BRPI0808603A2 - "VENTILATION AND APPLICATION Duct" - Google Patents

Description

“VENTILATION AND APPLICATION Duct”

Field of the Invention

The present invention relates to the application of a paromatic polyamide. More specifically, it refers to a ventilation duct containing the p-aromatic polyamide and its application, as well as the application of p-aromatic polyamide to the ventilation duct.

Background of the Invention

A ventilation duct is generally used in a well or other areas to introduce fresh air into the work region and to replace waste gas, the waste gas described may be a mixture of air and other flammable, explosive and toxic gases. In an explosive mine operation, the pipeline flow is placed in front of the blast site to rapidly dilute toxic, flammable, explosive gases using fresh air. Therefore, the vent duct must be made of an explosion resistant, impact resistant, cut resistant, flame retardant material in order to reduce the incident [damage] to a minimum.

Regular vent ducts used in explosive wells are those that use fiberglass, polyester, polyvinyl alcohol fiber (vinylon), etc., as the reinforcing structure material. The glass fiber has a relatively high tensile strength, but the tear strength of fabrics made from it is relatively poor. Organic fibers such as polyester fiber and vinyl fiber are extraordinarily soft, but their tensile strength is not high, and they are not flame retardant. However, the service life of these regular materials in the ventilation ducts is extremely short, as a result, the risk of accidents is extraordinarily high.

So far, there have been no ventilation ducts that at the same time have extraordinarily high tensile strength, tear resistance, flexibility, flame retardant and good explosive impact resistance manufactured using existing technology.

Therefore, it is an urgent need in the field of the present invention to develop a ventilation duct which at the same time has extraordinarily high tensile strength, tear strength, flexibility, flame retardant and good explosive impact resistance.

Brief Description of the Invention The object of the present invention is to provide a ventilation duct which at the same time has extraordinarily high tensile strength, tear strength, flexibility, flame retardant and good explosive impact resistance; Said ventilation duct can be well applied in the explosive mining areas.

In one aspect, the present invention features a ventilation duct, which comprises:

a layer of fabric containing p-aromatic polyamide fiber; and

the polymer or polymer blend coated on the layer inside and / or outside the described textile fabric layer.

In a preferred embodiment of the present example, the described paromatic polyamide is selected from poly (p-phenylene terephthalate) (i.e. poly (p-phenylene terephthalate), poly (pfenylene terephthalate) copolymer, poly (p (benzamide), poly (p-benzamide) copolymer, polysulfonamide, polysulfonamide copolymer, and mixtures thereof.

In another preferred embodiment, the disclosed polymer includes polyvinyl chloride, chlorinated polyvinyl chloride, polyethylene chloride, polychloroprene rubber, ethylene propylene rubber, EPT rubber, butadiene acrylonitrile rubber, natural rubber, styrene rubber. - butadiene, epichlorohydrin rubber, chlorosulfonated polyethylene rubber, fluorine rubber, silicone rubber, butyl rubber, halogenated butyl rubber, polyurethane, polyethylene, polypropylene, epoxy resin, phenolic resin and mixtures thereof, the polymer blend described includes the mixture of the polymers described with at least one of the substances selected from the following group: solvent, plasticizer, packaging agent, flame retardant agent, vulcanizing agents, age inhibiting agent, vulcanization promoter, antioxidant, hardening agent anti-burning agent, anti-ultraviolet light stabilizing agent, anti-static agent o, thixotropic, thermal stabilizing agent and lubricants.

In another preferred embodiment, at least in the warp direction, the fabric layer is comprised of 100% paromatic polyamide fiber, or the yarn combination consisting of 5 to 100% p-aromatic polyamide fiber and 0 to 95% of other fibers, wherein the other fibers described include: fiberglass, polyester fiber, polyamide fiber, polyvinyl alcohol fiber, cotton fiber, vinylon fiber, rayon fiber, viscose fiber, elastane, fiber polyvinyl chloride, acrylic fiber, basalt fiber, aromatic polyamide fibers, polyester staple fiber, polyamide staple fibers, polyvinyl alcohol staple fibers, glass staple fibers, rayon staple fibers, vinyl staple fibers viscose, elastane staple fibers, polyvinyl chloride staple fibers, acrylic staple fibers, and mixtures thereof.

