BAG FILTER FABRIC AND PRODUCTION METHOD THEREFOR

Abstract

The invention addresses the problem of providing a filter fabric for a bag filter, which has excellent collection performance and low pressure drop and is resistant to a decrease in dust collection performance due to abrasion or cracking, and also a method for producing the same. Means for resolution is a filter fabric for a bag filter in which a nonwoven fabric A including short fibers a having a single-fiber fineness of 0.3 to 0.9 dtex, a base fabric, and a nonwoven fabric B including short fibers b having a single-fiber fineness of 0.3 to 4.0 dtex are laminated in this order.

Description

TECHNICAL FIELD

The present invention relates to a filter fabric for a bag filter, which has excellent collection performance and low pressure drop and is resistant to a decrease in dust collection performance due to abrasion or cracking, and also to a method for producing the same.

BACKGROUND ART

Bag filters are installed in the dust chamber of a dust collector and used for collecting dust. Dust dislodgement and dust collection are repeated to enable long-term dust collection.

Conventionally, as a bag filter, a nonwoven fabric interlaced by needle punching or the like (felt) or a woven fabric is used. In recent years, in terms of device size reduction, a method in which a highly breathable nonwoven fabric is used, and also dust is dislodged by pulse jet, has been widespread. Further, considering the problems of air pollution caused by PM 2.5 and the like, for the collection of finer dust, a filter using a high-fineness material and a type of filter formed of a PTFE membrane film attached to a substrate have been used (see, e.g., PTLs 1 and 2).

However, the filter using a high-fineness material has been problematic in that the breathability decreases, resulting in an increase in the energy consumption of the dust collector. In addition, in the type of filter formed of a PTFE membrane film attached to a substrate, because such a filter is a thin layer, there have been problems in that the dust collection performance decreases due to abrasion or cracking, or the life decreases.

CITATION LIST

Patent Literature

PTL 1: JP-A-9-313832

PTL 2: JP-A-10-230119

SUMMARY OF INVENTION

Technical Problem

The invention has been accomplished against the above background. An object thereof is to provide a filter fabric for a bag filter, which has excellent collection performance and low pressure drop and is resistant to a decrease in dust collection performance due to abrasion or cracking, and also a method for producing the same.

Solution to Problem

The present inventors have conducted extensive research to solve the above problems. As a result, they have found that when a nonwoven fabric having a specific single-fiber fineness is laminated on each side of a base fabric, it is possible to obtain a filter fabric for a bag filter, which has excellent collection performance and low pressure drop and is resistant to a decrease in dust collection performance due to abrasion or cracking. As a result of further extensive research, they have accomplished the invention.

Thus, the invention provides a filter fabric for a bag filter, including: a nonwoven fabric A including short fibers a having a single-fiber fineness of 0.3 to 0.9 dtex; a base fabric; and a nonwoven fabric B including short fibers b having a single-fiber fineness of 0.3 to 4.0 dtex, the nonwoven fabric A, the base fabric, and the nonwoven fabric B being laminated in this order.

At this time, it is preferable that at least one of the short fiber a and the short fiber b has a tensile strength of 2.2 cN/dtex or more. In addition, it is preferable that at least one of the short fiber a and the short fiber b has an elongation of 25% or more. In addition, it is preferable that at least one of the short fiber a and the short fiber b has 6 to 30 crimps/2.54 cm. In addition, it is preferable that at least one of the short fiber a and the short fiber b has a crimp degree within a range of 8 to 40%. In addition, it is preferable that at least one of the short fiber a and the short fiber b has a fiber length within a range of 20 to 80 mm. In addition, it is preferable that at least one of the short fiber a and the short fiber b includes a meta-type aramid fiber. In addition, it is preferable that at least one of the nonwoven fabric A and the nonwoven fabric B has a weight per unit within a range of 100 to 300 g/m². In addition, it is preferable that the filter fabric has a porosity within a range of 75 to 90%. In addition, it is preferable that the nonwoven fabric A is placed on a filtrate-collecting surface side. In addition, it is preferable that all fibers forming the filter fabric for a bag filter are meta-type aramid fibers.

In the filter fabric for a bag filter of the invention, it is preferable that after 5,000 abrasion cycles in accordance with a Martindale abrasion test (counterpart: cotton cloth) on a surface of the nonwoven fabric A or a surface of the nonwoven fabric B, the average pore size increase rate is 30% or less, and the pressure drop increase rate is 30% or less. In addition, it is preferable that on a surface of the nonwoven fabric A or a surface of the nonwoven fabric B, the average pore size is within a range of 7 to 17 μm. In addition, it is preferable that the filter fabric has a tensile strength of 600 N/5 cm or more both in the MD direction and the CD direction.

According to the invention, there is also provided a method for producing a filter fabric for a bag filter, the method including: laminating a nonwoven fabric A including short fibers a having a single-fiber fineness of 0.3 to 0.9 dtex, a base fabric, and a nonwoven fabric B including short fibers b having a single-fiber fineness of 0.3 to 4.0 dtex in this order; and then subjecting the laminate to needle punching and then calendering.

Advantageous Effects of Invention

According to the invention, a filter fabric for a bag filter, which has excellent collection performance and low pressure drop and is resistant to a decrease in dust collection performance due to abrasion or cracking, and a method for producing the same are obtained.

DESCRIPTION OF EMBODIMENTS

Hereinafter, embodiments of the invention will be described in detail.

First, it is important that the short fibers a have a single-fiber fineness within a range of 0.3 to 0.9 dtex (more preferably 0.3 to 0.8 dtex, particularly preferably 0.3 to 0.6 dtex). When the single-fiber fineness is less than 0.3 dtex, the strength of the fibers is likely to be low, and, in the production of a filter fabric, the fibers are likely to break upon the interlacing treatment or the like, whereby the nonwoven fabric strength may decrease; therefore, this is undesirable. Conversely, when the single-fiber fineness is more than 0.9 dtex, the dust collection properties decrease, and dust is likely to penetrate into the filter fabric; therefore, this is undesirable.

In addition, the short fibers a preferably have a tensile strength of 2.2 cN/dtex or more (more preferably 2.2 to 6.0 cN/dtex). When the tensile strength is less than 2.2 cN/dtex, the strength of the fibers is likely to be low, and, in the production of a filter fabric, the fibers are likely to break upon the interlacing treatment or the like, whereby the nonwoven fabric strength may decrease.

