CN105244116A - Cable wire manufacturing method - Google Patents
Cable wire manufacturing method Download PDFInfo
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- CN105244116A CN105244116A CN201510552794.7A CN201510552794A CN105244116A CN 105244116 A CN105244116 A CN 105244116A CN 201510552794 A CN201510552794 A CN 201510552794A CN 105244116 A CN105244116 A CN 105244116A
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Abstract
The invention relates to a cable wire manufacturing method comprising the following steps that a carbon fiber is led out by a yarn frame to enter a first impregnation area for impregnation, and the used epoxy resin is heat-resistant high-mechanical-property epoxy resin; the carbon fiber enters a first curing furnace for precuring after completion of impregnation so that a carbon fiber composite core is manufactured, diameter is 5mm-12mm, and degree of curing is enabled to be greater than 85% by regulating temperature; glass fibers of the two sides are led out and then enter a second impregnation area and a third impregnation area for impregnation respectively, and the used epoxy resin is high-temperature-resistant weather-resistant epoxy resin; the glass fibers after impregnation are wound and wrapped on the external layer of the carbon fiber core via a winding area, thickness of single side is 0.5mm-2mm, and winding speed is controlled to be synchronous with pultrusion speed via a servo motor; the carbon fiber composite core and the glass fiber protection layer are composite and then pass a second curing furnace together, and the carbon fiber composite core and the glass fiber protection layer are fully cured by regulating temperature; and a composite material cable core product is collected at a winding disc through a traction machine.
Description
The divisional application that the application is the applying date is " on 02 05th, 2013 ", application number is " 2013100442638 ", name is called the application for a patent for invention of " a kind of manufacture method of carbon fiber composite material cable wire ".
Technical field
The present invention relates to a kind of cable core, especially relate to a kind of manufacture method of cable.
Background technology
Cable core as the substitute products of traditional steel core, due to long-term high temperature in the wild, sunshine, work under the mal-conditions such as climate change, while requiring it to have excellent mechanical property, also there are high temperature resistant, uvioresistant and ageing resistance etc., require very high to the combination property of cable core.
Traditional cable core structure is the load-bearing core that internal carbon fibers and epoxy resin composite material are made, the outside protective layer being glass fibre and epoxy resin composite and making, both shared same resin systems.Under same resin system, interact between the performances such as high temperature resistant, tensile strength, bending strength, modulus, compression strength, uvioresistant and ageing resistance, by modification increase performance in a certain respect often with sacrifice on the other hand performance for cost.
Dicyclopentadiene (DCPD) is the dimer of cyclopentadiene, mainly come from cracking of ethylene by-product C 5 fraction and
Carbonization of coal by-product light benzene fraction, because chemism is high, be the raw material of Petropols and multiple fine chemicals, be introduced into epoxy resin, Properties of Epoxy Resin can be made to improve, as its viscosity, mechanical property and good flame-retardance and toughness are all better than general purpose epoxy resin.
Summary of the invention
The present invention devises a kind of manufacture method of cable, and it is poor that its technical problem solved is that existing cable core exists the aspect of performances such as resistance to elevated temperatures, tensile strength, mechanical property, anti-flammability, compression strength, uvioresistant and ageing resistance.
In order to solve the technical problem of above-mentioned existence, present invention employs following scheme: a kind of cable core, comprise load-bearing core (12) and protective layer (13), described protective layer (13) is coated on the outside of described load-bearing core (12) by winding process, it is characterized in that: the compound that described load-bearing core (12) is heat-resisting strong mechanical performance epoxy resin and carbon fiber, the compound that described protective layer (13) is high temperature resistant weather resistance epoxy resin and glass fibre; Described load-bearing core
(12) heat-resisting strong mechanical performance epoxy resin is made up of following compositions: the blending epoxy of 100 mass parts; The curing agent of 20-75 mass parts; The diluent of 10-30 mass parts; The promoter of 0.5-5.0 mass parts; The filler of 0.5-5.0 mass parts; Described blending epoxy comprises epoxy resin a and epoxy resin b; Epoxy resin a is dicyclopentadiene (DCPD) type epoxy resin, and described epoxy resin b is the composition of glycidyl amine epoxy resin and bisphenol A-type glycidyl ether type epoxy resin; The mass ratio of epoxy resin a and epoxy resin b is: 50-80:20-50; The structural formula of described dicyclopentadiene type epoxy resin is as follows:
, in formula, n is the integer of 0 to 10; The mass ratio of the glycidyl amine epoxy resin in described epoxy resin b and bisphenol A-type glycidyl ether type epoxy resin is: 1:9-9:1.
