CN111704361A - High-refractive-index high-performance glass fiber composition, glass fiber and composite material thereof - Google Patents

High-refractive-index high-performance glass fiber composition, glass fiber and composite material thereof Download PDF

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CN111704361A
CN111704361A CN202010510732.0A CN202010510732A CN111704361A CN 111704361 A CN111704361 A CN 111704361A CN 202010510732 A CN202010510732 A CN 202010510732A CN 111704361 A CN111704361 A CN 111704361A
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glass fiber
index
refractive
refractive index
glass
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CN111704361B (en
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韩利雄
姚远
曾庆文
谭家顶
宋凡
苟习颖
彭珂
徐强
王艺
高冰心
许诗勇
黄浪
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Chongqing Xuan Billion New Mstar Technology Ltd
Chongqing Polycomp International Corp
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Chongqing Polycomp International Corp
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    • CCHEMISTRY; METALLURGY
    • C03GLASS; MINERAL OR SLAG WOOL
    • C03CCHEMICAL COMPOSITION OF GLASSES, GLAZES OR VITREOUS ENAMELS; SURFACE TREATMENT OF GLASS; SURFACE TREATMENT OF FIBRES OR FILAMENTS MADE FROM GLASS, MINERALS OR SLAGS; JOINING GLASS TO GLASS OR OTHER MATERIALS
    • C03C13/00Fibre or filament compositions
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    • C08ORGANIC MACROMOLECULAR COMPOUNDS; THEIR PREPARATION OR CHEMICAL WORKING-UP; COMPOSITIONS BASED THEREON
    • C08JWORKING-UP; GENERAL PROCESSES OF COMPOUNDING; AFTER-TREATMENT NOT COVERED BY SUBCLASSES C08B, C08C, C08F, C08G or C08H
    • C08J5/00Manufacture of articles or shaped materials containing macromolecular substances
    • C08J5/04Reinforcing macromolecular compounds with loose or coherent fibrous material
    • C08J5/0405Reinforcing macromolecular compounds with loose or coherent fibrous material with inorganic fibres
    • C08J5/043Reinforcing macromolecular compounds with loose or coherent fibrous material with inorganic fibres with glass fibres
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    • C08ORGANIC MACROMOLECULAR COMPOUNDS; THEIR PREPARATION OR CHEMICAL WORKING-UP; COMPOSITIONS BASED THEREON
    • C08JWORKING-UP; GENERAL PROCESSES OF COMPOUNDING; AFTER-TREATMENT NOT COVERED BY SUBCLASSES C08B, C08C, C08F, C08G or C08H
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    • C08ORGANIC MACROMOLECULAR COMPOUNDS; THEIR PREPARATION OR CHEMICAL WORKING-UP; COMPOSITIONS BASED THEREON
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    • C08J2377/00Characterised by the use of polyamides obtained by reactions forming a carboxylic amide link in the main chain; Derivatives of such polymers
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    • C08ORGANIC MACROMOLECULAR COMPOUNDS; THEIR PREPARATION OR CHEMICAL WORKING-UP; COMPOSITIONS BASED THEREON
    • C08KUse of inorganic or non-macromolecular organic substances as compounding ingredients
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Abstract

The high-refractive-index high-performance glass fiber composition, the glass fiber and the composite material comprise 55.2 to 59.2 weight percent of SiO2(ii) a 11.6-15.6 wt% of Al2O3(ii) a 21.5-23.3 wt% CaO; 0-0.5 wt% MgO; 3.5-5.9% of Y2O3+Bi2O3+ BaO; 3.5-4.9 wt% of Y2O3(ii) a 0.1-0.9 wt% of Bi2O30.1 to 1.5 wt% BaO; 0-0.4 wt% TiO2(ii) a 0-0.3 wt% Fe2O3;Li2O、Na2O and K2The sum of the mass percent of O is 0.3-1.5 wt%. The refractive index of the high-refractive-index high-performance glass fiber is 1.580-1.590, the high-refractive-index high-performance glass fiber has good matching property with the refractive index of polycarbonate resin, and the color is lighter; the high-refractive-index high-performance glass fiber impregnated yarn has tensile strength of more than 2600MPa, tensile modulus of more than 87GPa and good dimensional stability. The forming temperature of the high-refractive-index high-performance glass fiber is not more than 1210 ℃, and the upper limit temperature of crystallization is not more than 1150 ℃.

Description

High-refractive-index high-performance glass fiber composition, glass fiber and composite material thereof
Technical Field
The invention belongs to the technical field of modification of high polymer materials, and particularly relates to a high-refractive-index high-performance glass fiber composition, and glass fibers and a composite material thereof.
Background
The glass fiber is an inorganic non-metallic material with excellent performance, has the advantages of high tensile strength, high strength, good temperature resistance and corrosion resistance, heat insulation, sound insulation, non-combustion and the like, and is widely applied to various fields of electronics, electricity, automobiles, aviation, ships, environmental protection, chemical engineering, buildings and the like.
Polycarbonate (PC) is used as a thermoplastic resin, has good transparency, no toxicity, weather resistance, heat resistance, impact resistance, fatigue resistance and electrical performance, is a universal engineering plastic with the highest growth speed among the use frequencies of five engineering plastics, and is widely applied to the fields of office equipment such as glass assembly industry, automobile industry, electronics, electrical appliance industry, industrial mechanical parts, optical disks, packaging, computers and the like, medical treatment and health care, films, leisure and protective equipment and the like. With the further expansion of the application range of PC resin, in order to compensate the defect of insufficient mechanical strength, glass fiber is used to enhance the mechanical property and dimensional stability of PC resin. However, the refractive index of PC resin is higher, usually greater than 1.58, while the refractive index of ordinary glass fiber is usually 1.54-1.56, which are different from each other, if ordinary glass fiber is directly added, the light transmission of the product is reduced, and the light transmission of the product is reduced more obviously with the increase of the content of ordinary glass fiber.