The short fibers preferably have an elongation of 25% or more (more preferably 25 to 50%). When the elongation is less than 25%, in the production of a filter fabric, the fibers are likely to break upon the interlacing treatment or the like, whereby the nonwoven fabric strength may decrease.

The short fibers a are preferably crimped so that they can have an enhanced ability to collect dust. In this regard, it is preferable that the number of crimps is within a range of 6 to 30/2.54 cm. In addition, it is preferable that the crimp degree is within a range of 8 to 40%.

The short fibers a preferably have a fiber length within a range of 20 to 80 mm.

The kind of the short fibers a is not particularly limited, and examples thereof include polyester fibers, polyamide fibers, polyolefin fibers, PPS (polyphenylene sulfide) fibers, aramid fibers (wholly aromatic polyamide fibers), and glass fibers. Among them, in terms of heat resistance, meta-type aramid fibers (meta-type wholly aromatic polyamide fibers) are preferable. Meta-type aramid fibers are made of a polymer in which m-phenyleneisophthalamide (meta-type wholly aromatic polyamide) makes up 85 mol % or more of repeating units. The meta-type wholly aromatic polyamide may also be a copolymer containing a third component in an amount within a range of less than 15 mol %.

Such a meta-type wholly aromatic polyamide can be produced by a conventionally known interfacial polymerization method. With respect to the polymerization degree of the polymer, it is preferable to use one having an intrinsic viscosity (I.V.) within a range of 1.3 to 1.9 dl/g as measured with an N-methyl-2-pyrrolidone solution having a concentration of 0.5 g/100 ml. Examples of commercially available products of meta-type aramid fibers include Conex (trade name), Conex Neo (trade name), and Nomex (trade name).

Meanwhile, the short fibers b preferably have a single-fiber fineness within a range of 0.3 to 4.0 dtex (more preferably 0.4 to 3.2 dtex, particularly preferably 0.8 to 2.5 dtex). When the single-fiber fineness is less than 0.3 dtex, the strength of the fibers is likely to be low, and, in the production of a filter fabric, the fibers are likely to break upon the interlacing treatment or the like, whereby the nonwoven fabric strength may decrease; therefore, this is undesirable. Conversely, when the single-fiber fineness is more than 4.0 dtex, the dust collection performance decreases; therefore, this is undesirable. Incidentally, it is preferable that the single-fiber fineness of the short fibers b is higher than the single-fiber fineness of the short fibers a.

In addition, the short fibers b preferably have a tensile strength of 2.2 cN/dtex or more (more preferably 2.2 to 6.0 cN/dtex). When the tensile strength is less than 2.2 cN/dtex, the strength of the fibers is likely to be low, and, in the production of a filter fabric, the fibers are likely to break upon the interlacing treatment or the like, whereby the nonwoven fabric strength may decrease.

The short fibers b preferably have an elongation of 25% or more (more preferably 25 to 50%). When the elongation is less than 25%, in the production of a filter fabric, the fibers are likely to break upon the interlacing treatment or the like, whereby the nonwoven fabric strength may decrease.

The short fibers b are preferably crimped so that they can have an enhanced ability to collect duct. In this regard, it is preferable that the number of crimps is within a range of 6 to 30/2.54 cm. In addition, it is preferable that the crimp degree is within a range of 8 to 40%.

The short fibers b preferably have a fiber length within a range of 20 to 80 mm.

The kind of the short fibers b is not particularly limited, and examples thereof include polyester fibers, polyamide fibers, polyolefin fibers, PPS (polyphenylene sulfide) fibers, aramid fibers (wholly aromatic polyamide fibers), and glass fibers. Among them, in terms of heat resistance, meta-type aramid fibers (meta-type wholly aromatic polyamide fibers) are preferable. Meta-type aramid fibers are made of a polymer in which m-phenyleneisophthalamide makes up 85 mol % or more of repeating units.

The meta-type wholly aromatic polyamide may also be a copolymer containing a third component in an amount within a range of less than 15 mol %. Such a meta-type wholly aromatic polyamide can be produced by a conventionally known interfacial polymerization method. With respect to the polymerization degree of the polymer, it is preferable to use one having an intrinsic viscosity (I.V.) within a range of 1.3 to 1.9 dl/g as measured with an N-methyl-2-pyrrolidone solution having a concentration of 0.5 g/100 ml. Examples of commercially available products of meta-type aramid fibers include Conex (trade name), Conex Neo (trade name), and Nomex (trade name).

In the invention, a nonwoven fabric A including the short fibers a, a base fabric, and a nonwoven fabric B including the short fibers b are laminated in this order.

Here, it is preferable that at least one of the nonwoven fabric A and the nonwoven fabric B (preferably both the nonwoven fabric A and the nonwoven fabric B) has a weight per unit within a range of 100 to 300 g/m² (more preferably 120 to 250 g/m²). When the weight per unit is less than 100 g/m², the dust collection performance may decrease. Conversely, when the weight per unit is more than 300 g/m², the pressure drop may increase.

In the nonwoven fabric A and the nonwoven fabric B, the nonwoven fabric kind is not particularly limited and may be a needle-punched nonwoven fabric, a spunlace nonwoven fabric, or a wet-laid nonwoven fabric, for example. A needle-punched nonwoven fabric is preferable.

The base fabric, which is also called a scrim, serves as a strength-retaining layer in a filter fabric for a bag filter, and is provided in order to prevent pressurization to the dust-collecting layer by exhaust gas or the like, slacking due to the self-weight of the dust-collecting layer itself, and the like.

The fibers forming the base fabric are not particularly limited, but meta-type aramid fibers are preferable in terms of heat resistance. In this regard, it is preferable that the single-fiber fineness is within a range of 1.0 to 3.0 dtex. In addition, a spun yarn made of short fibers having a fiber length 20 to 80 mm is preferable. In addition, with respect to the yarn count, a 5- to 20-count two-ply yarn or single yarn is preferable.