In another preferred embodiment, 100% paromatic polyamide fibers or yarn combination is twisted or non-twisted, the torsion coefficient of the described postaromatic polyamide fiber or combined yarn is from 0 to 25, where the coefficient of twist is defined as follows:

torsion coefficient = number of twists per meter x V denier number

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Where the denier number refers to the weight per 9,000 meters of fiber, calculated in grams.

In another preferred embodiment, the warp and weft tensile strength of the fabric layer is greater than 3,000 N / 50 mm.

In another preferred embodiment, the bond strength between the

fabric layer and the polymer or polymer blend described is greater than 20 N / 25 mm.

In another aspect, the present invention relates to the application of the above described ventilation duct to the blast or blast sites.

In another preferred embodiment, the location of explosives or

Blasting is a well or gallery.

In another aspect, the present invention relates to the application of p-aromatic polyamide fiber to the ventilation duct.

Brief Description of the Figures Figure 1 is a profile of the ventilation duct structure with

based on an embodiment of the present invention, wherein the polymer or polymer blend layer is coated on the outside of the fabric layer containing the p-aromatic polyamide fiber.

Figure 2 is a profile of the vent duct structure based on another embodiment of the present invention, wherein the polymer or polymer blend layer is coated within the fabric layer containing the p-aromatic polyamide fiber.

Figure 3 is a profile view of the vent duct structure based on another embodiment of the present invention, wherein the polymer or polymer blend layer is coated on the outside and inside of the fabric layer containing the p-aromatic polyamide fiber.

The person skilled in the art will appreciate that the size and percentage in Figures 1 to 3 do not represent the actual size and percentage.

Detailed Description of the Invention

It has been discovered by Depositors after prolonged and in-depth studies that p-aromatic polyamide fiber is an extraordinarily high strength organic fiber. It is flame retardant, with a limiting oxygen index of 29, it is self-extinguishing after being removed from a fire, the fabric is malleable, and it has extraordinarily high resistance both in warp and weft direction, including tensile strength and tear strength, it is therefore extremely suitable for use as reinforcing material for the structure of ventilation ducts in explosive wells. Compared to regular fiberglass, vinyl fiber, or polyester fiber products, is capable of significantly improving the safety level of explosives or exploding underground environments. It is based on the discovery described above that the present invention may be realized.

In the first aspect of the present invention, a venting duct is provided, the disclosed venting duct is composed of a fabric layer containing p-aromatic polyamide fiber as well as an inner coated polymer or polymer blend layer and / or outside of the fabric layer described.

In the present invention, p-aromatic polyamide refers to the para-aramid fiber defined in ISO 2076, ie a linear polymer composed of an aromatic group bonded via an amide bond or imide bond, wherein at least 85% Wool Amicide Bond The imide bond is directly bonded to the aromatic ring, i.e. the imide bond contained therein, with the number of imide bonds not being greater than the amide bond.

There are no specific restrictions on p-aromatic polyamide applicable in the present invention, which may be a regular p-aromatic polyamide, typical examples of which include, but are not limited to: poly (p-phenylene terephthalate) such as Kevlar ®, Twaron, Heracron, Terlon and Tervar, and their analogs; poly (p-phenylene terephthalate) copolymers, such as Technora, SVM, Armos and Rusar, and their analogs; poly (p-benzamide);

poly (p-benzamide) copolymers; polysulfonamide, polysulfonamide copolymers, and mixtures thereof.

The p-aromatic polyamide applicable in the present invention may include substances with structures as shown in the following molecular formulas, but are not limited to these specific examples only:

o o

where m and n indicate the number of structural units described

above in the molecular chain, or are known as the degree of polymerization. There are no specific restrictions on the numerical values of m and n, and they can be -Q — 1,2, -or-some other integer.