In the development process of alkali-free glass fiber, the improvement of the mechanical properties of the glass fiber is considered, and the research on the improvement of the refractive index and the transparency of the glass fiber is not much.
Japanese patent laid-open No. Hei 5-155638 discloses a glass fiber composition for reinforcing polycarbonate resin, which comprises (by weight): SiO 2254-62%,Al2O38-12%,CaO 18-22%,TiO20.5-1.9%,MgO 0-5%,ZnO 0-5%,BaO 0-5%,ZrO20.6-5%,Li2O+Na2O+K2O0-1%, the refractive index of the glass fiber is 1.5700-1.6000, and 0.5-1.9% TiO is added2Although the refractive index of the glass fiber can be increased, TiO is used as the refractive index2The content of more than 0.5 percent can cause the glass fiber product to have light yellow and low transparency.
Chinese patent CN200580015038.5 discloses a glass fiber for reinforcing polycarbonate resin, which comprises B2O3And no B2O3Two types. Wherein contains B2O3The glass fiber component comprises (by weight percent)Ratio): SiO 2250-60%,Al2O310-15%,CaO 15-25%,TiO22-10%,B2O32-8%,MgO 0-5%,ZnO 0-5%,BaO 0-5%,ZrO20-5%,Li2O+Na2O+K2O0-2%, and the refractive index of the glass fiber is 1.580-1.590. Does not contain B2O3The glass fiber component comprises (by weight percent): SiO 2250-60%,Al2O310-15%,CaO 15-25%,TiO24.1-5%,MgO 0-5%,ZnO 0-5%,BaO 0-5%,ZrO20-5%,Li2O+Na2O+K2O 0-2%,ZnO+Y2O31-5%,TiO2+ZnO+BaO+ZrO26-8%, the refractive index of the glass fiber is 1.583-1.586, but TiO2The content is obviously higher, so that the glass fiber product is bright yellow and the transparency is seriously influenced.
Chinese patent CN200910002941.8 discloses a similar glass fiber for reinforcing polycarbonate resin, which comprises the following main components (by weight percent): SiO 2250-60%,Al2O310-15%,CaO 15-25%,TiO23-5%,MgO0-5%,ZnO 0-5%,BaO 0-5%,ZrO20-5%,Li2O+Na2O+K2O 0-2%,ZrO22-5%, the refractive index of the glass fiber can reach 1.583-1.586, although the refractive index of the glass fiber can be improved, the use amount of TiO2 is large, so that the color of the glass product is obviously yellow, the production difficulty is large, and the application range of the glass product is limited.
Disclosure of Invention
The invention provides a high-refractive-index high-performance glass fiber composition, a glass fiber and a composite material thereof, which have the advantages of high refractive index, excellent mechanical property and very good light transmittance, and can be widely applied to the field with high requirements on mechanical property and transparency.
The technical scheme of the invention is as follows:
the high-refractive-index high-performance glass fiber composition comprises the following components in percentage by mass:
Figure BDA0002528301770000021
wherein, Y is2O3The mass percentage of the TiO is 3.5-4.9wt percent2、Na2O、K2O is introduced as an impurity, not separately added, and the Li2O、Na2O、K2The sum of the mass percent of O is not more than 1.5 wt%.
Preferably, Y is2O3、Bi2O3The sum of the mass percent of BaO is 3.5-5.9wt percent, wherein the Bi is2O3The mass percentage of the BaO is 0.1-0.9 wt%, wherein the mass percentage of the BaO is 0.1-1.5 wt%.
Preferably, the TiO is introduced as an impurity2The mass percentage of the components is controlled to be 0-0.4 wt%.
Preferably, the Fe2O3The mass percentage of the components is controlled to be 0-0.3 wt%.
Preferably, the Li2O、Na2O、K2The mass percentage of O is controlled to be 0.3-1.5 wt%
Preferably, the SiO2The mass percentage of the components is controlled to be 55.2-59.2 wt%.
Preferably, the Al is2O3The mass percentage of the components is controlled to be 11.6-15.6wt percent,
preferably, the weight percentage of CaO is controlled to be 21.5-23.3 wt%.
Preferably, the MgO content is controlled to 0-0.5 wt%.
The content of each component of the high-refractive-index high-performance glass fiber composition is preferably as follows in percentage by mass:
Figure BDA0002528301770000031
wherein, Y is2O3Is 3.5 to 4.9 weight percent, and the Bi2O3The mass percentage of the BaO is 0.1-0.9 wt%, wherein the mass percentage of the BaO is 0.1-1.5 wt%.
The high-refractive-index high-performance glass fiber is prepared from the high-refractive-index high-performance glass fiber composition, and the refractive index of the high-refractive-index high-performance glass fiber is 1.580-1.590.
A high-refractive-index high-performance glass fiber reinforced composite material comprises the high-refractive-index high-performance glass fiber.
In the present invention, Silica (SiO)2) Is one of the main oxides forming the network structure of the glass, and mainly plays a role in improving the mechanical strength, chemical stability and thermal stability of the glass. In a certain range, SiO in glass2The higher the content, the better the mechanical strength of the glass, but the higher the melting temperature and fiber forming temperature of the glass, the greater the production difficulty. Taken together, the SiO of the present invention2The mass percentage content is 55-60 wt%, preferably 55.2-59.2 wt%.