In the base fabric, the fabric structure is not limited and may be a woven fabric, a nonwoven fabric, or a knitted fabric. In terms of obtaining excellent strength, a woven fabric is preferable. At this time, the weave structure is preferably a plain-weave structure. In addition, the weave density is preferably such that that the warp density and the weft density are within a range of 5 to 20 yarns/2.54 cm.

In addition, it is preferable that the weight per unit of the base fabric is within a range of 30 to 150 g/m². When the weight per unit is less than 30 g/m², the strength may decrease. Conversely, when the weight per unit is more than 150 g/m², the pressure drop may increase.

A method for producing a filter fabric for a bag filter of the invention preferably includes laminating a nonwoven fabric A including short fibers a having a single-fiber fineness of 0.3 to 0.9 dtex, abase fabric, and a nonwoven fabric B including short fibers b having a single-fiber fineness of 0.3 to 4.0 dtex in this order and then subjecting the laminate to needle punching. In addition, it is preferable to subsequently perform calendering.

In this regard, it is preferable that calendering is performed using specifications with upper and lower metal rollers. It is preferable that both the upper and lower rollers have a temperature of 100 to 200° C., and the linear pressure is within a range of 50 to 200 kgf/cm. In addition, when the dust-collecting surface side of the filter fabric has been singed by a burner, or the fiber surface is coated with a treatment agent containing an oxide of a metal such as silicon or aluminum and a fluororesin, fiber degradation is suppressed, whereby the durability of the filter fabric improves, and also the dust collection efficiency improves, which is preferable.

In the filter fabric for a bag filter thus obtained, it is preferable that the porosity is within a range of 75 to 90%. When the porosity is less than 75%, the pressure drop is too high, and energy saving may not be achieved. Conversely, when the porosity is more than 90%, the collection performance may decrease. Incidentally, the porosity can be adjusted by the calendering treatment.

Here, it is preferable that the pressure drop is 200 Pa or less (more preferably 5 to 200 Pa, particularly preferably 5 to 100 Pa).

In addition, it is preferable that after 5,000 abrasion cycles in accordance with a Martindale abrasion test (counterpart: cotton cloth) on the nonwoven fabric A surface or the nonwoven fabric B surface, the average pore size increase rate is 30% or less, and the pressure drop increase rate is 30% or less.

Here, the average pore size is measured in accordance with ASTM-F-316. In addition, the rate of average pore size increase and the rate of pressure drop increase are calculated by the following equations.

Average pore size increase rate=(average pore size after abrasion−average pore size before abrasion)/average pore size before abrasion×100

Pressure drop increase rate=(pressure drop after abrasion−pressure drop before abrasion)/pressure drop before abrasion×100

In addition, it is preferable that the breathability is within a range of 5 to 10 cm³/cm²·sec. In addition, it is preferable that on the nonwoven fabric A surface or the nonwoven fabric B surface, the average pore size is within a range of 7 to 17 μm. In addition, it is preferable that the minimum pore size is within a range of 2 to 6 μm. In addition, it is preferable that the maximum pole size is within a range of 22 to 44 μm.

In addition, it is preferable that the breathability is within a range of 5 to 10 cm³/cm²·sec. In addition, it is preferable that the average pore size is within a range of 7 to 13 μm.

In addition, it is preferable that the tensile strength is 600 N/5 cm or more (more preferably 700 to 3,000 N/5 cm) both in the MD direction (longitudinal direction) and the CD direction (transverse direction).

The filter fabric for a bag filter of the invention is configured as above, and thus has excellent collection performance and low pressure drop and is resistant to a decrease in dust collection performance due to abrasion or cracking. In addition, when all fibers forming the filter fabric for a bag filter are meta-type aramid fibers, excellent heat resistance is also offered. When the filter fabric for a bag filter of the invention is used, it is preferable that the nonwoven fabric A is placed on the filtrate-collecting surface side.

EXAMPLES

Next, examples of the invention and comparative examples will be described in detail, but the invention is not limited thereto. Incidentally, measurement items were measured by the following methods.

(1) Fiber Length, Single-Fiber Fineness, Tensile Strength and Elongation, Number of Crimps, Crimp Degree

Measurement was performed in accordance with JIS L 1015. The physical properties of raw materials are shown in Table 1.

TABLE 1
Single-Fiber	Fiber	Tensile	Tensile	Number of	Crimp
Fineness	Length	Strength	Elongation	Crimps	Degree
dtex	mm	cN/dtex	%	crimps/2.54 cm	%
0.1-0.2	24	2.1	30	12	7
0.5	38	2.5	37	17	11
0.8	38	3.8	40	12	15
2.2	51	4.3	44	13	19
3.0	51	4.7	44	13	19
5.0	76	5.1	44	8	15

(2) Weight Per Unit and Thickness of Nonwoven Fabric

Evaluation was performed in accordance with JIS L 1096. Thickness was evaluated at a load of 5 gf/m² (4.9 cN/m²).

(3) Atmospheric Dust Collection Efficiency

At a wind speed adjusted to 5.1 cm/sec, atmospheric dust in front of and behind a sample was counted with a particle counter, and the collection efficiency was calculated from their ratio.

Atmospheric dust collection efficiency (%)=(1−(the number of atmospheric dust particles after passing through the sample/the number of atmospheric dust particles before passing through the sample))×100

(4) Pressure Drop

At the time of the atmospheric dust collection efficiency measurement, the pressure was measured before and after the dust passed through the test piece, and the pressure difference was determined as the pressure drop.

(5) Pore Size

The maximum pole size, the average pore size, and the minimum pore size were determined in accordance with ASTM-F-316.

(6) Dust Entry Depth

The JIS Class 8 powder was introduced into a filter at a concentration of 1 g/m³ and an inflow speed of 10 cm/sec until a pressure drop of 2 kPa was reached. Under a microscope, a cross-section and the surface opposite from the dust passage side were observed. When the entry depth was less than ⅓ the entire thickness, a rating of “pass” was given, while in the case of ⅓ or more, a rating of “fail” was given.

(7) Tensile Strength

In accordance with JIS L1096, the maximum tensile strength was measured at a sample width of 50 mm, a grip distance of 100 mm, and a tensile speed of 200 mm/min.

(8) Porosity

Measurement was performed as follows: 100−100×(density÷specific gravity 1.38).

The density was calculated as follows: weight per unit÷thickness÷1,000.