In described protective layer (13), high temperature resistant weather resistance epoxy resin is made up of following compositions: comprise component A and B component, wherein component A comprises following compositions: 100 mass parts epoxy resin, 5-20 mass parts diluent, 0.5-5.0 mass parts silane coupler, the inorganic filler of 0.5-5.0 mass parts; B component comprises following compositions: 25-45 mass parts amine curing agent, 0.5-5.0 mass parts promoter; Described epoxy resin is the combination of epoxy resin c and epoxy resin d, and the mass ratio of epoxy resin c and epoxy resin d is: 50-80:20-50; Described epoxy resin c is for comprising glycidic amine type, diglycidyl ether type or the glycidyl ester type glycolylurea epoxide resin of one or more glycolylurea ring (five yuan of diazacyclos), glycolylurea ring (five yuan of diazacyclos) structural formula is as follows, and in glycolylurea ring (five yuan of diazacyclos) structural formula, substituent R 1 and R2 are H, CH3, C2H5, aryl or aralkyl:
; Described epoxy resin d is at least one in following several epoxy resin: 4,5-epoxide ring ethane-1,2-dioctyl phthalate 2-glycidyl ester, bisphenol-f type glycidyl ether type epoxy resin or bisphenol A-type glycidyl ether type epoxy resin; Wherein, bisphenol-f type glycidyl ether type epoxy resin or bisphenol A-type glycidyl ether type epoxy resin preferred viscosity ranges: 500-4000mPas(25 DEG C).
Further, described protective layer (13) epoxy resin c is the 2-glycidyl amine type glycolylurea epoxide resin containing a glycolylurea ring, and chemical structural formula is as follows:
; Substituent R 1 wherein and R2 exist and combine selection mode below: the 1) compound of R1 to be H, R2 be H; 2) compound of R1 to be CH3, R2 be H; 3) compound of R1 to be CH3, R2 be CH3; 4) compound of R1 to be C2H5, R2 be H; 5) compound of R1 to be C2H5, R2 be CH3.
Further, amine curing agent described in described protective layer (13) is the combination of amine curing agent a and amine curing agent b, and the mass ratio of amine curing agent a and amine curing agent b is: 20-40:5-25; Described amine curing agent a is the polyether monoamine compound comprising two or more amido functional groups, preferably from molecular weight ranges 200-2500, range of viscosities: 5-300mPas(25 DEG C) polyether monoamine compound in one or more; Described amine curing agent b is one or more of aliphat amine and modified aliphatic aminated compounds, preferably from one or more in diethylenetriamine, triethylene tetramine, TEPA, diamines, methylol ethylenediamine, methylol diethylenetriamine, beta-hydroxyethyl ethylenediamine.
Further, described in described protective layer (13), promoter is selected from: one or more in 2,4,6-tri-(dimethylamino methyl) phenol, boron trifluoride complex, triethanolamine.
Further; diluent described in described protective layer (13) is the compound comprising two epoxy functionality and at least one ehter bond, preferably from one or more in ethylene glycol diglycidylether, butanediol diglycidyl ether, hexanediol diglycidyl ether, cylohexanediol diglycidyl ether, cyclohexanedimethanodiglycidyl diglycidyl ether, neopentylglycol diglycidyl ether, polyethyleneglycol diglycidylether, resorcinolformaldehyde resin.