In the present invention, alumina (Al)2O3) With SiO2The glass and the Al jointly form a glass network structure, the higher the content of the glass is, the more excellent the mechanical strength, particularly the elastic modulus of the glass is, but the high-temperature viscosity of the glass is obviously increased, and the Al generally2O3When the content exceeds 16%, the viscosity of the glass becomes too high, the glass is difficult to be formed into fibers, and the problem of devitrification is liable to occur. Thus, Al according to the invention2O3The content is 10 to 16 wt%, preferably 11.6 to 15.6 wt%.
In the invention, calcium oxide (CaO) and magnesium oxide (MgO) both belong to alkaline earth metal oxides and have the functions of adjusting the high-temperature viscosity of the glass and improving the crystallization tendency of the glass, but the atomic weight and the ionic radius of Ca are larger relative to Mg and Ca, so that the effect of improving the refractive index of the glass is more obvious. Meanwhile, in the alkali-free glass system, the total content of CaO and MgO is generally not more than 25%, preferably less than 24%. The invention is preferably to add CaO selectively in order to guarantee a higher refractive index, MgO is generally not added specifically, but the invention allows the introduction of a small amount of MgO in the form of impurities of mineral raw materials in view of the cost of the mineral raw materials. Experiments prove that the comprehensive effect is best when the CaO content is controlled to be 20-24 wt% and the MgO content is controlled to be 0-1.5 wt%. The preferable mass percentage of CaO is 21.5-23.3 wt%, and the preferable mass percentage of MgO is 0-0.5 wt%.
The glass fiber of the invention is specially added with yttrium oxide (Y)2O3) May further contain Bi2O3And BaO. Y is2O3、Bi2O3BaO and BaO both belong to elements with larger atomic radius and atomic mass, and have the effects of reducing the high-temperature viscosity of the glass and improving the refractive index of the glass in the glass. It has also been found that when one of the substances is added alone, Y2O3The effect is obviously better than that of Bi2O3And BaO; when two or three substances are added simultaneously, a synergistic effect can be generated, the adjustment range of the refractive index is optimized, the crystallization tendency is reduced, and the difficulty of wire drawing operation is improved. Y in the glass fiber of the present invention2O3+Bi2O3The BaO mass percentage content is 3.1-6.9%; preferably 3.5 to 5.9 wt%. Among them, more preferred among the glass fibers of the present invention, Y2O33.5 to 4.9 weight percent of Bi2O3The mass percentage content is 0.1-0.9 wt%, and the mass percentage content of BaO is 0.1-1.5 wt%.
In glass, titanium dioxide (TiO)2) The effect of improving the refractive index is very obvious, and a plurality of glasses with higher refractive index contain higher TiO2But at the same time TiO2There is also a pronounced coloring effect, with the glass appearing yellowish when its content exceeds 0.5% by weight and already appearing very distinctly bright yellow when its content exceeds 1% by weight. Therefore, the present invention does not substantially contain TiO2However, to reduce the cost of the raw material, the present invention allows the introduction of small amounts of TiO in the form of impurities in the mineral raw material2. To avoid impurity TiO2Effect on glass color, TiO in the glass fibers of the invention2The mass percentage content is limited to 0-1 wt.%, preferably 0-0.4 wt.%.
In the glass fiber, a small amount of Fe2O3The performance is not greatly affected, but if the content is higher, the glass is yellowed or greened. Typically to reduce the cost of the mineral feedstock, small amounts of incorporation are generally permitted. In the present invention, Fe2O3It is introduced mainly as a mineral raw material impurity without special addition. However, in order to control the color of the glass, Fe is contained in the glass fiber of the present invention2O3The mass percentage content is limited to 0-0.6 wt.%, preferably 0-0.3 wt.%.
In order to reduce the melting temperature of the glass fiber and improve the fiber forming difficulty, a small amount of Li can be added into the glass fiber2O, the mass percent content of which is 0-1 wt%. The glass fiber of the present invention also contains a small amount of alkali metal oxide Na2O and K2O, which also helps to reduce the difficulty of glass fiber production. Na in the glass composition of the invention2O and K2The total content of O is controlled between 0 and 0.8 weight percent. Meanwhile, the Li2O、Na2O and K2The sum of the O contents by mass is preferably 0.3 to 1.5 wt%.
In the present invention, a preferred embodiment of the glass fiber is: 55.2-59.2 wt% SiO2(ii) a 11.6-15.6 wt% of Al2O3(ii) a 21.5-23.3 wt% CaO; 0-0.5 wt% MgO; 3.5-5.9% of Y2O3+Bi2O3+ BaO; 3.5-4.9 wt% of Y2O3(ii) a 0.1-0.9 wt% of Bi2O30.1 to 1.5 wt% BaO; 0-0.4 wt% TiO2(ii) a 0-0.3 wt% Fe2O3
Li2O、Na2O and K2The sum of the mass percent of O is 0.3-1.5 wt%. The refractive index of the glass fiber is 1.580-1.590, the glass fiber has good matching property with the refractive index of polycarbonate resin, and the color is lighter; the glass fiber impregnated yarn has tensile strength of more than 2600MPa, tensile modulus of more than 87GPa and good dimensional stability. The glass fiber forming temperature is not more than 1210 ℃, and the upper limit temperature of crystallization is not more than 1150 ℃.
The method for preparing the glass fiber is not particularly limited, and the glass fiber can be prepared by a tank furnace method or an electric melting furnace method which are well known to those skilled in the art.
The tank furnace method or the electric melting furnace method specifically comprises the following steps: calculating the required raw material adding proportion according to the actual formula of the glass; quantitatively conveying various raw materials to a mixing bin according to the proportion, and fully and uniformly mixing to obtain qualified batch; conveying the batch to a kiln head bin of the tank furnace or the electric melting furnace, and delivering the batch to the tank furnace or the electric melting furnace by a feeder at a constant speed; the batch materials are heated, melted, clarified and homogenized in a tank furnace at the high temperature of 1300 ℃ and 1500 ℃ to form qualified molten glass; cooling the molten glass to the molding temperature through the operation channel, and then flowing out through a platinum bushing to form glass filaments; rapidly drawing the glass fiber into glass fiber with a set diameter under the high-speed traction of a wire drawing machine, and winding the glass fiber into a spinning cake by the wire drawing machine after spray cooling, impregnating compound coating and beam collecting; and then on a short cutting production line, cutting the silk cake into short strands with required length, and drying, granulating, sieving and the like to obtain the short glass fiber yarn.