(9) Martindale Abrasion Test

5,000 abrasion cycles were performed in accordance with the Martindale abrasion test specified in JIS L-1096 (counterpart: cotton cloth).

(10) Web Width Increase Rate

For the card passing properties described below, at the time of passage for about 30 seconds, a web width increase rate of 2.2 times or more was rated “fail” while a web width increase rate of less than 2.2 times was rated “pass”.

(11) Nep

For the card passing properties described below, three 10 cm×10 cm square samples of the web were obtained at the time of passage for about 30 seconds, and the average number of fiber neps of 0.5 mm or more was counted. A nep count of 10 or more was rated “fail” while a nep count of less than 10 was rated “pass”.

(12) Roller Wrap-Around

For the card passing properties described below, the operation was stopped after passage for about 60 seconds to completely stop the rotation, and, in such a state, wrapping around the inner cylinder roller was visually observed; when wrap-around with a width of 1 cm or more was observed, a rating of “fail” was given, while in the case of less than 1 cm, a rating of “pass” was given.

(13) Breathability

Breathability was measured in accordance with JIS L1096 8.26, A Method (Frazier Method).

(Scrim)

The scrim is a plain-woven fabric produced from meta-type aramid fibers (Conex (trade name) manufactured by Teijin Limited, single-fiber fineness: 2.2 dtex, fiber length: 51 mm) using a 10-count two-ply yarn as the warp at a weave density of 20 yarns/2.54 cm and a 20-count single yarn as the weft at a weave density of 14 yarns/2.54 cm.

(Calendering)

Using specifications with upper and lower metal rollers, calendering was performed at a temperature of about 200° C. (both upper and lower rollers) and a linear pressure of about 100 kgf/cm (980 N/cm) with the distance between the upper and lower rollers being suitably adjusted to achieve the intended thickness.

(Card Passing Properties)

The passing properties in the carding step were evaluated in terms of web width elongation rate, the number of neps, and roller wrap-around as described above. The carding was performed under the conditions shown in Table 2 below, in which the cylinder surface speed of 940 m/min was taken as a ratio of 1. With respect to the loaded material, the material was uniformly arranged with a width of 0.1 m and a length of 0.6 m and loaded at a speed of 0.6 m/min.

TABLE 2
Cylinder Speed	Speed Ratio (Relative to Cylinder)
m/min	Taker-in	Cylinder	Worker	Stripper	Cylinder	Doffer
941	0.48	1.0	0.011	0.34	1.0	0.021

Example 1

A 0.5-dtex raw material made of meta-type aramid fibers having a cut length of 38 mm and a 2.2-dtex raw material made of meta-type aramid fibers having a cut length of 51 mm were each independently carded. Then, the carded nonwoven fabric having a weight per unit of about 200 g/m² on the filtrate-collecting surface side and the carded nonwoven fabric having a weight per unit of about 200 g/m² on the opposite side were laminated with a scrim having a weight per unit of 70 g/m² as a base fabric interposed therebetween. The laminate was then needle-punched and calendered.

With respect to the obtained sample, the weight per unit, thickness, density, tensile strength, atmospheric dust collection rate, pressure drop, minimum, average, and maximum pore sizes, and dust entry depth were evaluated. The evaluation results are shown in Table 3 and Table 4.

Example 2

A 0.8-dtex raw material made of meta-type aramid fibers having a cut length of 38 mm and a 2.2-dtex raw material made of meta-type aramid fibers having a cut length of 51 mm were each independently carded. Then, the carded nonwoven fabric having a weight per unit of about 200 g/m² on the filtrate-collecting surface side and the carded nonwoven fabric having a weight per unit of about 200 g/m² on the opposite side were laminated with a scrim having a weight per unit of 70 g/m² as a base fabric interposed therebetween. The laminate was then needle-punched and calendered.

With respect to the obtained sample, the weight per unit, thickness, density, tensile strength, atmospheric dust collection rate, pressure drop, minimum, average, and maximum pore sizes, and dust entry depth were evaluated. The evaluation results are shown in Table 3 and Table 4.

Example 3

0.5-dtex raw materials made of meta-type aramid fibers having a cut length of 38 mm were carded. Then, the carded nonwoven fabric having a weight per unit of about 200 g/m² on the filtrate-collecting surface side and the carded nonwoven fabric having a weight per unit of about 200 g/m² on the opposite side were laminated with a scrim having a weight per unit of 70 g/m² as abase fabric interposed therebetween. The laminate was then needle-punched and calendered.

With respect to the obtained sample, the weight per unit, thickness, density, tensile strength, atmospheric dust collection rate, pressure drop, minimum, average, and maximum pore sizes, and dust entry depth were evaluated. The evaluation results are shown in Table 3 and Table 4.

Example 4

A 0.5-dtex raw material made of meta-type aramid fibers having a cut length of 38 mm and a 3.0-dtex raw material made of meta-type aramid fibers having a cut length of 51 mm were each independently carded. Then, the carded nonwoven fabric having a weight per unit of about 200 g/m² on the filtrate-collecting surface side and the carded nonwoven fabric having a weight per unit of about 200 g/m² on the opposite side were laminated with a scrim having a weight per unit of 70 g/m² as a base fabric interposed therebetween. The laminate was then needle-punched and calendered.

With respect to the obtained sample, the weight per unit, thickness, density, tensile strength, atmospheric dust collection rate, pressure drop, minimum, average, and maximum pore sizes, and dust entry depth were evaluated. The evaluation results are shown in Table 3 and Table 4.

Example 5

A 0.5-dtex raw material made of meta-type aramid fibers having a cut length of 38 mm and a 2.2-dtex raw material made of meta-type aramid fibers having a cut length of 51 mm were each independently carded. Then, the carded nonwoven fabric having a weight per unit of about 50 g/m² on the filtrate-collecting surface side and the carded nonwoven fabric having a weight per unit of about 200 g/m² on the opposite side were laminated with a scrim having a weight per unit of 70 g/m² as a base fabric interposed therebetween. The laminate was then needle-punched and calendered.

With respect to the obtained sample, the weight per unit, thickness, density, tensile strength, atmospheric dust collection rate, pressure drop, minimum, average, and maximum pore sizes, and dust entry depth were evaluated. The evaluation results are shown in Table 3 and Table 4.