Further, described in described protective layer (13), coupling agent is the silane coupling agent comprising epoxy functionality; Be preferably gamma-aminopropyl-triethoxy-silane, the one in γ-glycidyl ether oxygen propyl trimethoxy silicane or γ-(methacryloxy) propyl trimethoxy silicane.
Further, the curing agent in described load-bearing core (12) is selected from: one or more in phthalic anhydride, maleic anhydride, tetrahydrochysene phthalate anhydride, α-methacrylic acid.
Further, the diluent in described load-bearing core (12) is selected from: one or more in ethylene glycol diglycidylether, butanediol diglycidyl ether, hexanediol diglycidyl ether, cylohexanediol diglycidyl ether.
Further, the promoter in described load-bearing core (12) is selected from: one or more in tertiary amine, benzyl dimethylamine, 2,4,6-tri-(dimethylamino methyl) phenol, boron trifluoride complex, 2-ethyl-4-methylimidazole.
Further, the inorganic filler in described load-bearing core (12) is selected from: one or more in calcium carbonate, kaolin, diatomite, bentonite, nano-titanium oxide, talcum powder.
A manufacture method for carbon fiber composite material cable wire, comprises the following steps:
The first step, is drawn carbon fiber by creel, enters the first impregnation district impregnation, and the epoxy resin of use is heat-resisting strong mechanical performance epoxy resin;
Second step, after impregnation completes, carbon fiber enters the first curing oven precuring, obtained carbon fiber complex core, and diameter is 5mm-12mm, regulates temperature to make curing degree reach more than 85%;
3rd, both sides glass fibre enters the second impregnation district and the 3rd impregnation district impregnation after drawing respectively, and the epoxy resin of use is high temperature resistant weather resistance epoxy resin;
4th step, after impregnation, glass fibre is outer at carbon fiber core by being wound around district's voluble wrapping, and one-sided thickness is 0.5mm-2mm, and speed of wrap is by Serve Motor Control and pultrusion speed synchronised;
5th step, carbon fiber complex core by the second curing oven, regulates temperature to make both fully solidifications together with after glass fibre protective layer compound;
6th step, composite material cable core goods are by after hauling machine, and at closed reel, place collects.
The manufacture method of this carbon fiber composite material cable wire, compared with the manufacture method of traditional carbon fiber composite material cable wire, has following beneficial effect:
(1) the heat-resisting strong mechanical performance epoxy resin of the load-bearing core in the present invention is selected from the composition of dicyclopentadiene type epoxy resin, glycidyl amine epoxy resin and glycidyl ether type epoxy resin, their constituent has strong mechanical performance and good flame-retardance performance, and resin long working life can meet the needs that cable uses.
(2) the present invention's heat-resisting strong mechanical performance epoxy resin has good wettability and adhesive strength to carbon fiber, cured product has good thermal endurance and mechanical strength, and the thermal endurance of the fibre reinforced cable adopting the present invention heat-resisting strong mechanical performance epoxy resin to make, moisture-proof, electric property, toughness and machinability are greatly enhanced.
(3) anhydrides compound or acids is adopted to import the curing agent mixture of molding epoxy resin as vacuum in the present invention, thus there is good toughness and higher glass transition temperature, to meet heat resistant requirements, can use at a higher temperature after reprocessing, its finished product interior solid is good, air-gap-free, performance are homogeneous.
(4) diluent in the heat-resisting strong mechanical performance epoxy resin of the present invention can reduce curing system viscosity, increases mobility, increases the service life, do not affect again the mechanical performance of epoxy resin cured product.
(5) promoter in the heat-resisting strong mechanical performance epoxy resin of the present invention effectively can solve the problem of cold curing overlong time, while shortening curing time, ensure that the intensity of solidfied material remains unchanged substantially.
(6) add filler in the heat-resisting strong mechanical performance epoxy resin of the present invention, except can reducing goods cost, also can improve epoxy resin processability, flame resistance, the viscosity of resin and processing technology.