Compared with the prior art, the invention has the advantages that:
1. the high-refractive-index high-performance glass fiber composition disclosed by the invention can reduce TiO to the maximum extent on the basis of ensuring that the refractive index of a glass fiber product is maintained at 1.580-1.5902In an amount of, or even not including, TiO2Therefore, the prepared high-refractive-index high-performance glass fiber has excellent transparency, and the composite material reinforced by the high-refractive-index high-performance glass fiber also has good transparency, particularly the glass fiber reinforced PC composite material, and the high-refractive-index high-performance glass fiber does not influence the natural color of PC resin, so that the high-refractive-index high-performance glass fiber can be widely applied to occasions with high requirements on color, particularly transparency.
2. The high-refractive-index high-performance glass fiber prepared from the high-refractive-index high-performance glass fiber composition has good mechanical properties, the tensile strength of the dipped yarn is as high as 2600MPa or more, and the tensile modulus is as high as 87GPa or more, so that the glass fiber reinforced composite material, particularly the glass fiber reinforced PC composite material, can be kept more favorably in structural strength and dimensional stability.
3. The high-refractive-index high-performance glass fiber composition has good fiber forming performance when being used for preparing high-refractive-index high-performance glass fibers, the forming temperature is not more than 1210 ℃, the upper limit temperature of crystallization is not more than 1150 ℃, the production difficulty is equivalent to that of general boron-free and fluorine-free alkali-free glass fibers, the preparation method of the glass fibers is not specially limited, the glass fibers can be prepared according to a tank furnace method or an electric melting furnace method well known by the technical personnel in the field, and the large-scale production can be realized under the existing tank furnace process condition.
Detailed Description
In order to facilitate understanding of the present invention, the present invention will be described in more detail below with reference to specific examples and comparative examples.
In the embodiment and the comparative example of the invention, the high-temperature viscosity of the glass fiber is detected by a BROOKFIELD high-temperature viscometer produced by ORTON company; the glass liquidus temperature is detected by an Orton Model gradient furnace; the refractive index of the glass fiber is measured by GB/T7962.1-2010 standard, and the tensile modulus is measured by ASTM D2343-03 standard.
Wherein T islogη=3The temperature at which the glass viscosity is 1000 poise corresponds to the temperature of the glass melt at the time of glass fiber molding, and is also referred to as the glass "glass fiber molding temperature".
TLiquid for treating urinary tract infectionThe liquidus temperature of glass is represented by a temperature at which the glass crystallization rate is 0, i.e., an upper limit of glass crystallization temperature, and is also referred to as "glass fiber crystallization temperature".
And the components of the compounds in the examples 1-21 are the components of the glass formula, and the components of the compounds in the comparative examples 1 and 2 refer to pages 53-54 of the book of glass fiber and mineral wool, and the numerical values are weight percentages. Because of factors such as detection errors, trace impurities not being analyzed and counted, decimal place values and the like, the total percentage content of the components in the table may not be completely 100%.
Example 1
By mass percent, 60 wt% of SiO210.8 wt% of Al2O322.4 wt% CaO, 0.3 wt% MgO, 0.3 wt% TiO24.0 wt% of Y2O30.3 wt% of BaO, 0.7wt% of Bi2O30.4 wt% of Li2O, 0.7 wt% of Na2O+K2O, 0.1 wt% Fe2O3Calculating the addition proportion of the required raw materials according to the formula, quantitatively conveying various raw materials to a mixing bin according to the proportion, and fully and uniformly mixing to obtain a qualified batch; conveying the batch to a kiln head bin of the tank furnace, and delivering the batch to the tank furnace by a feeder at a constant speed; the batch materials are heated, melted, clarified and homogenized in a tank furnace at the high temperature of 1300 ℃ and 1500 ℃ to form qualified high-refractive index high-performance glass liquid 1; cooling the high-refractive-index high-performance glass melt 1 to the molding temperature through an operation channel, and then flowing out through a platinum bushing to form a high-refractive-index high-performance glass wire 1; the glass fiber 1 is rapidly drawn into a high-refractive-index high-performance glass fiber 1 with a set diameter (13 +/-1 um) under the high-speed traction of a drawing machine, and is subjected to spray cooling, impregnating compound coating and bundling to be wound into a high-refractive-index high-performance spinning cake 1 by the drawing machine; and then on a short cutting production line, cutting the high-refractive-index high-performance spinning cake into short strands with required length, and carrying out the working procedures of drying, granulating, sieving and the like to obtain the high-refractive-index high-performance chopped glass fiber yarn 1.
The test shows that the forming temperature T of the high-refractivity high-performance glass fiber 1logη=3The upper limit of the crystallization temperature T of the molten glass 1 is 1205 DEG CLiquid for treating urinary tract infection1114 ℃, the refractive index nD/20 ℃ of the chopped glass fiber yarn 1 was 1.582, and the tensile modulus was 87.0 GPa.
