CN102212332A - Non-asbestos fiber compound sealing material - Google Patents
Non-asbestos fiber compound sealing material Download PDFInfo
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- CN102212332A CN102212332A CN2011100861914A CN201110086191A CN102212332A CN 102212332 A CN102212332 A CN 102212332A CN 2011100861914 A CN2011100861914 A CN 2011100861914A CN 201110086191 A CN201110086191 A CN 201110086191A CN 102212332 A CN102212332 A CN 102212332A
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Abstract
The invention relates to a non-asbestos fiber compound sealing material, in particular to a high-performance paper-making method material, and belongs to the cross field of material science and paper-making technology. The non-asbestos fiber compound sealing material consists of non-asbestos fiber, rubber latex, mixed inorganic fillers and an auxiliary agent, wherein the mixed inorganic fillers are formed by the gradation of minimum two types, at most six types of fillers of different average grain sizes, and the average grain size of the bigger fillers is more than 2.5 times that of the adjacent smaller fillers. Because the closest packing theory is adopted in the invention and the fillers are formed by the gradation of the fillers of different average grain sizes, the close packing microporous material structure can be obtained while less rubber latex is consumed, various important indexes, such as the sealing property, mechanical strength and heat resistance, of the product are greatly improved, and the high-performance non-asbestos fiber compound sealing material is obtained. By the gradation of the fillers, the paper machine paper-making property of the pulp is improved.
Description
Technical field
The invention belongs to the crossing domain of Materials science and paper-making technique, relate to a kind of no fibrous magnesium silicate composite seal, especially the high-performance paper process does not have the fibrous magnesium silicate composite seal.
Background technology
The fiber composite sealing material is mainly used in makes various gasket seals, be widely used in the sealing of various vehicles, mechanical means and various pipes junction, use properties and the environmental health in the Industrial processes and the operational safety of vehicle, machinery played critical effect.The fibrous encapsulation material has fibrous magnesium silicate product and no fibrous magnesium silicate product two big classes.Fibrous magnesium silicate is inexpensive, once is the only selection of making the used fiber of sealing material.But, the carcinogenesis of fibrous magnesium silicate, the hazardness of HUMAN HEALTH progressively extensively is familiar with by people along with the reach of science.So the use of asbestos is under an embargo in the flourishing country of industry.In China, owing to the difference of stage of economic development, also owing to the backwardness in the no asbestos product technical development, asbestos product is also widely used at present on the one hand.Also do not become a kind of process and development trend but there are asbestosization, the shared ratio of no asbestos product improves rapidly year by year.
The manufacture method of fiber composite sealing material mainly contains two kinds of roll-in method and paper process.The product of roll-in method can reach higher density, so section sealing property (Bulk Sealability) height.But because of adopting benzene, organic solvents such as toluene and gasoline are dispersion medium, and the high and with serious pollution defective of cost is arranged.And paper process to make water be dispersion medium, the low and free of contamination advantage of cost is arranged, be the environmentally friendly mode of production.But the product of paper process can't reach very high density because of the characteristic of its technological process, so the stopping property of material, mainly is the level that the section sealing property is difficult to reach the roll-in method product, makes its range of application be subjected to very big restriction.
The main effect of fiber composite sealing material in application process is exactly the sealing of guarantee system.Yet because the porous characteristics of sealing material itself, absolute zero is leaked and is difficult to guarantee.The leakage form of sealing material mainly contains two kinds: (Interfacial Leakage) revealed at the interface and (Bulk Leakage) revealed in the section infiltration.The characteristic with material itself is revealed not only in its median surface, and is relevant as soft adaptability, compression resilience, creep relaxation etc., and also with the working accuracy on metal flange surface, the combined effect of the preliminary tension of bolt and applied environment generation is relevant.The paper process product is good because of soft adaptability, the rate of compression height, so interfacial seal performance (Interfacial Sealability) is generally good than roll-in method product, promptly its interface is revealed lower than roll-in method product usually.And section infiltration leakage is main relevant with the voidage and the micro-pore diameter in sealing material transverse section, therefore is also referred to as the micropore seepage.Can characterize the size of micropore seepage in theory by the infiltration rate Q/A of unit surface in the Darcy equation (1).