(7) the present invention adopts glycolylurea epoxide resin and low viscosity epoxy resin (4,5-epoxide ring ethane-1,2-dioctyl phthalate 2-glycidyl ester, bisphenol-f type glycidyl ether type epoxy resin or bisphenol A-type glycidyl ether type epoxy resin) blending type epoxy resin as resin matrix, can not only meet fibre reinforced composites vacuum imports shaping to the low viscous requirement of resin, and composite product can also be made to possess excellent resistance to elevated temperatures.
(8) glycolylurea epoxide resin used in the present invention has that viscosity is low, good manufacturability, good wetting property is had to glass fibre, carbon fiber and multiple filler, owing to comprising five yuan of diazacyclos in its structure, also have the features such as Heat stability is good, thermal endurance is high, weather resisteant is good concurrently.
(9) the toughness functional groups such as multiple ehter bonds are comprised in the polyether monoamine curing agent structure used in the present invention, composite product can be made to have the shock resistance of high-strength and high ductility, by adopting the blending type curing system of polyether monoamine curing agent and aliphat amine curing agent, the problems such as solidfied material fragility, elongation at break are little effectively can be solved.
(10) the present invention adopts a certain amount of promoter to coordinate blending type amine curing agent to use together, effectively can solve the problem of cold curing overlong time, while shortening curing time, ensure that the intensity of solidfied material remains unchanged substantially.
(11) the present invention adopts inorganic filler can reduce the shrinkage of goods, improves the dimensional stability of goods, surface smoothness and flatness etc., also can improve impact strength and the compressive strength of goods to a certain extent; In addition, filler add the consumption that can reduce epoxy resin, reduce costs.
(12) auxiliary agent that the present invention adopts also comprises silane coupler and diluent.Wherein silane coupler can improve bonding strength between reinforcing fiber materials and resin, improves interface state, is conducive to the mechanical performance and the electrical insulation capability that improve composite product; The effect of diluent can reduce the viscosity of whole composition.
Accompanying drawing explanation
Fig. 1 is the structural representation of cable core of the present invention;
Fig. 2 is the moulding process schematic diagram of cable core of the present invention.
Description of reference numerals: 1-creel; 2-the first impregnation district; 3-the first curing oven; 4-the second impregnation district; 5-the three impregnation district; 6-be wound around district; 7-the second curing oven; 8-hauling machine; 9-closed reel; 10-carbon fiber; 11-glass fibre; 12-load-bearing core; 13-protective layer.
Embodiment
Below in conjunction with Fig. 1 and Fig. 2, the present invention will be further described: as shown in Figure 1, a kind of cable core, comprise load-bearing core 12 and protective layer 13, protective layer 13 is coated on the outside of load-bearing core 12 by winding process, load-bearing core 12 is the compound of heat-resisting strong mechanical performance epoxy resin and carbon fiber, and protective layer 13 is the compound of high temperature resistant weather resistance epoxy resin and glass fibre; The heat-resisting strong mechanical performance epoxy resin of load-bearing core 12 is made up of following compositions: the blending epoxy of 100 mass parts; The curing agent of 20-75 mass parts; The diluent of 10-30 mass parts; The promoter of 0.5-5.0 mass parts; The filler of 0.5-5.0 mass parts; Described blending epoxy comprises epoxy resin a and epoxy resin b; Epoxy resin a is dicyclopentadiene (DCPD) type epoxy resin, and epoxy resin b is the composition of glycidyl amine epoxy resin and bisphenol A-type glycidyl ether type epoxy resin; The mass ratio of epoxy resin a and epoxy resin b is: 50-80:20-50; The structural formula of described dicyclopentadiene type epoxy resin is as follows:
In formula, n is the integer of 0 to 10; The mass ratio of the glycidyl amine epoxy resin in described epoxy resin b and bisphenol A-type glycidyl ether type epoxy resin is: 1:9-9:1.
