of the fabric can be improved by laminating and integrating the scrim and the web. In the case of a general felt for a bag filter, a web that is arranged above and below a scrim and entangled and integrated with a needle punch is used. The scrim is an aggregate of a cloth, and a woven or knitted fabric can be appropriately selected and used. Since the scrim plays a role as an aggregate of felt, when used for a bag filter, a scrim having a tensile strength of 390 N / 5 cm or more and a breaking elongation of less than 50% is preferable. This is because it is not preferable to use a scrim less than 390 N / 5 cm as a bag filter because dust accumulates on the surface of the felt and elongation occurs due to its own weight. The scrim has an air permeability of 70 cc / cm ² / sec or more, and preferably has a form in which the scrim is entangled with short fibers by needle punching. If a scrim having an air permeability of less than 70 cc / cm ² / sec is used, the air flow when made into felt is too low, and the pressure loss of the felt is undesirably high.
[0018]
The weight of the whole felt is preferably in the range of 400 to 900 g / m ² for use as a bag filter, but in the range of 500 to 800 g / m ² so as to withstand the impact of compressed air when dusting off. Is particularly preferred.
[0019]
In the present invention, in order to effectively improve the collection efficiency, it is preferable to use a fluororesin-based fiber and a heat-resistant high-strength fiber for the web. Among the webs, those containing a fluororesin fiber and a high-strength fiber particularly on the filtration surface side are preferable. This is because, when water jet punching is performed from the surface (filtration surface) of the fabric, the fluororesin-based fibers on the surface of the fabric are fibrillated and entangled with the high-strength fiber, thereby exhibiting the effect of the present invention. Fluororesin fibers on the non-filtering surface) are hardly fibrillated. Therefore, it is most preferable that the web on the filtration surface side contains a fluororesin fiber and a heat-resistant high-strength fiber.
[0020]
In the entire web constituting the heat-resistant fabric of the present invention, the content of the fluororesin fibers is preferably in the range of 40 to 95 wt%. More preferably, the content is in the range of 50 to 80% by weight because the felt has both excellent chemical resistance and high rigidity. When the fluororesin-based fiber content is less than 50 wt%, the water-jet punching treatment makes the fluororesin-based fiber fibrillated and improves the sieving effect of the filter. It is not preferable because the plus α ″ hardly occurs. On the other hand, if the content of the fluororesin fiber is more than 95% by weight, the fluororesin fiber becomes fibrillated and the fabric strength is undesirably reduced.
[0021]
As described above, the heat-resistant high-strength fiber of the present invention is most preferably made of glass fiber or carbon fiber. Is particularly preferable because it is a fiber that is particularly large.
[0022]
As the glass fiber, any commercially available glass fiber can be used without any problem. However, in order to further exert the effects of the present invention, a "general E type having a fiber length of 38 mm to 150 mm (non-alkali glass, "Excellent incombustibility, heat resistance and strength", "Alkali resistant glass", "C type (chemical resistance, especially acid resistant glass)", "S type (alkali-free aluminosilicate glass, high elastic modulus) or" A "two-component" glass fiber can be used, and a glass fiber having a DE diameter (average fiber diameter of 5 to 7 μm) can be suitably used.
[0023]
As the carbon fiber, any polyacrylonitrile-based or pitch-based carbon fiber can be used as long as the fiber length is in the range of 30 mm to 150 mm. A fiber having a diameter of 5 to 7 μm is preferable because of high strength.
[0024]
The heat-resistant fabric of the present invention preferably has an air permeability measured based on the Frazier method defined in JIS L 1096 in the range of ^{2 to} 16 cc / cm ² / sec. By increasing the pressure of the water jet punch treatment for fibrillating the fluororesin-based fibers, the fibrillation of the fluororesin-based fibers proceeds, but the ventilation rate tends to decrease. If a cloth having an air permeability of less than ² cc / cm ² / sec is used as a bag filter, the load on the blower increases, which is not preferable in use. Conversely, by lowering the processing conditions of the water jet punch, the ventilation rate can be made higher than 16 cc / cm ² / sec, but the fibrillation of the fluororesin fibers constituting the fabric has not been sufficiently performed. Therefore, it is not preferable because the effects of the present invention are not exhibited.
[0025]
The heat-resistant fabric of the present invention preferably has a collection efficiency of 70% to 90% for particles having a particle size of 0.3 to 0.5 μm at a filtering air velocity of 1 m / min. In the case of using a non-fibrillated fluororesin-based fiber and the other configuration is the same as the present invention, the collection efficiency under the above-mentioned conditions is less than 70%. By fibrillating the fluororesin fibers on the surface and entanglement with the high-strength fibers, the collection efficiency is improved to 70% to 90%.