Example 6

A 0.5-dtex raw material made of meta-type aramid fibers having a cut length of 38 mm and a 2.2-dtex raw material made of meta-type aramid fibers having a cut length of 51 mm were each independently carded. Then, the carded nonwoven fabric having a weight per unit of about 120 g/m² on the filtrate-collecting surface side and the carded nonwoven fabric having a weight per unit of about 200 g/m² on the opposite side were laminated with a scrim having a weight per unit of 70 g/m² as abase fabric interposed therebetween. The laminate was then needle-punched and calendered.

With respect to the obtained sample, the weight per unit, thickness, density, tensile strength, atmospheric dust collection rate, pressure drop, minimum, average, and maximum pore sizes, and dust entry depth were evaluated. The evaluation results are shown in Table 3 and Table 4.

Example 7

A 0.5-dtex raw material made of meta-type aramid fibers having a cut length of 38 mm and a 2.2-dtex raw material made of meta-type aramid fibers having a cut length of 51 mm were each independently carded. Then, the carded nonwoven fabric having a weight per unit of about 280 g/m² on the filtrate-collecting surface side and the carded nonwoven fabric having a weight per unit of about 200 g/m² on the opposite side were laminated with a scrim having a weight per unit of 70 g/m² as a base fabric interposed therebetween. The laminate was then needle-punched and calendered.

With respect to the obtained sample, the weight per unit, thickness, density, tensile strength, atmospheric dust collection rate, pressure drop, minimum, average, and maximum pore sizes, and dust entry depth were evaluated. The evaluation results are shown in Table 3 and Table 4.

Example 8

A 0.5-dtex raw material made of meta-type aramid fibers having a cut length of 38 mm and a 2.2-dtex raw material made of meta-type aramid fibers having a cut length of 51 mm were each independently carded. Then, the carded nonwoven fabric having a weight per unit of about 350 g/m² on the filtrate-collecting surface side and the carded nonwoven fabric having a weight per unit of about 200 g/m² on the opposite side were laminated with a scrim having a weight per unit of 70 g/m² as a base fabric interposed therebetween. The laminate was then needle-punched and calendered.

With respect to the obtained sample, the weight per unit, thickness, density, tensile strength, atmospheric dust collection rate, pressure drop, minimum, average, and maximum pore sizes, and dust entry depth were evaluated. The evaluation results are shown in Table 3 and Table 4.

Examples 9 to 12

A 0.5-dtex raw material made of meta-type aramid fibers having a cut length of 38 mm and a 2.2-dtex raw material made of meta-type aramid fibers having a cut length of 51 mm were each independently carded. Then, the carded nonwoven fabric having a weight per unit of about 200 g/m² on the filtrate-collecting surface side and the carded nonwoven fabric having a weight per unit of about 200 g/m² on the opposite side were laminated with a scrim having a weight per unit of 70 g/m² as a base fabric interposed therebetween. The laminate was then needle-punched and calendered. At this time, the weight per unit and thickness were changed as shown in Table 3 and Table 4.

With respect to the obtained sample, the weight per unit, thickness, density, tensile strength, atmospheric dust collection rate, pressure drop, minimum, average, and maximum pore sizes, and dust entry depth were evaluated. The evaluation results are shown in Table 3 and Table 4.

Comparative Example 1

A 0.1 to 0.2-dtex raw material made of meta-type aramid fibers having a cut length of 38 mm and a 2.2-dtex raw material made of meta-type aramid fibers having a cut length of 51 mm were each independently carded. Then, the carded nonwoven fabric having a weight per unit of about 200 g/m² on the filtrate-collecting surface side and the carded nonwoven fabric having a weight per unit of about 200 g/m² on the opposite side were laminated with a scrim having a weight per unit of 70 g/m² as abase fabric interposed therebetween. The laminate was then needle-punched and calendered.

With respect to the obtained sample, the weight per unit, thickness, density, tensile strength, atmospheric dust collection rate, pressure drop, minimum, average, and maximum pore sizes, and dust entry depth were evaluated. The evaluation results are shown in Table 3 and Table 4.

Comparative Example 2

2.2-dtex raw materials made of meta-type aramid fibers having a cut length of 51 mm were carded. Then, the carded nonwoven fabric having a weight per unit of about 200 g/m² on the filtrate-collecting surface side and the carded nonwoven fabric having a weight per unit of about 200 g/m² on the opposite side were laminate with a scrim having a weight per unit of 70 g/m² as a base fabric interposed therebetween. The laminate was then needle-punched and calendered.

With respect to the obtained sample, the weight per unit, thickness, density, tensile strength, atmospheric dust collection rate, pressure drop, minimum, average, and maximum pore sizes, and dust entry depth were evaluated. The evaluation results are shown in Table 3 and Table 4.

Comparative Example 3

A 0.5-dtex raw material made of meta-type aramid fibers having a cut length of 38 mm and a 0.1 to 0.2-dtex raw material made of meta-type aramid fibers having a cut length of 38 mm were each independently carded. Then, the carded nonwoven fabric having a weight per unit of about 200 g/m² on the filtrate-collecting surface side and the carded nonwoven fabric having a weight per unit of about 200 g/m² on the opposite side were laminated with a scrim having a weight per unit of 70 g/m² as a base fabric interposed therebetween. The laminate was then needle-punched and calendered.

With respect to the obtained sample, the weight per unit, thickness, density, tensile strength, atmospheric dust collection rate, pressure drop, minimum, average, and maximum pore sizes, and dust entry depth were evaluated. The evaluation results are shown in Table 3 and Table 4.

Comparative Example 4

A 0.5-dtex raw material made of meta-type aramid fibers having a cut length of 38 mm and a 5.0-dtex raw material made of meta-type aramid fibers having a cut length of 76 mm were each independently carded. Then, the carded nonwoven fabric having a weight per unit of about 200 g/m² on the filtrate-collecting surface side and the carded nonwoven fabric having a weight per unit of about 200 g/m² on the opposite side were laminated with a scrim having a weight per unit of 70 g/m² as abase fabric interposed therebetween. The laminate was then needle-punched and calendered.

With respect to the obtained sample, the weight per unit, thickness, density, tensile strength, atmospheric dust collection rate, pressure drop, minimum, average, and maximum pore sizes, and dust entry depth were evaluated. The evaluation results are shown in Table 3 and Table 4.