Protective layer 13 epoxy resin c is the 2-glycidyl amine type glycolylurea epoxide resin containing a glycolylurea ring, and chemical structural formula is as follows:
; Substituent R 1 wherein and R2 exist and combine selection mode below: the 1) compound of R1 to be H, R2 be H; 2) compound of R1 to be CH3, R2 be H; 3) compound of R1 to be CH3, R2 be CH3; 4) compound of R1 to be C2H5, R2 be H; 5) compound of R1 to be C2H5, R2 be CH3.
Amine curing agent described in protective layer 13 is the combination of amine curing agent a and amine curing agent b, and the mass ratio of amine curing agent a and amine curing agent b is: 20-40:5-25; Described amine curing agent a is the polyether monoamine compound comprising two or more amido functional groups, preferably from molecular weight ranges 200-2500, range of viscosities: 5-300mPas(25 DEG C) polyether monoamine compound in one or more; Described amine curing agent b is one or more of aliphat amine and modified aliphatic aminated compounds, preferably from one or more in diethylenetriamine, triethylene tetramine, TEPA, diamines, methylol ethylenediamine, methylol diethylenetriamine, beta-hydroxyethyl ethylenediamine.
Described in protective layer 13, promoter is selected from: one or more in 2,4,6-tri-(dimethylamino methyl) phenol, boron trifluoride complex, triethanolamine.
Diluent described in protective layer 13 is the compound comprising two epoxy functionality and at least one ehter bond, preferably from one or more in ethylene glycol diglycidylether, butanediol diglycidyl ether, hexanediol diglycidyl ether, cylohexanediol diglycidyl ether, cyclohexanedimethanodiglycidyl diglycidyl ether, neopentylglycol diglycidyl ether, polyethyleneglycol diglycidylether, resorcinolformaldehyde resin.
Coupling agent described in protective layer 13 is the silane coupling agent comprising epoxy functionality; Be preferably gamma-aminopropyl-triethoxy-silane, the one in γ-glycidyl ether oxygen propyl trimethoxy silicane or γ-(methacryloxy) propyl trimethoxy silicane.
Also add ultraviolet absorber in protective layer 13, ultraviolet absorber is one in UV-9, UV-531, UV-327, triazine-5 or how several combination.
Also add energy transfer agent in protective layer 13, described energy transfer agent is one or both combinations in three (1,2,2,6,6-pentamethvl base) phosphite esters or AM101.
Curing agent in load-bearing core 12 is selected from: one or more in phthalic anhydride, maleic anhydride, tetrahydrochysene phthalate anhydride, α-methacrylic acid.
Diluent in load-bearing core 12 is selected from: one or more in ethylene glycol diglycidylether, butanediol diglycidyl ether, hexanediol diglycidyl ether, cylohexanediol diglycidyl ether.
Promoter in load-bearing core 12 is selected from: one or more in tertiary amine, benzyl dimethylamine, 2,4,6-tri-(dimethylamino methyl) phenol, boron trifluoride complex, 2-ethyl-4-methylimidazole.
Inorganic filler in load-bearing core 12 is selected from: one or more in calcium carbonate, kaolin, diatomite, bentonite, nano-titanium oxide, talcum powder.
As shown in Figure 2, be the moulding process schematic diagram of cable core of the present invention, its operable profile principle is as follows:
The first step, is drawn carbon fiber 10 by creel 1, enters the first impregnation district 2 impregnation, and the epoxy resin of use is heat-resisting strong mechanical performance epoxy resin;
Second step, after impregnation completes, carbon fiber enters the first curing oven 3 precuring, obtained carbon fiber complex core, and diameter is 5-12mm, regulates temperature to make curing degree reach more than 85%;
3rd, both sides glass fibre 11 enters the second impregnation district 4 and the 3rd impregnation district 5 impregnation after drawing respectively, and the epoxy resin of use is high temperature resistant weather resistance epoxy resin;
4th step, after impregnation, glass fibre is outer at carbon fiber core by being wound around district 6 voluble wrapping, and one-sided thickness is 0.5mm-2mm, and speed of wrap is by Serve Motor Control and pultrusion speed synchronised;
5th step, carbon fiber complex core by the second curing oven 7, regulates temperature to make both fully solidifications together with after glass fibre protective layer compound;
6th step, composite material cable core goods are by after hauling machine 8, and at closed reel 9, place collects.