[0026]
The method for producing a heat-resistant fabric of the present invention comprises laminating a web containing a fluororesin-based fiber obtained by an emulsion spinning method and a heat-resistant high-strength fiber, and a scrim made of a heat-resistant fiber, and performing needle punching to perform felting. (Process 1), and a process (process 2) of subjecting this felt to water jet punch treatment to fibrillate the surface fluororesin-based fibers (process 2). Step 1 is an ordinary felting step, in which short fibers are passed through a card machine to form a web, scrims are appropriately selected and laminated, and thereafter, needle punching is performed, and entanglement and integration are performed. As the heat-resistant fabric of the present invention, a fabric obtained by performing a needle punching process and then calendering or heat setting to make the fabric denser and smoother can be used without any problem.
[0027]
Step 2 is a step of fibrillating the fluororesin fibers on the fabric surface, and the maximum processing water pressure of the water jet punch is preferably 120 to 250 kgf / cm ² . Here, the maximum processing water pressure means the highest water pressure among a plurality of nozzles installed in the water jet punch device. When the maximum treatment water pressure is less than 120 kgf / cm ² , the fluororesin fibers on the fabric surface are not sufficiently fibrillated, and the entanglement with the heat-resistant high-strength fibers is not sufficient. On the other hand, when the maximum treatment water pressure exceeds 250 kgf / cm ² , in addition to the fibrillation of the fluororesin-based fibers, the entanglement between the fibers proceeds, the density of the fabric increases, and the air flow rate is ² cc / cm ² / sec. Therefore, it is not preferable.
[0028]
The above-described heat-resistant cloth of the present invention can be suitably used as a bag filter by sewing it into a cylindrical shape. The sewn bag filter is preferably sewn so that a web containing fibrillated fluororesin fibers is arranged on the filtration surface side, that is, outside the cylinder.
[0029]
Further, the heat-resistant fabric of the present invention preferably has a web on both sides of the scrim, and the web on the filtration surface side contains fibrillated fluororesin fibers, and the non-filtration surface side is non-fibrillated fluororesin fibers. Preferably, the web contains Because the web on the filtration surface must contribute to the filtration of dust, the web on the non-filtration surface has a role to prevent abrasion with the metal retainer that holds the bag filter in a cylindrical shape. That's why. When used as a bag filter, the fluororesin-based fibers on the filtration surface are fibrillated and are extremely entangled with heat-resistant high-strength fibers, so the collection efficiency is high, the fabric strength is high, and further, It is possible to obtain a bag filter in which the detachment of fibers from the fabric surface is small. Fabrics with little detachment of fibers from the surface of the fabrics have good wiping performance when dust is repeatedly loaded, and are extremely suitable for use as a bag filter.
[0030]
When sewing in a cylindrical shape, it is preferable to sew using heat-resistant fibers. The heat-resistant fiber is not particularly limited, but from the viewpoint of heat resistance and chemical resistance, it is preferable to use a multifilament yarn of a fluororesin fiber, especially a PTFE fiber.
[0031]
【Example】
Hereinafter, the present invention will be described specifically with reference to Examples, but the present invention is not limited thereto.
[0032]
In addition, the measuring method of each physical property of a cloth is as follows.
[Air permeability] It was measured based on the Frazier method specified in JIS L 1096. Five measurement samples were randomly selected.
[Fabric strength] Measured based on the strip method specified in JIS L 1096. The sample size was 200 mm × 50 mm, the tensile speed was 100 mm / min, and the chuck interval was 100 mm. The measured value is the value of the primary strength in the vertical direction of the sample (in the direction perpendicular to the fiber orientation, and in the case of a sample containing a scrim, in the same direction as the vertical direction of the scrim).
[Collection efficiency] It was measured using an air dust counting method. Specifically, the number of dust contained in the air before and after filtration was measured using a particle counter, and the collection efficiency was calculated. The filtration wind speed is 1 m / min, and the size of the measured atmospheric dust is 0.3 to 0.5 μm.