In the formula: K is for characterizing the coefficient of sealing material penetrating quality, and Δ P is the pressure difference of pressure medium and ambient pressure; η is the viscosity of sealed medium, and l is the width of sealing material annulus, i.e. the running length of medium seepage.
The porous substrate that forms for piling up by filler particles, as no fibrous magnesium silicate composite seal involved in the present invention, its penetrating quality K can approximately be characterized by Kozeny-Carman equation (2):
In the formula: φ is the voidage of porous material inside, d
EffBe the effective diameter of the spheroidal particle that forms porous material, κ is constant (being generally 5).
From equation (1) and (2) as can be seen, under certain medium and pressure medium, fluid medium sees through the infiltration rate in sealing material transverse section mainly by the voidage of material internal and the size decision of filler effective diameter.Infiltration rate and material void rate cube and square being directly proportional of particle effective diameter.Therefore reveal for the infiltration that reduces porous material, promptly improve the section sealing property of fiber composite sealing material, must reduce the voidage and the particulate effective diameter of material internal structure simultaneously effectively.
The voidage and the particulate effective diameter that reduce the fibrous encapsulation material have three kinds of technological approaches usually.The first improves the tightness of material.For roll-in method, this is easily to realize; And paper process is subjected to the restriction of processing method, reach higher tightness (as>1.5g/cm
3) technologic difficulty arranged.And no matter be the product of roll-in method or paper process, when the tightness of material is too high, though its section sealing property continues to improve, but because of its flexibility and compressibility descend thereupon, cause reducing with the adaptability (conformability) of flange interfaces, therefore the interfacial seal of material can descend, so the comprehensive sealing performance of material may not improve.Certainly, this approach has also increased the cost of product simultaneously.
It two is the fillers that use low particle diameter in the prescription of fiber composite sealing material.Though but this approach can reduce d effectively
Eff, but can't reduce the voidage of material.Because can prove by mathematical computations, isometrical rigid spheres reaches formed material structure behind the closestpacking, and the diameter of its voidage and spheroid is irrelevant.Therefore according to equation (2), the simple use hanged down the sealing property that the particle diameter filler can not improve the fiber composite sealing material extremely effectively.On the other hand, because the particle diameter of filler is more little, specific surface area is big more, and its flow resistance is also big more.Therefore when in the prescription at material too much during the filler of the very low particle diameter of use, will the water filtering performance of slurry and the retention of filler sharply be descended, cause the slurry can't be in the moulding of wire-cloths drainage.Though in roll-in method production, do not have this problem, concerning the paper process production process, then can have a strong impact on the normal operation of paper machine.Therefore in the fibrous encapsulation material prescription of paper process, the median size of filler all is not less than 2 microns usually, and the effective diameter that can't further reduce filler by the filler that uses lower particle diameter improves its section sealing property.This is that paper process product section sealing property is usually than another reason of roll-in method product difference.
Another technological approaches that reduces fiber composite sealing material voidage is the latex content that improves in the material prescription.Though this method can improve the sealing property of material effectively, but it not only can increase the cost of material, and can damage the ultimate compression strength and the creep-resistant property of material, sealing material is easy to because of conquassation (crush failure) causes leaking, or causes the bolt pretightening seal failure that descends because of the creep relaxation transition.Too high latex content also can reduce the resistance to elevated temperatures of matrix material simultaneously.
This shows, how to improve the over-all properties of material all sidedly, comprise sealing property, tensile strength, creep-resistant property and resistance to elevated temperatures, be a significant challenge in no the fibrous magnesium silicate composite seal manufacturing technology, particularly paper process manufacturing technology always.For improving the over-all properties of paper process fiber composite sealing material, enlarge its range of application, key problem in technology wherein is when satisfying the paper process manufacturing technique requirent, realizes material structure closely by using the least possible latex.Break through this key problem in technology emphasis point of the present invention just.