Wherein, the preparation method of heat-resisting strong mechanical performance epoxy resin, comprises the following steps: step 1, epoxy resin a and epoxy resin b mix and be incorporated in less than 40 DEG C with the speed mechanical dispersed with stirring 5-10 minute of 800-1000 rev/min; Step 2, add inorganic filler and diluent successively while stirring, stand-by with left at room temperature after the speed mechanical dispersed with stirring 5-10 of 800-1000 rev/min minute; Step 3, by curing agent at 18 DEG C-25 DEG C with the speed mechanical dispersed with stirring 5-15 minute of 600-800 rev/min; Step 4, adding promoter while stirring, at room temperature with the speed mechanical dispersed with stirring 5-15 minute of 600-800 rev/min; Step 5, product obtained by step 2 to be mixed at 18 DEG C-25 DEG C with product obtained by step 4, with the speed mechanical dispersed with stirring 3-6 minute of 3000-3500 rev/min; Namely heat-resisting strong mechanical performance epoxy resin is obtained after step 6, vacuum defoamation.
Specifically, by 50g dicyclopentadiene (DCPD) type epoxy resin (purchased from Dai Nippon Printing HP-7200H, epoxide equivalent (EEW): 279), 45g bisphenol A-type glycidyl ether type epoxy resin E-51(is purchased from Wuxi Resin Factory of Blue Star New Chemical Material Co., Ltd., epoxide number is 0.48-0.54), 5g glycidyl amine epoxy resin JEh-012(is purchased from Changhu Jiafa chemistry Co., Ltd., epoxide number is 0.80-0.85) mixing, with the speed mechanical dispersed with stirring 5 minutes of 800 revs/min at 30 DEG C, add 0.5g kaolin successively while stirring, 10g1, 4-butanediol diglycidyl ether, with the speed mechanical dispersed with stirring of 800 revs/min after 10 minutes left at room temperature stand-by, 40g phthalic anhydride is at room temperature stirred with the speed mechanical of 600 revs/min, then in stirring simultaneously, add 0.5g2-ethyl-4-methylimidazole, at room temperature same with the speed mechanical dispersed with stirring 5-10 minute of 600 revs/min.At room temperature said components is mixed, with the speed mechanical dispersed with stirring 3 minutes of 3000 revs/min, after vacuum defoamation, namely obtain described composition epoxy resin, then pour die casting solidification into.The exothermic heat of reaction curve of differential scanning calorimetry (DSC method) test wrapper epoxy resin system, heating rate 5 DEG C/min and 15 DEG C/min, obtaining program curing by extrapolation is 28 DEG C of solidifications 5 hours, and 80 DEG C solidify 6 hours.According to standard GB/T/T2586-1995, the hot strength of epoxy matrix resin of preparation, fracture elongation, tensile modulus of elasticity are tested, specimen size is as follows: length is 100mm ± 0.5mm, end portion width is 10mm ± 0.5mm, narrow parallel portion length 30mm ± 0.5mm, narrow parallel portion width 5mm ± 0.2mm, thickness is 2.2mm ± 0.2mm.Experiment repetition six times, the hot strength recording this epoxy matrix resin is 68MPa, fracture elongation 5.7%, tensile modulus of elasticity 3.1GPa.Test the bending strength of epoxy matrix resin of preparation, the modulus of elasticity in static bending according to standard GB/T/T2570-1995, specimen size is as follows: length is 40mm, and width is 3mm ± 0.2mm, and thickness is 2mm ± 0.2mm.Experiment repetition six times, the bending strength recording this epoxy matrix resin is 112MPa, modulus of elasticity in static bending 3.12GPa.Differential scanning calorimetry (DSC method) surveys vitrification point, heating rate 5 DEG C/min, and the vitrification point recording epoxy matrix resin is 82 DEG C, and adopt NDJ-8S type rotation viscometer testing tree oil/fat composition viscosity, viscosity when 25 DEG C is 520mPas.