In one embodiment of the present invention, the fabric layer of the described post aromatic polyamide fiber may be a seamless air channel with a continuous knitting (structure), but may also be a seamed air channel of the stitched fabric. There are no specific restrictions on the coating polymer in the present invention, which may be a common polymer in the present state of the art. Typical examples include, but are not limited to: polyvinyl chloride, chlorinated polyvinyl chloride, chlorinated polyethylene, polychloroprene rubber, ethylene propylene rubber, EFA rubber, butadiene acrylonitrile rubber, natural rubber, styrene butadiene, epichlorohydrin rubber, chlorosulfonated polyethylene rubber, fluorine rubber, silicone rubber, butyl rubber, halogenated butyl rubber, polyurethane, polyethylene, polypropylene, epoxy resin, phenolic resin 10 and mixtures thereof, the polymer blend described includes: A mixture of the described polymers with at least one of the substances selected from the following group: solvent, plasticizer, packaging agent, flame retardant agent, vulcanizing agent, age inhibiting agent, vulcanization promoter, antioxidant, hardening agent. 15 anti-burning agent, anti-ultraviolet light stabilizing agent, anti-static agent, t ixotropic, thermal stabilizing agent and lubricants.

In the present invention, the disclosed polymer or polymer blend layer may be coated using the regular coating method in the field of the present invention on the inside and / or outside of the described fabric layer, the described coating method includes , but is not restricted to: dipping, brushing and calendering.

There are no specific restrictions on the polymer layer thickness applicable to the coating on the fabric layer in the present invention.

In another embodiment of the present invention, the ventilation duct

described may also include a coating layer.

In another embodiment of the present invention, there are no specific restrictions on the knitting and weaving process and the described fabric layer method, which may be any common knitting and weaving process in the field of the present invention, such as knitting. , shuttles, etc.

In another embodiment of the present invention, there is no specific restriction on the described fabric layer structure, which may be any common prior art structure such as taffeta, satin, twill, broken twill, basket, Oxford, multi-axial fabric , direct warp or straight weft, the structure of the solid core and all derivatives thereof.

In another embodiment of the present invention, there is no specific restriction on density in different directions of the fabric layer structure described, such as warp and weft density, i.e. counts per unit count. width, and may be the same or different.

In another embodiment of the present invention, there is no specific restriction on single-stranded yarns [fibers] of different directions constituting the fabric layer, such as the single-stranded yarn diameter of the fiber and the diameter of the warp. of single stranded fiber yarns, and may be the same or different.

In another embodiment of the present invention, at least in one direction of knitting the fabric layer, such as warp and weft direction, may be composed of 100% paromatic polyamide fiber, or yarn combination, composed of 5-100% (preferably 20-100%, more preferably 50-100%) of polyamidaparomatic fiber and 0-95% (preferably 70-80%) preferably other fibers, in that the other fibers described may include, but are not limited to: glass fiber, polyester fiber, polyamide fiber, polyvinyl alcohol fiber, cotton fiber, vinyl fiber, rayon fiber, viscose fiber, elastane, fiber polyvinyl chloride, acrylic fiber, basalt fiber, aromatic polyamide fibers, polyester staple fiber, polyamide staple fibers, polyvinyl alcohol staple fibers, staple glass fibers, rayon staple fibers, staple fibers vinylon, viscose staple fibers, elastane staple fibers, polyvinyl chloride staple fibers 5, acrylic staple fibers, and mixtures thereof.

In another preferred embodiment, 100% paromatic polyamide fibers or yarn combination may be twisted or non-twisted, the torsion coefficient of the p-aromatic polyamide fiber or combined yarn 10 described is from 0 to 25, preferably 0-10, more preferably 0-5, and most preferably 0-3, wherein the torsion coefficient is defined as follows:

torsion coefficient = number of twists per meter x V denier number

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Where the denier number refers to the weight per 9,000 meters of fiber, calculated in grams. The torsion coefficient described may also be calculated using other calculation methods applicable to the prior art.