Summary of the invention
To hang down the relatively poor shortcoming of over-all properties, particularly sealing property that the particle diameter filler causes material in order overcoming in the present paper process fibrous encapsulation material manufacturing technology because of using, to the present invention proposes a kind of manufacturing technology of not having the fibrous magnesium silicate composite seal.
The present invention uses the closestpacking principle, optimize the particle packing of mineral filler in the paper process fiber composite sealing material by the grating of 2~6 kinds of different median size fillers, thereby form the material microvoid structure of " closestpacking " (closest packing), voidage and particulate effective diameter in the sealing material structure are all reduced greatly.Can promptly form fine and close high leakproofness material structure, thereby make other key property of material also obtain very big improvement by using organic latex of low amount thus.
If the mineral filler of certain particle diameter is regarded as rigid spheres approx, as shown in Figure 1, for same diameter sphere a, when reaching closestpacking, according to the difference of the arrangement mode of spheroid, mathematical computations can prove that the voidage of formed accumulation body changes between 26% to 48%.The diameter of voidage and spheroid itself is irrelevant.But when the spheroid that uses different diameter carries out closestpacking, in the space that big ball a forms, can add the less diameter sphere b of some amount, and the voidage of accumulation body and micro-pore diameter are all significantly descended.For example when the hexagon mode that with ligancy is 8 was piled up, the voidage after isometrical spheroid is piled up was 38%, and after adding the less spheroid of second stage diameter, the voidage of accumulation body is reduced to 14.4% rapidly.Calculate according to background mathematics, have only diameter as spheroid a be spheroid b diameter more than 2.4 times the time, spheroid b could the space of completely filled between spheroid a in.Be voidage and the micro-pore diameter that further reduces accumulation body, can also add the littler spheroid c of diameter and be filled in the space that produces between spheroid a and the spheroid b.The rest may be inferred, along with the adding of next stage minor diameter spheroid, and the sustainable reduction of the voidage of accumulation body and micro-pore diameter (and effective diameter of filler), just the amplitude that reduces is slowed down along with the increase of progression, there is no need usually to reach more than 5~6 grades.So when realizing closestpacking by grating, can make the voidage of accumulation body and micropore size drop to very low with the spheroid of 2~6 kinds of different diameters.Still be that 8 hexagon accumulation mode is an example with above-mentioned ligancy, when the progression of grating continues to raise when being 3 grades, 4 grades and 5 grades, the voidage of accumulation body is reduced to 5.4%, 2.% and 0.8% respectively.Meanwhile, the particulate effective diameter of formation porousness accumulation body also descends along with the increase of grating progression.
The present invention utilizes the grain composition principle in the closestpacking theory, do not have in paper process and to use in the prescription of fibrous magnesium silicate composite seal by minimum 2 kinds, the mixing mineral filler that the filler grating of maximum 6 kinds of different median sizes forms, the median size of wherein big one-level filler is more than 2.4 times of median size that are adjacent time one-level filler, and the weight ratio of second stage filler and maximum level filler is not less than 7%.Can make like this and mix the microvoid structure that forms " closestpacking (closest packing) " in the fiber composite sealing material of mineral filler after moulding, thereby reduce the voidage φ and the particulate effective diameter d of material in the equation (2) effectively
Eff, and then improve the sealing property of material greatly.Simultaneously because material structure is by tightly packed the forming between the filler particles of different-grain diameter closely, rather than the method by latex content in the conventional pure increase prescription, ultimate compression strength, creep resistance and the over-all properties such as high temperature resistant of material also are significantly improved, obtain high performance no fibrous magnesium silicate composite seal thus.The result of grating makes minimum level filler shared ratio in the filler total amount not be higher than 15%, has therefore also kept slurry at web part of paper machine good water filtering performance and filler retention, and machine operation can normally be carried out.