Wherein, high temperature resistant weathering performance composition epoxy resin manufacture method is as follows: comprise the following steps: step 1, by part epoxy resin c and d in component A below 30 DEG C with the speed mechanical dispersed with stirring 5-10 minute of 800-1000 rev/min; Step 2, add diluent and coupling agent successively while stirring, stand-by with left at room temperature after the speed mechanical dispersed with stirring 5-10 of 800-1000 rev/min minute; Step 3, by composition amine curing agent a and b in B component at room temperature with the speed mechanical dispersed with stirring 5-10 minute of 600-800 rev/min; Step 4, adding promoter, primary antioxidant and aid anti-oxidants while stirring, at room temperature with the speed mechanical dispersed with stirring 5-10 minute of 600-800 rev/min; Step 5, at room temperature by component A and B component mixing, with the speed mechanical dispersed with stirring 3-5 minute of 3000-3500 rev/min; Namely high temperature resistant weathering performance composition epoxy resin is obtained after step 6, vacuum defoamation.
By 10.0g glycolylurea epoxide resin MHR-070(purchased from Wuxi Meihua Chemical Co., Ltd., epoxide number is 0.70-0.74), 90.0g bisphenol A-type glycidyl ether type epoxy resin E-51(is purchased from Wuxi Resin Factory of Blue Star New Chemical Material Co., Ltd., epoxide number is 0.48-0.54) at 25 DEG C with the speed mechanical dispersed with stirring 5 minutes of 800 revs/min, add 5g1 successively while stirring, 4-butanediol diglycidyl ether, 0.5g γ-glycidyl ether oxygen propyl trimethoxy silicane, with the speed mechanical dispersed with stirring of 800 revs/min after 10 minutes left at room temperature stand-by, by 15.0g polyetheramine D230 and 20.0g triethylene tetramine at room temperature with the speed mechanical dispersed with stirring 5 minutes of 600 revs/min, adding 0.5g2 while stirring, 4, 6-tri-(dimethylamino methyl) phenol, 0.08g tetra-[β-(3, 5-di-tert-butyl-hydroxy phenyl) propionic acid] the two lauryl alcohol ester of pentaerythritol ester and 0.02g thio-2 acid, at room temperature with the speed mechanical dispersed with stirring 5 minutes of 600 revs/min.At room temperature said components is mixed, with the speed mechanical dispersed with stirring 3 minutes of 3000 revs/min, after vacuum defoamation, namely obtain described composition epoxy resin, then pour die casting solidification into.The exothermic heat of reaction curve of differential scanning calorimetry (DSC method) test wrapper epoxy resin system, heating rate 5 DEG C/min and 15 DEG C/min, obtaining program curing by extrapolation is 35 DEG C of solidifications 1 hour, and 110 DEG C solidify 2 hours, and 180 DEG C solidify 2 hours.According to standard GB/T/T16421-1996, the hot strength of epoxy matrix resin of preparation, fracture elongation, tensile modulus of elasticity are tested, specimen size is as follows: length is 100mm ± 0.5mm, end portion width is 10mm ± 0.5mm, narrow parallel portion length 30mm ± 0.5mm, narrow parallel portion width 5mm ± 0.2mm, thickness is 2.2mm ± 0.2mm.Experiment repetition six times, the hot strength recording this epoxy matrix resin is 58MPa, fracture elongation 4.0%, tensile modulus of elasticity 2.5GPa.Test the bending strength of epoxy matrix resin of preparation, the modulus of elasticity in static bending according to standard GB/T/T16419-1996, specimen size is as follows: length is 40mm, and width is 3mm ± 0.2mm, and thickness is 2mm ± 0.2mm.Experiment repetition six times, the bending strength recording this epoxy matrix resin is 104MPa, modulus of elasticity in static bending 3.3GPa.Differential scanning calorimetry (DSC method) surveys vitrification point, heating rate 5 DEG C/min, and the vitrification point recording epoxy matrix resin is 155 DEG C, and adopt NDJ-8S type rotation viscometer testing tree oil/fat composition viscosity, viscosity when 25 DEG C is 471mPas.