In another embodiment of the present invention, warp and weft tensile strength of the described fabric layer is greater than 3,000 N / 50 mm, preferably greater than 4,000 N / 50 mm, and more preferably greater than 3,000 N / 50 mm. 5,000 N / 50 mm.

In another embodiment of the present invention, the tensile strength between the woven layer and the polymer or blend layer of the described polymers is greater than 20N / 25mm, preferably greater than 25N / 25mm, more preferably, greater than 30N / 25mm.

See attached drawings.

As shown in Figure 1, it is the structure of a ventilation duct based on an embodiment of the present invention, wherein the polymer or polymer blend layer 20 is coated on the outside of the fabric layer 10.

As shown in Figure 2, it is the structure of a ventilation duct based on another embodiment of the present invention, wherein the polymer or polymer blend layer 20 is coated within the fabric layer 10.

As shown in Figure 3, it is the structure of a ventilation duct based on another embodiment of the present invention, wherein the polymer layer or polymer blend 20 is coated, respectively, on the inside and outside of the fabric layer 10, wherein the polymer or polymer blend layer coated on the inside and outside, respectively, may be the same or different.

The second aspect of the present invention relates to the application of the above described ventilation duct to the blasting or blasting sites.

In another embodiment of the present invention, the blasting or blast sites may be a well or gallery.

The third aspect of the present invention relates to the application of p-aromatic polyamide fiber to the ventilation duct.

The main advantages of the present invention are:

The ventilation duct of the present invention at the same time has extraordinarily high tensile strength, tear resistance, flexibility and flame retardant and very good explosion tolerance, it can be very apical in the area of explosive mining.

The following is a more detailed description of the present invention.

in association with the specific examples. However, it should be understood that such embodiments are for illustration only of the present invention rather than a restriction of the scope of the present invention. In the following embodiments, by experimental methods where conditions are not specified, usually the regular conditions or conditions recommended by the manufacturers are followed. Unless otherwise specified, all parts and percentages are calculated by weight.

Examples Examples 1 to 6

Tensile strength test (standard test: HG / T 2580-1994 (in place of GB 5572) in MT 383-1995. Equivalent to IS01421)

The tissue layer in the ventilation duct

ventilation) is cut warp and weft-wise on a 50 mm wide piece of fabric to test tensile on an Instron® tentile tester (purchased from Instron Company, Norwood, MA, USA); The tensile tester automatically records the value of the maximum strength required for breakage damage.

Tear Strength Test (standard test: ASTM D 5587)

The tissue layer in the ventilation duct (ventilation duct tissue) is cut cut in the warp and weft direction into a 150 χ 75 mm wide piece of fabric, with a notch preserved in the middle of the longitudinal side of 150 mm in vertical direction to the longitudinal side. The specimen is then held [clamped] on the tensile tester, with the direction of the notch being parallel to the horizontal direction, and with the upper and lower notch ends being held in the clamp, “before the tensile tester is started for the experiment. Tearing The tensile tester automatically records the value of the maximum strength required to break damage.

Table 1 shows the test results in Example

from 1-6. Table 1

Examples Weight grams Tissue Tensile Strength Duct Tear Resistance (g / m2) Unventilated Vent Duct Uncoated Coating Tear Resistance Tension Resistance at Tear Tear (N50 Direction) direction of direction mm) warp (N / 50 weft (N) warp (N) mm) Example 1: 202 1845 2400 449 268 pure vivid fiber fabric Example 2: 309 2380 2590 495 537 mixed glass wool fabric Example 3: 195 8035 7665> 1997> 2328 Kevlar® Fabric A Example 4: 434 16670 18230> 3226> 2530 Kevlar® Fabric B Example 5: 304 9840 9540> 2075 > 2733 Kevlar® C fabric Example 6: 274 8750 6300> 3585> 1725 Kevlar® D fabric In the tear test, because of the tear resistance of Kevlar® fabric.