Example 2
By mass percent, 59.2 wt% of SiO211.6 wt% of Al2O322.4 wt% CaO, 0.3 wt% MgO, 0.3 wt% TiO24.0 wt% of Y2O30.3 wt% of BaO, 0.7 wt% of Bi2O30.4 wt% of Li2O, 0.7 wt% of Na2O+K2O, 0.1 wt% Fe2O3Calculating the addition proportion of the required raw materials according to the formula, quantitatively conveying various raw materials to a mixing bin according to the proportion, and fully and uniformly mixing to obtain a qualified batch; conveying the batch to a kiln head bin of the tank furnace, and delivering the batch to the tank furnace by a feeder at a constant speed; batch in tank furnace 1Heating at 1500 ℃ under 300 ℃ plus temperature, melting, clarifying and homogenizing to form qualified high-refractive-index high-performance glass liquid 2; the high-refractive-index high-performance glass liquid 2 is cooled to the molding temperature through the operation channel and then flows out through the platinum bushing to form a high-refractive-index high-performance glass wire 2; the glass fiber 2 is rapidly drawn into high-refractive index high-performance glass fiber 2 with a set diameter (13 +/-1 um) under the high-speed traction of a drawing machine, and is wound into a high-refractive index high-performance spinning cake 2 by the drawing machine after being subjected to spray cooling, impregnating compound coating and bundling; and then on a short cutting production line, cutting the high-refractive-index high-performance spinning cake 2 into short strands with required length, and carrying out the working procedures of drying, granulating, sieving and the like to obtain the high-refractive-index high-performance chopped glass fiber yarn 2.
The test shows that the forming temperature T of the glass fiber 2 with high refractive index and high performancelogη=3At 1201 ℃ and the upper limit T of the crystallization temperature of the molten glassLiquid for treating urinary tract infectionThe glass fiber strand had a refractive index nD/20 ℃ of 1.583 and a tensile modulus of 87.4GPa at 1119 ℃ in the chopped glass fiber strand 2.
Example 3
57.2 wt% of SiO213.6 wt% Al2O322.4 wt% CaO, 0.3 wt% MgO, 0.3 wt% TiO24.0 wt% of Y2O30.3 wt% of BaO, 0.7 wt% of Bi2O30.4 wt% of Li2O, 0.7 wt% of Na2O+K2O, 0.1 wt% Fe2O3Calculating the addition proportion of the required raw materials according to the formula, quantitatively conveying various raw materials to a mixing bin according to the proportion, and fully and uniformly mixing to obtain a qualified batch; conveying the batch to a kiln head bin of the tank furnace, and delivering the batch to the tank furnace by a feeder at a constant speed; the batch materials are heated, melted, clarified and homogenized in a tank furnace at the high temperature of 1300 ℃ and 1500 ℃ to form qualified high-refractive index high-performance glass liquid 3; the high-refractive-index high-performance glass liquid 3 is cooled to the molding temperature through the operation channel and then flows out through the platinum bushing to form a high-refractive-index high-performance glass wire 3; the glass fiber 3 is rapidly drawn into high-refractive index high-performance glass fiber 3 with set diameter (13 +/-1 um) under the high-speed traction of a drawing machine, and is drawn after spray cooling, impregnating compound coating and bundlingWinding into a spinning cake 3 with high refractive index and high performance; then on a short cutting production line, the high-refractive-index high-performance spinning cake 3 is cut into short strands with required length, and the high-refractive-index high-performance short glass fiber yarn 3 is obtained after the procedures of drying, granulating, sieving and the like.
The test shows that the forming temperature T of the glass fiber 3 with high refractive index and high performancelogη=31194 ℃ and the upper limit T of the crystallization temperature of the molten glassLiquid for treating urinary tract infection1127 ℃, the refractive index nD/20 ℃ of the chopped glass fiber yarn 3 was 1.586, and the tensile modulus was 88.4 GPa.
Example 4
The difference from example 3 is that SiO is added in mass percent2The amount of Al added was changed to 55.2 wt%, based on the total weight of Al2O3The amount of addition was changed to 15.6 wt%.
The test shows that the forming temperature T of the glass fiber with high refractive index and high performancelogη=31186 ℃ and the upper limit T of the crystallization temperature of the molten glassLiquid for treating urinary tract infectionThe glass fiber yarn had a refractive index nD/20 ℃ of 1.585 of 1134 ℃ and a tensile modulus of 88.5 GPa.
Examples 1 to 4 above are for SiO2And Al2O3The variation range of (A) is verified through experiments, and the test results are analyzed to show that the variation range of (A) is consistent with SiO2Improved component content, high refractive index and high performance glass fiber forming temperature Tlogη=3Also higher, and Al2O3The higher the content of the component (A), the upper limit T of the crystallization temperature of the molten glassLiquid for treating urinary tract infectionThe higher the glass modulus, the less the glass refractive index is affected and the slightly increased.
Example 5
The difference from example 3 is that SiO is added in mass percent2The amount of Al added was changed to 58.2 wt%, based on the total weight of Al2O3The amount of CaO added was changed to 14.4 wt%, and the amount of CaO added was changed to 20.6 wt%.
The test shows that the forming temperature T of the glass fiber with high refractive index and high performancelogη=31198 ℃ and the upper limit T of the crystallization temperature of the molten glassLiquid for treating urinary tract infectionThe glass chopped strand had a refractive index nD/20 ℃ of 1.573 and a tensile modulus of 88.3GPa at 1132 ℃.
Example 6
The difference from example 3 is that SiO is added in mass percent2The amount of addition of (B) was changed to 57.7 wt%, and Al was added2O3The amount of CaO added was changed to 14 wt%, and the amount of CaO added was changed to 21.5 wt%.
The test shows that the forming temperature T of the glass fiber with high refractive index and high performancelogη=31196 ℃ and the upper limit T of the crystallization temperature of the molten glassLiquid for treating urinary tract infectionAt 1130 ℃, the refractive index nD/20 ℃ of the chopped glass fiber yarn was 1.580, and the tensile modulus was 88.3 GPa.