The present invention proposes a kind of no fibrous magnesium silicate composite seal, it is characterized in that: described no fibrous magnesium silicate composite seal is made up of by following proportioning following each component:
Wherein, described mixing mineral filler is by minimum 2 kinds, and the filler grating of maximum 6 kinds of different median sizes forms, and the median size of big one-level filler is more than 2.4 times of median size that are adjacent time one-level filler; Mix maximum level filler in the mineral filler and be median size 2~20 microns common fillers, the minimum level filler is a median size at 0.1~0.5 micron ultra tiny filler.
Feature of the present invention also comprises:
The weight percent of described maximum level filler in described mixing mineral filler is 40%~90%.
The weight ratio of particle diameter second stage filler and maximum level filler is not less than 7% in the described mixing mineral filler.
In the filler component in the described mixing mineral filler more than the particle diameter third stage and the third stage, the weight ratio that inferior one-level filler is adjacent big one-level filler is not less than 20%.
Having one-level in the described mixing mineral filler at least is the ultra tiny filler of median size less than 0.5 μ m.
Mixing mineral filler of the present invention is formed by one or more gratings in lime carbonate, talcum powder, kaolin, wollastonite, sepiolite, wilkinite, mica and the attapulgite etc.; The filler of grating has 2 kinds to 6 kinds different particle size range.Described non-asbestos fiber is one or more the mixture in vegetable fibre, aramid fiber, acrylic fiber, polysulphonamide fiber, phenolic fibre, carbon fiber, glass fibre, sepiolite fibre, the aluminium silicate fiber peacekeeping ceramic fiber etc.Described vulcanization system comprises vulcanizing agent, promotor and promoting agent; Wherein vulcanizing agent is a sulphur; Promotor is thiazoles, phosphorodithioic acid salt and thiurams; Promoting agent is zinc oxide or stearic acid.Described anti-aging agent is a styrenated diphenylamine, right, right-the diisopropylbenzyl pentanoic, 2-thiol group tolimidazole or 2,6 ditertiary butyl p cresol.Described pigment is carbon black or ferric oxide etc.Described dyestuff is an organic dye.Described latex is one or more in acrylic latex, nitrile rubber, styrene-butadiene latex, carboxylic acrylonitrile butadiene rubber latex, carboxylic styrene butadiene latex, polychloroprene latex or the natural rubber latex.
The closestpacking principle that the present invention calculates according to background mathematics and material structure is learned, adopt the filler of a certain proportion of different-grain diameter scope to mix use by grating, wherein maximum level is a median size 2~20 microns common fillers, minimum level is a median size at 0.1~0.5 micron ultra tiny filler, make it in product structure, form the microvoid structure of closestpacking, reduced simultaneously voidage and the particulate effective diameter in the material structure effectively, the sealing property of product is improved greatly, also significantly improved other over-all properties of material.Simultaneously, also kept slurry, the paper machine operation can normally be carried out at web part of paper machine good water filtering performance and filler retention because fine filler shared ratio in the filler total amount is little.
Description of drawings
To be the reducing spheroid reach structure section synoptic diagram behind the closestpacking with cubical arrangement mode to Fig. 1.
Embodiment
Embodiment 1: the weight ratio of each component is in the no fibrous magnesium silicate composite seal prescription:
Wherein mix mineral filler by 65% 1
#Lime carbonate, 25% 2
#Lime carbonate and 10% 3
#The lime carbonate grating forms.The median size of used each filler of grating sees Table 1.
Table 1
The filler numbering | 1 #Lime carbonate | 2 #Lime carbonate | 3 #Lime carbonate |
Median size/micron | 3.98 | 1.64 | 0.48 |
According to above proportioning raw materials, with the prescription and the single filler of employing (the sample 2:100%1 of invention example 1
#Pearl filler; Sample 3:100%3
#Pearl filler) same recipe is carried out paper process respectively and is copied the sheet test.The performance comparison of three sealing material samples is as shown in table 2.
Table 2
As can be seen from Table 2, compare with the sample 2 that adopts 100% ordinary calcium carbonate filler, adopt grating to mix the sample of the invention example 1 of mineral filler, its drainage time is influenced little, sealing property then improves greatly, and tensile strength also is significantly improved simultaneously.