TABLE 3
	Structure
				Opposite Side from
	Collection Surface	Scrim	Collection Surface
	Single-Fiber	Nonwoven Fabric	Weight	Single-Fiber	Nonwoven Fabric	Weight
	Fineness	Weight per Unit	per Unit	Fineness	Weight per Unit	per Unit	Thickness	Density
	dtex	g/m2	g/m2	dtex	g/m2	g/m2	mm	g/cm3
Example 1	0.5	200	70	2.2	200	525	2.0	0.26
Example 2	0.8	200	70	2.2	200	457	1.8	0.25
Example 3	0.5	200	70	0.5	200	454	1.9	0.24
Example 4	0.5	200	70	3.0	200	475	1.9	0.25
Example 5	0.5	50	70	2.2	200	330	1.4	0.24
Example 6	0.5	120	70	2.2	200	405	1.6	0.25
Example 7	0.5	280	70	2.2	200	555	2.2	0.25
Example 8	0.5	350	70	2.2	200	623	2.5	0.25
Example 9	0.5	200	70	2.2	200	515	1.4	0.37
Example 10	0.5	200	70	2.2	200	521	2.0	0.26
Example 11	0.5	200	70	2.2	200	525	3.5	0.15
Example 12	0.5	200	70	2.2	200	470	3.8	0.12
Comparative	0.1-0.2	200	70	2.2	200	473	2.0	0.24
Example 1
Comparative	2.2	200	70	2.2	200	461	1.7	0.27
Example 2
Comparative	0.5	200	70	0.1-0.2	200	459	2.0	0.23
Example 3
Comparative	0.5	200	70	5.0	200	488	2.0	0.24
Example 4

TABLE 4
	Tensile Strength	Atmospheric Dust Collection Efficiency		Minimum	Average	Maximum
	MD	CD	0.3	0.5	1	2	5	Pressure	Pore	Pore	Pore	Dust
	Direction	Direction	um	um	um	um	um	Drop	Size	Size	Size	Entry
	N/5 cm	N/5 cm	%	%	%	%	%	Pa	μm	μm	μm	Depth
Example 1	686	1380	55	66	83	94	100	95	4	12	39	Pass
Example 2	640	1711	41	52	75	88	100	58	5	17	43	Pass
Example 3	507	772	71	82	95	99	100	155	3	10	29	Pass
Example 4	700	1200	40	50	70	85	100	80	6	17	44	Pass
Example 5	600	1000	27	35	59	78	100	46	7	16	45	Fail
Example 6	650	1200	41	50	73	85	100	93	5	15	37	Pass
Example 7	686	1450	60	70	88	97	100	120	3	11	33	Pass
Example 8	700	1500	70	80	92	99	100	205	3	10	28	Pass
Example 9	700	1400	65	75	93	97	100	200	3	10	28	Pass
Example 10	670	1350	56	67	84	95	100	96	4	11	38	Pass
Example 11	650	1270	39	47	66	79	94	39	5	15	49	Pass
Example 12	660	1300	33	40	60	75	90	33	6	17	51	Fail
Comparative
Example 1	600	400	65	75	93	97	100	210	3	10	28	Pass
Comparative
Example 2	733	1962	28	36	60	77	100	44	7	18	47	Fail
Comparative
Example 3	600	500	70	80	97	98	100	250	2	8	23	Pass
Comparative
Example 4	720	1240	30	40	60	75	100	70	7	19	50	Fail

Examples 13 to 18, Comparative Examples 5 to 8

On the respective surfaces of the scrim, a collection-surface web and an opposite-surface web were laminated and needle-punched to integrate with the base fabric, and the side to serve as a dust-collecting surface was subjected to a singeing treatment, thereby giving a filter fabric. In the case where a filter fabric having a lower porosity was to be obtained, calendering was performed at a temperature of 200° C., a linear pressure of 100 kgf/cm (980 N/cm), and a speed of 2 m/min, thereby giving a filter fabric. As a PTFE membrane-attached product, the above processing was followed by the lamination of a PTFE membrane, thereby giving a filter fabric. The evaluation results are shown in Table 5 and Table 6.

TABLE 5
		Fineness	Fineness of					Tensile	Tensile
		of	Opposite Side		Weight	Thickness		Strength	Strength
		Collection	from Collection		per	Pressing		in MD	in CD	Breath-
	Raw	Surface	Surface	Processing	Unit	5 g/mm2	Porosity	Direction	Direction	ability
	Material	dtex	dtex	Details	g/m2	mm	%	N/5 cm	N/5 cm	cm3/cm2/s
Example 13	Meta-aramid	0.2	0.5	Singeing	461	3.5	91	600	550	4
Example 14	Meta-aramid	0.5	0.5	Singeing	461	3.5	91	630	700	10
Example 15	Meta-aramid	0.5	2.2	Singeing	525	3.5	89	650	1200	14
Example 16	Meta-aramid	0.2	0.5	Singeing/	461	1.9	82	610	600	13
				Calendering
Example17	Meta-aramid	0.5	0.5	Singeing/	461	1.9	82	610	600	13
				Calendering
Example 18	Meta-aramid	0.5	2.2	Singeing/	525	2.0	81	660	1250	6
				Calendering
Comparative	Meta-armid +	2.2	2.2	Singeing/
Example 5	PTFE			Calendering/PTFE
	membrane			Lamination
Comparative	PPS + PTFE	2.2	2.2	Singeing/	518	2.0	81	720	1700	3.3
Example 6	membrane			Calendering/PTFE
				Lamination
Comparative	Meta-aramid	2.2	2.2	Singeing	552	1.8	77	710	1650	3.5
Example 7					491	3.2	89	700	1800	22
Comparative	Meta-aramid	2.2	2.2	Singeing/
Example 8				Calendering	491	1.7	80	710	1850	20