Example 1
A fluororesin-based fiber (TOYOFLON (R), 7.4 dtex × 70 mm, manufactured by Toray Industries, Ltd.) obtained by the emulsion spinning method and a glass fiber (E-type glass fiber, 0.3 dtex cut into a length of 57 mm) are separated by a weight ratio of 80. : 20 and mixed into a sheet web through an opener and a card machine. As a scrim, using lastex scrim (made by Gore-Tex, using PTFE slit yarn yarn, using 400D, plain woven fabric having a woven density of 20 yarns / inch, basis weight 70 g / m ² ), and laminating in the order of web / scrim / web, Needle punching was performed at 350 needles / cm ² to obtain felt. After performing heat setting on the felt at 200 ° C. for 1 minute, an operation of performing water jet punching twice on one side of the felt at a processing speed of 1 m / min and a maximum processing water pressure of 150 kgf / cm ² was added. A heat resistant fabric was obtained. The obtained heat-resistant cloth was one in which the fluororesin fibers were fibrillated and finely entangled with the glass fibers.
Example 2
The heat-resistant cloth obtained in Example 1 was further subjected to a single water jet punching process at a processing speed of 1 m / min and a maximum processing water pressure of 200 kgf / cm ² . In the obtained heat-resistant cloth, the fibrillation of the fluororesin fiber proceeded more than the heat-resistant cloth of Example 1, and the fiber was more finely entangled with the glass fiber.
Example 3
Fluororesin-based fiber (TOYOFLON (R), 7.4 dtex x 70 mm, manufactured by Toray) and carbon fiber (Torayca (R) fiber, manufactured by Toray, T700S-12000FY (total fineness: 800 dtex)) obtained by the emulsion spinning method have a length of 51 mm. Cut) is mixed in a ratio of 85:15 and made into a web through an opener and a card machine. Using a multifilament woven fabric of a fluororesin fiber (TOYOFLON (R) manufactured by Toray, a woven fabric using T200-440dtex-60FY, product number # 4378, basis weight 250 g / m ² ) as a scrim, laminating in the order of web / scrim / web, Needle punching was performed at a needle count of 300 needles / cm ² to obtain a felt. After heat-setting the felt at 210 ° C. × 1 minute, an operation of performing water jet punching twice on one side of the felt at a processing speed of 1 m / min and a maximum processing water pressure of 120 kgf / cm ² was added. A heat resistant fabric was obtained. The obtained heat-resistant cloth was one in which the fluororesin fibers were fibrillated and finely entangled with the carbon fibers.
Comparative Example 1
In Example 1, the heat-set felt was used as the heat-resistant cloth of Comparative Example 1. In the heat-resistant cloth of Comparative Example 1, the fluororesin-based fibers were composed of fibers having a diameter of about 20 to 27 μm, no fibrillation was observed, and no finely entangled portions with the glass fibers were observed. Was.
Comparative Example 2
Fluororesin-based fibers (PROFILEN (R), type 803/60, 2.7 dtex × 60 mm) obtained by the split peeling method were passed through an opener and a card machine to form a web. As a scrim, using lastex scrim (made by Gore-Tex, using PTFE slit yarn yarn, using 400D, plain woven fabric having a woven density of 20 yarns / inch, basis weight 70 g / m ² ), and laminating in the order of web / scrim / web, Needle punching was performed at 350 needles / cm ² , followed by needle punching to obtain a felt. A heat-resistant fabric of Comparative Example 2 was heat-set on the felt at 200 ° C. for 1 minute. In the heat-resistant cloth of Comparative Example 2, the fluororesin-based fiber had an irregular cross-section, and the thin portion was composed of a fiber having a fiber thickness of about 10 μm and the thick portion having a fiber thickness of about 40 μm. No portion where the system fiber was divided into a plurality of fibers in the length direction was observed, and no fibrillation was observed.
Comparative Example 3
One side of the heat-resistant cloth of Comparative Example 2 was subjected to water jet punching twice at a processing speed of 1 m / min and a maximum processing water pressure of 100 kgf / cm ² to obtain a heat-resistant cloth of Comparative Example 3. The heat-resistant fabric of Comparative Example 3 was composed of only fibers having a fiber thickness of about 10 to 40 μm, and no fibrillated portion of the fluororesin-based fiber was observed.
Comparative Example 4
In Example 3, the heat-set felt was used as the heat-resistant cloth of Comparative Example 4. In the heat-resistant cloth of Comparative Example 4, the fluororesin-based fibers were composed of fibers having a diameter of about 20 to 27 μm, no fibrillation was observed, and no finely entangled portions with the glass fibers were observed. Was.