Example 7
The difference from example 3 is that SiO is added in mass percent2The amount of Al added was changed to 56.8 wt%, based on the total weight of Al2O3The amount of CaO added was changed to 13.2 wt%, and the amount of CaO added was changed to 23.3 wt%.
The test shows that the forming temperature T of the glass fiber with high refractive index and high performancelogη=31191 ℃ and the upper limit T of the crystallization temperature of the molten glassLiquid for treating urinary tract infection1128 ℃, the refractive index nD/20 ℃ of the chopped glass fiber yarn was 1.586, and the tensile modulus was 88.2 GPa.
Example 8
The difference from example 3 is that SiO is added in mass percent2The amount of Al added was changed to 56.4 wt%, based on the total weight of Al2O3The amount of CaO added was changed to 12.9 wt%, and the amount of CaO added was changed to 24 wt%.
The test shows that the forming temperature T of the glass fiber with high refractive index and high performancelogη=31188 ℃ and the upper limit T of the crystallization temperature of the molten glassLiquid for treating urinary tract infection1128 ℃, the refractive index nD/20 ℃ of the chopped glass fiber yarn was 1.587, and the tensile modulus was 87.9 GPa.
In examples 5 to 8, the influence of the preferable CaO content range on the refractive index was examined on the basis of example 3, and the refractive index of the high-refractive-index, high-performance glass fiber was increased with the increase of the CaO content and the SiO content was increased with the increase of the CaO content2And Al2O3Reduced total amount, high refractive index and high performance glass fiber forming temperature Tlogη=3And the tensile modulus decreases.
Example 9
The difference from example 3 is that SiO is added in mass percent2The amount of MgO added was changed to 57.5 wt%, and the amount of MgO added was changed to 0.
The test shows that the forming temperature T of the glass fiber with high refractive index and high performancelogη=31194 ℃ and the upper limit T of the crystallization temperature of the molten glassLiquid for treating urinary tract infection1125 ℃ and the refractive index nD/20 ℃ of the chopped glass fiber yarn was 1.585, and the tensile modulus was 88.1 GPa.
Example 10
The difference from example 3 is that SiO is added in mass percent2The amount of MgO added was changed to 56.6 wt%, and the amount of MgO added was changed to 0.9 wt%.
The test shows that the forming temperature T of the glass fiber with high refractive index and high performancelogη=31190 ℃ and the upper limit T of the crystallization temperature of the molten glassLiquid for treating urinary tract infectionAt 1130 ℃, the refractive index nD/20 ℃ of the chopped glass fiber yarn was 1.585, and the tensile modulus was 88.0 GPa.
Example 11
The difference from example 3 is that SiO is added in mass percent2The amount of MgO added was changed to 56.0 wt%, and the amount of MgO added was changed to 1.5 wt%.
The test shows that the forming temperature T of the glass fiber with high refractive index and high performancelogη=31187 ℃ and the upper limit T of the crystallization temperature of the molten glassLiquid for treating urinary tract infectionThe glass fiber yarn had a refractive index nD/20 ℃ of 1.585 and a tensile modulus of 87.9GPa at 1132 ℃.
Examples 9 to 11 were conducted based on example 3 to verify the variation range of MgO content, and it was not possible to replace CaO with MgO, which replaced part of SiO in this experiment, since it was necessary to ensure the refractive index of high-refractive index high-performance glass fiber2. In general, small amounts of MgO do not have a significant effect on the properties, but too high a content can lead to SiO2The content is low, so that the molding temperature is reduced and the molding interval (T)logη=3-TLiquid for treating urinary tract infection) And the size is reduced, which is not beneficial to the stable drawing of the high-refractivity high-performance glass fiber.
Example 12
The difference from example 3 is in massIn percent, measured by weight, adding Li2The addition of O is changed to 0 wt%, corresponding to SiO2In an amount of 57.6 wt%, Na2O+K2The amount of O added was 0.7 wt%.
The test shows that the forming temperature T of the glass fiber with high refractive index and high performancelogη=3At 1201 ℃ and the upper limit T of the crystallization temperature of the molten glassLiquid for treating urinary tract infectionThe melt index nD/20 ℃ of the chopped glass fiber yarn was 1.556, and the tensile modulus was 87.9GPa, at 1126 ℃.
Example 13
The difference from example 3 is that Li is added in mass percent2The addition of O is changed to 1.0 wt%, corresponding to SiO2In an amount of 56.8 wt%, Na2O+K2The amount of O added was 0.5 wt%.
The test shows that the forming temperature T of the glass fiber with high refractive index and high performancelogη=31185 ℃ and the upper limit T of the crystallization temperature of the molten glassLiquid for treating urinary tract infection1125 ℃ and 1.584 for the refractive index nD/20 ℃ of the chopped glass fiber yarn, and 87.9GPa for the tensile modulus.
Example 14
The difference from example 3 is that Li is added in mass percent2The addition of O is changed to 1.5 wt%, which corresponds to SiO2In an amount of 56.3 wt%, Na2O+K2The amount of O added was 0.5 wt%.
The test shows that the forming temperature T of the glass fiber with high refractive index and high performancelogη=31179 ℃ and the upper limit T of the crystallization temperature of the molten glassLiquid for treating urinary tract infectionThe melt index nD/20 ℃ of the chopped glass fiber yarn was 1.583, and the tensile modulus was 87.5GPa, at 1126 ℃.
Examples 12 to 14 were carried out to verify Li based on example 32The content of O varies within a range where a small amount of Li is observed2O pairs for lowering glass forming temperature Tlogη=3The effect is obvious, and the influence on other properties is not great. However, if the content is too high, the molding temperature may be lowered too low, resulting in a molding interval (T)logη=3-TLiquid for treating urinary tract infection) Too small, is not favorable for the stable wire drawing of the glass fiber.