TABLE 6
													Pressure
											Average		Drop
							Mini-	Aver-	Max-		Increase	Pressure	Increase
	Atmospheric Dust		mum	age	imum	Average	Rate	Drop	Rate
	Collection Effciency	Pressure	Pore	Pore	Pore	after	after	after	after	Dust
	(Linear Velocity: 5.1 cm/s)	Drop	Size	Size	Size	Abrasion	Abrasion	Abrasion	Abrasion	Entry
	0.3 um	0.5 um	1 um	2 um	5 um	Pa	μm	μm	μm	μm	%	Pa	%	Depth
Example 13	60	65	80	90	100	65	4	13	44	13	0	67	−3	Pass
Example 14	50	59	77	88	100	53	5	15	47	15	0	55	−3	Pass
Example 15	39	47	66	79	94	39	5	15	49	15	3	42	−7	Pass
Example 16	70	69	85	96	100	110	3	12	40	15	25	110	0	Pass
Example 17	60	67	84	95	100	100	5	15	42	15	3	100	0	Pass
Example 18	55	66	83	94	100	95	4	12	39	12	0	97	−2	Pass
Comparative
Example 5	99	100	100	100	96	198	0.32	0.6	32	17	2585	51	289	Pass
Comparative	98	100	99	99	95	180	0.76	1.5	25	19	1130	60	200	Pass
Example 6
Comparative	27	31	45	58	96	25	11	24	60	24	1	27	−9	Fail
Example7
Comparative
Example 8	25	30	49	66	73	49	6	17	46	17	−1	51	−5	Fail

Examples 19 to 36 and Comparative Examples 9 to 11

A polymetaphenylene isophthalamide powder produced by an interfacial polymerization method was suspended in N-methyl-2-pyrrolidone (NMP) to forma slurry, and then heated for dissolution to give a transparent polymer solution. This polymer solution was, as a spinning dope, discharged and spun from a spinneret into a coagulation bath. After the passage of the immersion length (effective coagulation bath length), the fiber was once drawn in air, stretched, and subjected to a drying treatment, and then a polymetaphenylene isophthalamide tow fiber was obtained. The tow was crimped in a stuffing box-type crimper and heat-set, and then an oil was applied, followed by cutting to a certain length, thereby giving a meta-type aramid short fiber. The evaluation results are shown in Table 7. Incidentally, in the table, CN: the number of crimps, CD: crimp degree, CR: residual crimp degree, OPU: oil deposition rate.

TABLE 7
Single-Fiber Fineness × Fiber Length mm	0.1 × 38	0.5 × 76	0.5 × 51	0.5 × 38	2.2 × 76
Single-Fiber Fineness	dtex	0.10	0.49	0.47	0.49	0.47	0.48	0.50	0.50	0.49	0.50	2.18
Strength	cN/dt	2.0	3.2	3.2	3.2	3.2	3.5	2.9	3.3	3.2	2.9	4.5
Elongation	%	33	37	38	35	33	36	37	33	32	36	37
CN	T/25 mm	—	5	10	15	5	10	15	5	10	15	11
CD	%	—	2.2	2.2	8.4	3.8	3.8	7.2	2.9	2.9	6.3	17.0
OR	%	—	1.7	1.7	6.7	2.8	2.8	6.3	1.7	1.7	5.0	12.0
OPU	%	—	0.65	0.59	0.73	0.71	0.58	0.84	0.56	0.70	0.48	0.60

Further, a scrim was prepared as described above. On the respective surfaces of the scrim, a collection-surface web and an opposite-surface web were laminated and needle-punched to integrate with the base fabric. Further, in order to form a filter fabric for a bag filter, the side to serve as a dust-collecting surface was subjected to a singeing treatment. In the case where a filter fabric having a lower porosity was to be obtained, calendering was performed at a temperature of 200° C., a linear pressure of 100 kg/cm (980 N/cm), and a speed of 2 m/min, thereby giving a filter fabric. The evaluation results are shown in Table 8 and Table 9.

TABLE 8
				Process Passing
		Properties of
	Short Fibers a	Short Fibers a	Short Fibers b
		Number		Web				Number
		of		Width				of		A/B	Weight
	Fine-	Crimps	Fiber	Increase				Crimps	Fiber	Weight	per	Thick-	Poro-	Tensile Strength
	ness	crimps/	Length	Rate		Wrap-	Fineness	crimps/	Length	Ratio	Unit	ness	sity	MD	CD
	dtex	2.54 cm	mm	%	Nep	Around	dtex	2.54 cm	mm	50/50	g/m2	mm	%	N/5 cm	N/5 cm
Example 19	0.5	10	51	Pass	Pass	Pass	2.2	11	76	50/50	500	1.8	80	734	1363
Example 20	0.5	10	51	Pass	Pass	Pass	2.2	11	76	50/50	500	3.2	89	701	1503
Example 21	0.5	5	38	Fail	Pass	Pass	2.2	11	76	50/50	—	—	—	—	—
Example 22	0.5	10	38	Fail	Pass	Pass	2.2	11	76	50/50	502	1.7	79	782	1317
Example 23	0.5	15	38	Pass	Fail	Fail	2.2	11	76	50/50	512	1.9	81	737	1453
Example 24	0.5	5	51	Fail	Pass	Pass	2.2	11	76	50/50	490	1.6	78	716	1610
Example 25	0.5	15	51	Pass	Fail	Fail	2.2	11	76	50/50	503	1.9	80	756	1323
Example 26	0.5	5	76	Pass	Fail	Fail	2.2	11	76	50/50	567	1.9	78	745	1826
Example 27	0.5	10	76	Pass	Fail	Fail	2.2	11	76	50/50	502	1.8	80	765	1596
Example 28	0.5	15	76	Pass	Fail	Fail	2.2	11	76	50/50	489	1.8	80	719	1430
Example 29	0.5	5	38	Fail	Pass	Pass	2.2	11	76	50/50	—	—	—	—	—
Example 30	0.5	10	38	Fail	Pass	Pass	2.2	11	76	50/50	502	3.3	89	801	1161
Example 31	0.5	15	38	Pass	Fail	Fail	2.2	11	76	50/50	512	3.8	90	737	1321
Example 32	0.5	5	51	Fail	Pass	Pass	2.2	11	76	50/50	490	3.0	88	678	1441
Example 33	0.5	15	51	Pass	Fail	Fail	2.2	11	76	50/50	503	3.5	90	746	1118
Example 34	0.5	5	76	Pass	Fail	Fail	2.2	11	76	50/50	567	3.5	88	726	1763
Example 35	0.5	10	76	Pass	Fail	Fail	2.2	11	76	50/50	502	3.4	89	727	1586
Example 36	0.5	15	76	Pass	Fail	Fail	2.2	11	76	50/50	489	3.4	89	710	1350
Comparative	0.1	—	—	—	—	—	—	—	—	—	—	—	—	—	—
Example 9
Comparative	2.2	11	76	Pass	Pass	Pass	2.2	11	76	50/50	484	1.6	78	779	2070
Example 10
Comparative	2.2	11	76	Pass	Pass	Pass	2.2	11	76	50/50	484	3.1	89	747	1982
Example 11