Embodiment 2: the weight ratio of each component is in the no fibrous magnesium silicate composite seal prescription:
Wherein mix mineral filler by 50% 1
#Talcum powder, 30% 2
#Talcum powder, 14% 1
#Kaolin and 6% 2
#The kaolin grating forms.The median size of used each filler of grating sees Table 3.
Table 3
Numbering | 1 #Talcum powder | 2 #Talcum powder | 1 #Kaolin | 2 #Kaolin |
Median size/micron | 8.01 | 3.22 | 1.23 | 0.31 |
According to above proportioning raw materials, with the prescription and the single filler of employing (the sample 5:100%1 of invention example 2
#Talcum powder; Sample 6:100%2
#The kaolin filler) same recipe is carried out paper process respectively and is copied the sheet test.The performance comparison of three sealing material samples is as shown in table 4.
Table 4
As can be seen from Table 4, with employing 100%1
#The sample 5 of talcum powder is compared, and adopts grating to mix the sample of the invention example 2 of mineral filler, and its drainage time is influenced little, and sealing property then improves nearly 10 times, simultaneously tensile strength also be improved significantly.
Embodiment 3: the weight ratio of each component is in the no fibrous magnesium silicate composite seal prescription:
Wherein mix mineral filler by 45% 1
#Talcum powder, 28% 2
#Talcum powder, 17% 1
#Kaolin and 10% 3
#The lime carbonate grating forms.The median size of used each filler of grating sees Table 5.
Table 5
According to above proportioning raw materials, with the prescription and the single filler of employing (the sample 8:100%2 of invention example 3
#Talcum powder; Sample 9:100%3
#Pearl filler) same recipe is carried out paper process respectively and is copied the sheet test.The performance comparison of three sealing material samples is as shown in table 6.
Table 6
As can be seen from Table 6, with employing 100%2
#The sample 8 of talcum powder is compared, and it is close to adopt grating to mix the sample drainage rate of invention example 3 of mineral filler, and sealing property increases substantially, simultaneously tensile strength also be improved significantly.
Claims (9)
1. no fibrous magnesium silicate composite seal, it is characterized in that: described no fibrous magnesium silicate composite seal contains:
Wherein, described mixing mineral filler is by minimum 2 kinds, and the filler grating of maximum 6 kinds of different median sizes forms, and the median size of big one-level filler is more than 2.4 times of median size that are adjacent time one-level filler; What mix maximum level in the mineral filler is median size 2~20 microns common fillers, minimum level be median size at 0.1~0.5 micron ultra tiny filler.
2. mixing mineral filler according to claim 1 is characterized in that: the weight percent of described maximum level filler in described mixing mineral filler is 40%~90%.
3. mixing mineral filler according to claim 1 is characterized in that: the weight ratio of particle diameter second stage filler and maximum level filler is not less than 7% in the described mixing mineral filler.
4. mixing mineral filler according to claim 1 is characterized in that: in the filler component in the described mixing mineral filler more than the particle diameter third stage and the third stage, the weight ratio that inferior one-level filler is adjacent big one-level filler is not less than 20%.
5. mixing mineral filler according to claim 1 is characterized in that: having one-level in the described mixing mineral filler at least is the ultra tiny filler of median size less than 0.5 μ m.
6. mixing mineral filler according to claim 1 is characterized in that: described mixing mineral filler is formed by one or more gratings in lime carbonate, talcum powder, kaolin, wollastonite, sepiolite, wilkinite, mica and the attapulgite etc.; The filler of grating has 2 kinds to 6 kinds different particle size range.
7. fiber according to claim 1 is characterized in that: described non-asbestos fiber is made up of in vegetable fibre, aramid fiber, acrylic fiber, polysulphonamide fiber, phenolic fibre, carbon fiber, glass fibre, sepiolite fibre, the aluminium silicate fiber peacekeeping ceramic fiber etc. one or more.