Example 15
The difference from the embodiment 3 is that,based on the mass percentage, the addition amount of BaO is changed to 0.1 wt%, and the corresponding SiO2The amount of (B) was 58.1 wt%.
The test shows that the forming temperature T of the glass fiber with high refractive index and high performancelogη=3The upper limit T of the crystallization temperature of the molten glass is 1200 DEG CLiquid for treating urinary tract infection1128 ℃, the refractive index nD/20 ℃ of the chopped glass fiber yarn was 1.580, and the tensile modulus was 88.2 GPa.
Example 16
The difference from example 3 is that the amount of BaO added is 1.5 wt% in terms of mass percent, corresponding to SiO2The amount of (B) was 56.4 wt%.
The test shows that the forming temperature T of the glass fiber with high refractive index and high performancelogη=31188 ℃ and the upper limit T of the crystallization temperature of the molten glassLiquid for treating urinary tract infection1129 ℃, the refractive index nD/20 ℃ of the chopped glass fiber yarn was 1.587, and the tensile modulus was 88.1 GPa.
Examples 15 to 16 were conducted by examining the range of variation of the BaO content on the basis of example 3, and it can be seen that the crystallization temperature T can be lowered by adding a small amount of BaOLiquid for treating urinary tract infectionIncreasing the molding interval (T)logη=3-TLiquid for treating urinary tract infection) And has certain positive effect on the refractive index and the elastic modulus of the glass.
Example 17
The difference from example 3 is that Bi is added in mass percent2O3The addition amount of (A) is changed to 0.6 wt%, corresponding to SiO2The amount of (B) was 56.9 wt%.
The test shows that the forming temperature T of the glass fiber with high refractive index and high performancelogη=31192 ℃ and the upper limit T of the crystallization temperature of the molten glassLiquid for treating urinary tract infection1125 ℃ and the refractive index nD/20 ℃ of the chopped glass fiber yarn was 1.585, and the tensile modulus was 88.2 GPa.
Example 18
The difference from example 3 is that Bi is added in mass percent2O3The addition amount of (A) is changed to 0.9 wt%, corresponding to SiO2The amount of (B) was 56.6 wt%.
The test shows that the forming temperature T of the glass fiber with high refractive index and high performancelogη=31190 deg.CUpper limit of devitrification temperature T of molten glassLiquid for treating urinary tract infectionThe glass fiber yarn had a refractive index nD/20 ℃ of 1.586 and a tensile modulus of 88.2GPa at 1124 ℃.
Examples 17 to 18 were conducted to verify Bi based on example 32O3In the content range of (B), it can be seen that a small amount of Bi acts similarly to BaO2O3It also has the functions of reducing crystallization temperature and enlarging forming interval. But BaO and Bi2O3If the amount is too high, not only the cost is increased, but also adverse effects may occur.
Example 19
The difference from example 3 is that Y is calculated by mass percentage2O3The addition amount of (A) was changed to 4.9 wt%, which corresponds to SiO2The amount of (B) was 56.3 wt%.
The test shows that the forming temperature T of the glass fiber with high refractive index and high performancelogη=31191 ℃ and the upper limit T of the crystallization temperature of the molten glassLiquid for treating urinary tract infectionThe glass fiber was 1132 ℃ C., the refractive index nD/20 ℃ C. of the chopped glass fiber yarn was 1.590, and the tensile modulus was 88.9 GPa.
Example 20
The difference from example 3 is that Y is calculated by mass percentage2O3The addition amount of (A) was changed to 4.5 wt%, which corresponds to SiO2The amount of (B) was 56.7 wt%.
The test shows that the forming temperature T of the glass fiber with high refractive index and high performancelogη=31192 ℃ and the upper limit T of the crystallization temperature of the molten glassLiquid for treating urinary tract infectionThe resultant was 1129 ℃, and the chopped glass fiber yarn had a refractive index nD/20 ℃ of 1.588 and a tensile modulus of 88.7 GPa.
Example 21
The difference from example 3 is that Y is calculated by mass percentage2O3The addition amount of (A) was changed to 3.5 wt%, corresponding to SiO2The amount of (B) was 57.7 wt%.
The test shows that the forming temperature T of the glass fiber with high refractive index and high performancelogη=31198 ℃ and the upper limit T of the crystallization temperature of the molten glassLiquid for treating urinary tract infection1125 ℃ and 1.580 in terms of the refractive index nD/20 ℃ of the chopped glass fiber yarn, and 87.7GPa in terms of the tensile modulus.
Examples 19 to 21 were carried out to verify Y on the basis of example 32O3The content of (3) is within the range, and analysis shows that Y is increased2O3The content, the refractive index and the elastic modulus of the glass fiber are obviously increased, and the crystallization temperature is increased along with the increase of the content, the refractive index and the elastic modulus of the glass fiber, because of SiO2The content is relatively reduced, and the forming temperature is also reduced. So if Y continues to be increased2O3Content, on the one hand, increased cost, over-standard refractive index, and on the other hand, the molding window (T)logη=3-TLiquid for treating urinary tract infection) Too small, which is not conducive to wire drawing production.
Comparative example 1
54.4 percent by weight of SiO214.9 wt.% Al2O316.6 wt% CaO, 4.6 wt% MgO, trace TiO2,<0.5 wt% of Na2O+K2O,<0.5 wt% Fe2O38.5 wt% of B and 0.3 wt% of F, calculating the addition proportion of the required raw materials according to the formula, quantitatively conveying various raw materials to a mixing bin according to the proportion, and fully and uniformly mixing to obtain qualified batch; conveying the batch to a kiln head bin of the tank furnace, and delivering the batch to the tank furnace by a feeder at a constant speed; the batch materials are heated, melted, clarified and homogenized in a tank furnace at the high temperature of 1300 ℃ and 1500 ℃ to form qualified molten glass; cooling the molten glass to the molding temperature through the operation channel, and then flowing out through a platinum bushing to form glass filaments; rapidly drawing the glass fiber into glass fiber with a set diameter (13 +/-1 um) under the high-speed traction of a wire drawing machine, and winding the glass fiber into a spinning cake by the wire drawing machine after spray cooling, impregnating compound coating and bundling; and then on a short cutting production line, cutting the silk cake into short strands with required length, and drying, granulating, sieving and the like to obtain the common short glass fiber yarn.