Comparative Example 5
Fluororesin-based fiber (TOYOFLON (R), 7.4 dtex x 70 mm, manufactured by Toray) and carbon fiber (Torayca (R) fiber, manufactured by Toray, T700S-12000FY (total fineness: 800 dtex)) obtained by the emulsion spinning method have a length of 51 mm. Cut) is mixed in a ratio of 30:70 and made into a web through an opener and a card machine. Using a multifilament woven fabric of a fluororesin fiber (TOYOFLON (R) manufactured by Toray, a woven fabric using T200-440dtex-60FY, product number # 4378, basis weight 250 g / m ² ) as a scrim, laminating in the order of web / scrim / web, Needle punching was performed at a needle count of 300 needles / cm ² to obtain a felt. The felt was heat-set at 210 ° C. for 1 minute to obtain a heat-resistant cloth of Comparative Example 5. In the heat-resistant cloth of Comparative Example 5, the fluororesin-based fibers were composed of fibers having a diameter of about 20 to 27 μm, no fibrillation was observed, and no finely entangled portions with the carbon fibers were observed. Was.
Comparative Example 6
The heat-resistant cloth of Comparative Example 6 was obtained by performing water jet punching twice on one surface of the heat-resistant cloth of Comparative Example 5 at a processing speed of 1 m / min and a maximum processing water pressure of 50 kgf / cm ² . In the heat-resistant cloth of Comparative Example 6, the fluororesin-based fibers were composed of fibers having a diameter of about 20 to 27 μm, no fibrillation was observed, and no finely entangled portions with the carbon fibers were observed. Was.
[0033]
[Table 1]

[0034]
Table 1 shows the physical properties of the heat-resistant cloth obtained as described above. As is clear from the results in Table 1, it can be seen that all of the fabrics of Comparative Examples 1 to 6 have low collection efficiency. In addition, the fabric of Comparative Example 2 in which the proportion of the fluororesin fiber is 100% has a low fabric strength, and the water jet punch treatment further reduces the fabric strength, which is not preferable for use as a bag filter. I understand.
[0035]
Furthermore, in the case of the fabric of Comparative Example 5 in which the mixing ratio of the fluororesin fibers is small, the collection efficiency is not improved even when the water jet punching treatment is performed, which is not preferable.
[0036]
On the other hand, the fabrics of Examples 1 to 3 have a high collection efficiency and maintain high fabric strength and air permeability, and thus can be suitably used for bag filters.
[0037]
【The invention's effect】
Since the fluororesin-based fibers on the fabric surface are fibrillated and entangled with the heat-resistant high-strength fibers, a heat-resistant fabric having a high collection efficiency when used as a filter can be obtained. Further, while the fluororesin-based fibers are fibrillated, the heat-resistant high-strength fibers do not fibrillate, so that a decrease in the fabric strength is small and a heat-resistant fabric having high mechanical strength can be obtained.

Claims (11)

A heat-resistant fabric comprising a fluororesin-based fiber and a heat-resistant high-strength fiber, wherein at least a part of the fluororesin-based fiber is fibrillated and entangled with the heat-resistant high-strength fiber. The heat-resistant fabric according to claim 1, wherein the web and the scrim are laminated. The heat-resistant fabric according to claim 2, wherein the web comprises a fluororesin-based fiber and a heat-resistant high-strength fiber. The heat-resistant fabric according to claim 3, wherein the web contains a fluororesin fiber in a range of 40 to 95 wt%. The heat-resistant fabric according to claim 3, wherein the heat-resistant high-strength fiber is a glass fiber. The heat-resistant fabric according to claim 3, wherein the heat-resistant high-strength fiber is a carbon fiber. The air flow rate measured based on the Frazier method defined in JIS L 1096 is in the range of ^{2 to} 16 cc / cm ² / sec, according to any one of claims 1 to 6, Heat resistant fabric. The heat-resistant fabric according to any one of claims 1 to 7, wherein the collection efficiency of particles having a particle size of 0.3 to 0.5 µm at a filtration wind speed of 1 m / min is 70% to 90%. Laminating a web containing a fluororesin-based fiber obtained by an emulsion spinning method and a heat-resistant high-strength fiber, and a scrim made of a heat-resistant fiber, and performing needle punching to form a felt. A step of punching to fibrillate the fluororesin fibers of the felt surface layer. Wherein the water-jet punching maximum processing pressure is 120~250kgf / cm ^2, the manufacturing method of the heat resistant fabric of claim 9. A bag filter obtained by sewing the heat-resistant cloth according to claim 1 in a cylindrical shape.