8. auxiliary addition agent according to claim 1 is characterized in that: said auxiliary addition agent is vulcanization system, anti-aging agent, pigment and dyestuff etc.; Wherein vulcanizing agent is a sulphur; Promotor is thiazoles, phosphorodithioic acid salt and thiurams; Promoting agent is zinc oxide or stearic acid; Described anti-aging agent is a styrenated diphenylamine, right, right-the diisopropylbenzyl pentanoic, 2-thiol group tolimidazole or 2,6 ditertiary butyl p cresol; Described pigment is carbon black or ferric oxide etc.; Described dyestuff is an organic dye.
9. latex according to claim 1 is characterized in that: described latex is one or more in acrylic latex, nitrile rubber, styrene-butadiene latex, carboxylic acrylonitrile butadiene rubber latex, carboxylic styrene butadiene latex, polychloroprene latex or the natural rubber latex.
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Cited By (7)
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CN102583994A (en) * | 2012-01-18 | 2012-07-18 | 大连环球矿产有限公司 | Composite mineral fiber and preparation method thereof |
CN104262711A (en) * | 2014-10-11 | 2015-01-07 | 成都俊马密封制品有限公司 | Cationic particle high-performance seal material |
CN105802218A (en) * | 2016-04-28 | 2016-07-27 | 苏州科迪流体控制设备有限公司 | High temperature resistant material for sealing valve |
CN106146933A (en) * | 2015-04-23 | 2016-11-23 | 中国制浆造纸研究院 | Wet moulding has the method for encapsulant without asbestos fibre of high strength |
CN106633199A (en) * | 2016-12-21 | 2017-05-10 | 齐齐哈尔大学 | Material for sealing ring with fabric |
CN109384980A (en) * | 2018-10-30 | 2019-02-26 | 江苏赛尔密封科技有限公司 | A kind of flame-resistant sealing material and preparation method thereof |
CN109778591A (en) * | 2019-01-11 | 2019-05-21 | 浙江理工大学 | A kind of hydrophilic flexibility graphite composite seal preparation method |
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《机械工程材料》 20051231 刘美红,黎振华,蔡仁良 "无石棉胶乳抄取密封材料的悬浮液稳定性研究" 第7页右栏和第9页表3配方6 1-9 第29卷, 第12期 * |
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Cited By (11)
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CN102583994A (en) * | 2012-01-18 | 2012-07-18 | 大连环球矿产有限公司 | Composite mineral fiber and preparation method thereof |
CN102583994B (en) * | 2012-01-18 | 2014-07-23 | 大连环球矿产有限公司 | Composite mineral fiber and preparation method thereof |
CN104262711A (en) * | 2014-10-11 | 2015-01-07 | 成都俊马密封制品有限公司 | Cationic particle high-performance seal material |
CN104262711B (en) * | 2014-10-11 | 2016-06-08 | 成都俊马密封制品有限公司 | A kind of cationic microparticles high-performance sealed material |
CN106146933A (en) * | 2015-04-23 | 2016-11-23 | 中国制浆造纸研究院 | Wet moulding has the method for encapsulant without asbestos fibre of high strength |
CN105802218A (en) * | 2016-04-28 | 2016-07-27 | 苏州科迪流体控制设备有限公司 | High temperature resistant material for sealing valve |
CN105802218B (en) * | 2016-04-28 | 2019-01-18 | 苏州科迪流体控制设备有限公司 | A kind of heat-resisting material for valve seal |
CN106633199A (en) * | 2016-12-21 | 2017-05-10 | 齐齐哈尔大学 | Material for sealing ring with fabric |
CN109384980A (en) * | 2018-10-30 | 2019-02-26 | 江苏赛尔密封科技有限公司 | A kind of flame-resistant sealing material and preparation method thereof |
CN109778591A (en) * | 2019-01-11 | 2019-05-21 | 浙江理工大学 | A kind of hydrophilic flexibility graphite composite seal preparation method |
CN109778591B (en) * | 2019-01-11 | 2021-07-09 | 浙江理工大学 | Preparation method of hydrophilic flexible graphite composite sealing material |
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