The test shows that the forming temperature T of the glass fiberlogη=31214 ℃ and the upper limit T of the crystallization temperature of the molten glassLiquid for treating urinary tract infectionThe glass fiber yarn had a refractive index nD/20 ℃ of 1.545 and a tensile modulus of 81.9GPa at 1135 ℃.
Comparative example 2
58.0 wt% of SiO by mass percentage211.2 wt% of Al2O322 wt% CaO, 2.7 wt% MgO,<2.2 wt% TiO20.5 wt% of Na2O+K2O, 0.3 wt% Fe2O3Calculating the addition proportion of the required raw materials according to the formula, quantitatively conveying various raw materials to a mixing bin according to the proportion, and fully and uniformly mixing to obtain a qualified batch; conveying the batch to a kiln head bin of the tank furnace, and delivering the batch to the tank furnace by a feeder at a constant speed; the batch materials are heated, melted, clarified and homogenized in a tank furnace at the high temperature of 1300 ℃ and 1500 ℃ to form qualified molten glass; cooling the molten glass to the molding temperature through the operation channel, and then flowing out through a platinum bushing to form glass filaments; rapidly drawing the glass fiber into glass fiber with a set diameter (13 +/-1 um) under the high-speed traction of a wire drawing machine, and winding the glass fiber into a spinning cake by the wire drawing machine after spray cooling, impregnating compound coating and bundling; and then on a short cutting production line, cutting the silk cake into short strands with required length, and drying, granulating, sieving and the like to obtain the common short glass fiber yarn.
The test shows that the forming temperature T of the glass fiberlogη=31261 deg.C, upper limit of crystallization temperature T of molten glassLiquid for treating urinary tract infection1173 ℃, the refractive index nD/20 ℃ of the chopped glass fiber yarn is 1.579, and the tensile modulus is 83.1 GPa.
Table 1 below is a summary of the ingredients and properties of examples 1-20 of the present invention and comparative examples 1-2.
Figure BDA0002528301770000131
The present invention can be used for reinforcing transparent PC resins, and also for reinforcing transparent Polyamide (PA) resins having a refractive index of about 1.57 to 1.59.
The glass fiber composition according to the present invention can be combined with one or more organic and/or inorganic materials, which may include thermosetting resins such as epoxy resins, unsaturated polyesters, vinyl resins, etc., and thermoplastic resins such as Polycarbonate (PC), polypropylene (PP), Polyamide (PA), polybutylene terephthalate (PBT), polyethylene terephthalate (PET), etc., to produce a composite material having excellent properties.
Although embodiments of the present invention have been shown and described above, it is understood that the above embodiments are exemplary and should not be construed as limiting the present invention, and that variations, modifications, substitutions and alterations can be made to the above embodiments by those of ordinary skill in the art within the scope of the present invention.

Claims (12)

1. The high-refractive-index high-performance glass fiber composition is characterized by comprising the following components in percentage by mass:
Figure FDA0002528301760000011
wherein, Y is2O3The mass percentage of the TiO is 3.5-4.9wt percent2、Na2O、K2O is introduced as an impurity, not separately added, and the Li2O、Na2O、K2The sum of the mass percent of O is not more than 1.5 wt%.
2. The high index, high performance glass fiber composition of claim 1, wherein Y is2O3、Bi2O3The sum of the mass percent of BaO is 3.5-5.9wt percent, wherein the Bi is2O3The mass percentage of the BaO is 0.1-0.9 wt%, wherein the mass percentage of the BaO is 0.1-1.5 wt%.
3. The high index high performance glass fiber composition of claim 1, wherein said TiO is introduced as an impurity2The mass percentage of the components is controlled to be 0-0.4 wt%.
4. The high index, high performance glass fiber composition of claim 1, wherein the Fe is2O3The mass percentage of the components is controlled to be 0-0.3 wt%.
5. The high index high performance glass fiber composition of claim 1, wherein the Li is Li2O、Na2O、K2The mass percentage of O is controlled to be 0.3-1.5 wt%
6. The high index high performance glass fiber composition of claim 1, wherein the SiO2The mass percentage of the components is controlled to be 55.2-59.2 wt%.
7. The high index, high performance glass fiber composition of claim 1, wherein said Al is2O3The mass percentage of the components is controlled to be 11.6-15.6wt percent,
8. the composition of claim 1, wherein the CaO is present in an amount of 21.5 to 23.3 wt%.
9. The composition of claim 1, wherein the MgO is contained in an amount of 0 to 0.5 wt%.
10. The high-refractive-index high-performance glass fiber composition according to claim 1, wherein the contents of the components are expressed by mass percent as follows:
Figure FDA0002528301760000021
wherein, Y is2O3Is 3.5 to 4.9 weight percent, and the Bi2O3The mass percentage of the BaO is 0.1-0.9 wt%, wherein the mass percentage of the BaO is 0.1-1.5 wt%.
11. A high refractive index high performance glass fiber made from the high refractive index high performance glass fiber composition of any one of claims 1 to 10, wherein the high refractive index high performance glass fiber has a refractive index of 1.580 to 1.590.
12. A high refractive index high performance glass fiber reinforced composite comprising the high refractive index high performance glass fiber of claim 11.
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