Kevlar® is too high, the fabric samples cannot be torn, and the fiber is extracted from the fabric instead. Therefore, it can only be indicated with [shown to have] a resistance value greater than one given.

Listed in Table 1 are the tensile strength data of the fabric samples prior to coating. Judging from Table 1, it can be clearly seen that where the weight per unit area is close (comparison between Example 1 and Example 3, and the comparison between Example 2 and Example 5), the tensile strength of the Kevlar® ventilation duct fabric is much higher than the strength of normal fiberglass fabric and blended glass wool fabric. If the weight per unit area of Kevlar® is increased, its tensile strength may be improved. For example, the weight area per unit of Kevlar® B fabric in Example 4 is only 2.2 times larger than the pure fiberglass fabric in Example 1, but its tensile strength is almost 9 times greater. . This indicates that with the same strength obtained, the weight of the product's ventilation duct can be reduced tremendously if Kevlar® is used, or with the same weight, a very high degree of resistance can be achieved using the duct product. ® ventilation fan.

Examples 7 to 12

Sample performance in Examples 1-6 after coating is determined in Examples 7-12. The coating process is: the fabric is laid, the polyvinyl chloride paste is poured into one end of the fabric, then the polyvinyl chloride paste is coated on the fabric surface using a manual coating machine. with thickness control. Said sample is then placed in a T68 ° C drying oven to be plasticized for 7 minutes 25 minutes before removal. The coated fabric is cut to the required size and used as an example of tear resistance to be tested.

The following test results are shown in Table 2 in Examples 7 through 12. Table 2

Examples Weight grams Tissue Tensile Strength Duct Tear Resistance (g / m2) Unventilated Vent Duct Uncoated Tear Resistance Tension Resistance at Tear Tear Direction Direction (N50 mm) warp (N / 50 weft (N) warp (N) mm) Example 7: pure vivid fiber fabric 202 2030 2245 73 98 Example 8: mixed glass wool fabric 309 3005 2770 121 144 Example 9: Fabric 195 6550 7595 1413 1623 A Kevlar® Example 10: 434 15200 16640> 5000> 5000 Fabric B Kevlar® Example 11: Fabric 304 7030 8495 1051 886 C Kevlar® Example 12: t 274 6030 5950 491 461 D Kevlar® In the tear test, because of the tear resistance of the

Kêvlãr® “B is too high, the fabric samples cannot be torn, and the fiber is extracted from the fabric instead. Therefore, it can only be indicated with a resistance value higher than the given one.

Judging from Table 2, it can be clearly seen that in the case where the weight per unit of the fabric in the loom area is close, the tear resistance in the warp direction and in the weave direction of the Kevlar vent duct fabric ® is coated much higher than normal fiberglass fabric and blended glass wool fabric.

Example 13:

Binding Resistance Test with Polyvinyl Chloride Paste Coating (standard test: HG / T 3052 (replacing 10.720 GB) 383-1995 in MT. Equivalent to ISO 2411)

After the fabric layer (Kevlar® fabric) in the ventilation duct is coated with polyvinyl chloride, the unvulcanized nitrile rubber [acrylonitrile 10 butadiene] adhesive is attached to the surface of the coating, then is vulcanized to 165 ° C. After that, a 25mm wide sample is cut from the vulcanized sample, and the liner between the fabric and the nitrile rubber is carefully cut along the width direction, then placed on the tensile tester. Instron®, with a rubber end bracket 15 and the other holding the fabric to break the bond. Polyvinyl chloride and nitrile rubber are very compatible, so in a normal case there is no break in the bond between the fabric and the polyvinyl chloride coating. The tensile tester will automatically record the bond break resistance generated, which is also the bond strength.

The following table test results are shown in Table 3 below.

Example 13.