TABLE 9
	Atmospheric Dust CollectionEfficiency				Pore	Pore	Pore
	(Linear Velocity: 5.1 cm/s)		Pressure	Breath-	Size	Size	Size	Dust
	0.3 um	0.5 um	1 um	2 um	5 um	Drop	ability	Minimum	Average	Maximum	Entry
	%	%	%	%	%	Pa	cm3/cm2-s	μm	μm	μm	Depth
Example 19	64	80	93	98	100	156	4.4	3.2	11	39	Pass
Example 20	48	58	80	91	100	55	17	6.2	18	65	Pass
Example 21	—	—	—	—	—	—	—	—	—	—	—
Example 22	49	64	81	92	97	101	5.5	6.0	16	55	Pass
Example 23	61	76	90	97	93	123	4.4	4.0	13	42	Pass
Example 24	54	68	86	95	96	129	5.2	3.2	11	41	Pass
Example 25	68	86	96	99	98	149	4.4	3.1	11	34	Pass
Example 26	58	76	92	98	100	145	4.4	3.7	12	40	Pass
Example 27	59	73	90	97	100	143	4.6	3.3	12	42	Pass
Example 28	64	77	92	98	100	139	4.6	3.8	12	41	Pass
Example 29	—	—	—	—	—	—	—	—	—	—	—
Example 30	35	47	65	80	92	42	13	5.3	17	59	Pass
Example 31	45	59	78	91	98	51	11	6.3	16	51	Pass
Example 32	40	50	69	84	100	48	19	5.9	18	64	Pass
Example 33	51	62	81	92	99	56	17	5.6	18	61	Pass
Example 34	45	55	77	89	99	54	17	5.5	18	63	Pass
Example 35	43	53	74	86	97	52	18	5.9	19	65	Pass
Example 36	49	61	83	92	98	53	18	5.8	18	62	Pass
Comparative	—	—	—	—	—	—	—	—	—	—	—
Example 9
Comparative	31	40	60	78	81	57	11	6.0	18	46	Fail
Example 10
Comparative	22	29	51	67	94	25	34	10.9	25	67	Fail
Example 11

Incidentally, fibers having a single-fiber fineness of 0.1 dtex have poor spinnability, and thus were not obtained due to frequent occurrence of yarn breakage during the production process.

INDUSTRIAL APPLICABILITY

According to the invention, a filter fabric for a bag filter, which has excellent collection performance and low pressure drop and is resistant to a decrease in dust collection performance due to abrasion or cracking, and also a method for producing the same are provided. The industrial value thereof is extremely high.

Claims

1. A filter fabric for a bag filter, comprising: a nonwoven fabric A comprising short fibers a having a single-fiber fineness of 0.3 to 0.9 dtex; a base fabric; and a nonwoven fabric B comprising short fibers b having a single-fiber fineness of 0.3 to 4.0 dtex, the nonwoven fabric A, the base fabric, and the nonwoven fabric B being laminated in this order.

2. The filter fabric for a bag filter according to claim 1, wherein at least one of the short fiber a and the short fiber b has a tensile strength of 2.2 cN/dtex or more.

3. The filter fabric for a bag filter according to claim 1, wherein at least one of the short fiber a and the short fiber b has an elongation of 25% or more.

4. The filter fabric for a bag filter according to claim 1, wherein at least one of the short fiber a and the short fiber b has 6 to 30 crimps/2.54 cm.

5. The filter fabric for a bag filter according to claim 1, wherein at least one of the short fiber a and the short fiber b has a crimp degree within a range of 8 to 40%.

6. The filter fabric for a bag filter according to claim 1, wherein at least one of the short fiber a and the short fiber b has a fiber length within a range of 20 to 80 mm.

7. The filter fabric for a bag filter according to claim 1, wherein at least one of the short fiber a and the short fiber b includes a meta-type aramid fiber.

8. The filter fabric for a bag filter according to claim 1, wherein at least one of the nonwoven fabric A and the nonwoven fabric B has a weight per unit within a range of 100 to 300 g/m2.

9. The filter fabric for a bag filter according to claim 1, having a porosity within a range of 75 to 90%.

10. The filter fabric for a bag filter according to claim 1, wherein the nonwoven fabric A is placed on a filtrate-collecting surface side.

11. The filter fabric for a bag filter according to claim 1, wherein all fibers forming the filter fabric for a bag filter are meta-type aramid fibers.

12. The filter fabric for a bag filter according to claim 1, wherein after 5,000 abrasion cycles in accordance with a Martindale abrasion test (counterpart: cotton cloth) on a surface of the nonwoven fabric A or a surface of the nonwoven fabric B, the average pore size increase rate is 30% or less, and the pressure drop increase rate is 30% or less.

13. The filter fabric for a bag filter according to claim 1, having a breathability within a range of 5 to 10 cm3/cm2·sec.

14. The filter fabric for a bag filter according to claim 1, wherein on the surface of the nonwoven fabric A or the surface of the nonwoven fabric B, the average pore size is within a range of 7 to 17 μm.

15. The filter fabric for a bag filter according to claim 1, having a tensile strength of 600 N/5 cm or more both in the MD direction and the CD direction.

16. A method for producing a filter fabric for a bag filter, the method comprising: laminating a nonwoven fabric A comprising short fibers a having a single-fiber fineness of 0.3 to 0.9 dtex, a base fabric, and a nonwoven fabric B comprising short fibers b having a single-fiber fineness of 0.3 to 4.0 dtex in this order; and then subjecting the laminate to needle punching and then calendering.

17. The filter fabric for a bag filter according to claim 2, wherein at least one of the short fiber a and the short fiber b has an elongation of 25% or more.