Table 3

Example Bond Strength (N / 25 mm) Industry Standard (ΜΤ383-1995) Class I> 30 Class Il> 20 Example 13: Kevlar® Tissue A 54.5 Judging from Table 2 [sic; Table 3] above, the bond strength between Kevlar® fabric and polyvinyl chloride coating is higher than the standard for class I products as specified in the industry standard.

A detailed description of the present invention has been provided for

For the sake of clarity and understanding, but upon reading the description of the present application, the person skilled in the art will understand that, on the premise of not departing from the spirit and nature of the present invention, various modifications and alterations may be made. , these modifications and amendments fall within the range covered by the appended claims and their equivalent content.

Claims (10)

1. VENTILATION DUCK, which consists of: - a layer of fabric containing p-aromatic polyamide fiber, together with - a polymer layer or polymer blend coated on the inside and / or outside of the fabric layer described. VENTILATION Duct according to claim 1, characterized in that the described p-aromatic polyamide is selected from poly (p-phenylene terephthalate), poly (pfenylene terephthalate) copolymer, poly (p (benzamide), poly (p-benzamide) copolymer, polysulfonamide, polysulfonamide copolymer and mixtures thereof. VENTILATION Duct according to claim 1 or 2, characterized in that the polymer described includes: polyvinyl chloride, chlorinated polyvinyl chloride, chlorinated polyethylene, polychloroprene rubber, EPT rubber, butadiene rubber - acrylonitrile, natural rubber, styrene - butadiene rubber, epichlorohydrin rubber, chlorosulfonated polyethylene rubber, fluorine containing fluorine, silicone rubber, butyl rubber, halogenated butyl rubber, polyurethane, polyethylene, polypropylene, epoxy resin, resin phenol and mixtures thereof, with the described polymer mixture including the described polymer mixture with at least one of the substances selected from the following group: solvent, plasticizer, packaging agent, flame retardant, vulcanizing agents, age inhibiting agent vulcanization promoter, antioxidant, hardening agent, anti-oxidant; Anti-ultraviolet light stabilizing agent, antistatic agent, thixotropic, thermal stabilizing agent and lubricants. VENTILATION Duct according to claim 1, characterized in that at least in one direction of the warp; the fabric layer is composed of 100% p-aromatic polyamide fiber or yarn combination consisting of 5 to 100% paromatic polyamide fiber and 0 to 95% of other fibers, where the other fibers described include: fiberglass, polyester fiber, polyamide fiber, polyvinyl alcohol fiber, cotton fiber, vinyl fiber, rayon fiber, viscose fiber, elastane, polyvinyl chloride fiber, acrylic fiber, basalt fiber, aromatic polyamide fibers, polyester staple fiber, polyamide staple fibers, polyvinyl alcohol staple fibers, staple glass fibers, rayon staple fibers, vinylon staple fibers, elastane staple fibers, chloride staple staple fibers polyvinyl, acrylic staple fibers, and mixtures thereof. VENTILATION Duct according to claim 4, characterized in that 100% of the p-aromatic polyamide fibers or the combination of the yarns are twisted or non-twisted, the torsion coefficient of the polyamide p fiber 100% twisted aromatic or yarn combination described is 0 to 25, where the torsion coefficient is defined as follows: torsion coefficient = number of twists per meter x V denier number where denier number refers to weight per 9,000 meters of fiber, calculated in grams. VENTILATION Duct according to claim 1, characterized in that the tensile strength in the warp and weft direction of the described fabric layer is greater than 3,000 N / 50 mm. VENTILATION Duct according to Claim 1, characterized in that the bond strength between the fabric layer and the polymer or polymer blend layer described is greater than 20 N / 25 mm. APPLICATION, in the ventilation duct according to claim 1, to the locations of explosion or detonation. APPLICATION as described in claim 8, wherein the explosive or blasting site is a well or gallery. 10. APPLICATION of p-aromatic polyamide fiber in the ventilation duct.