Above by reference to the accompanying drawings to invention has been exemplary description; obvious realization of the present invention is not subject to the restrictions described above; as long as have employed the various improvement that method of the present invention is conceived and technical scheme is carried out; or design of the present invention and technical scheme directly applied to other occasion, all in protection scope of the present invention without to improve.
Claims (1)
1. the manufacture method of a cable, comprise the following steps: step 1, carbon fiber (10) is drawn by creel (1), enter the first impregnation district (2) impregnation, the epoxy resin used is heat-resisting strong mechanical performance epoxy resin, and described heat-resisting strong mechanical performance epoxy resin is made up of following compositions: the blending epoxy of 100 mass parts; The curing agent of 20-75 mass parts; The diluent of 10-30 mass parts; The promoter of 0.5-5.0 mass parts; The filler of 0.5-5.0 mass parts; Described blending epoxy comprises epoxy resin a and epoxy resin b; Epoxy resin a is dicyclopentadiene (DCPD) type epoxy resin, and described epoxy resin b is the composition of glycidyl amine epoxy resin and bisphenol A-type glycidyl ether type epoxy resin; The mass ratio of epoxy resin a and epoxy resin b is: 50-80:20-50; The structural formula of described dicyclopentadiene type epoxy resin is as follows:
, in formula, n is the integer of 0 to 10; The mass ratio of the glycidyl amine epoxy resin in described epoxy resin b and bisphenol A-type glycidyl ether type epoxy resin is: 1:9-9:1;
Step 2, after impregnation completes, carbon fiber enters the first curing oven (3) precuring, obtained carbon fiber complex core, and diameter is 5-12mm, regulates temperature to make curing degree reach more than 85%;
Step 3, both sides glass fibre (11) enters the second impregnation district (4) and the 3rd impregnation district (5) impregnation after drawing respectively, and the epoxy resin of use is high temperature resistant weather resistance epoxy resin; Described high temperature resistant weather resistance epoxy resin is made up of following compositions: comprise component A and B component, wherein component A comprises following compositions: 100 mass parts epoxy resin, 5-20 mass parts diluent, 0.5-5.0 mass parts silane coupler, the inorganic filler of 0.5-5.0 mass parts; B component comprises following compositions: 25-45 mass parts amine curing agent, 0.5-5.0 mass parts promoter; Described epoxy resin is the combination of epoxy resin c and epoxy resin d, and the mass ratio of epoxy resin c and epoxy resin d is: 50-80:20-50; Described epoxy resin c is for comprising glycidic amine type, diglycidyl ether type or the glycidyl ester type glycolylurea epoxide resin of one or more glycolylurea ring (five yuan of diazacyclos), glycolylurea ring (five yuan of diazacyclos) structural formula is as follows, and in glycolylurea ring (five yuan of diazacyclos) structural formula, substituent R 1 and R2 are H, CH3, C2H5, aryl or aralkyl:
, described epoxy resin d is at least one in following several epoxy resin: 4,5-epoxide ring ethane-1,2-dioctyl phthalate 2-glycidyl ester, bisphenol-f type glycidyl ether type epoxy resin or bisphenol A-type glycidyl ether type epoxy resin;
Described high temperature resistant weathering performance composition epoxy resin manufacture method is as follows: comprise the following steps: step (1), by part epoxy resin c and d in component A below 30 DEG C with the speed mechanical dispersed with stirring 5-10 minute of 800-1000 rev/min; Step (2), add diluent and coupling agent successively while stirring, stand-by with left at room temperature after the speed mechanical dispersed with stirring 5-10 of 800-1000 rev/min minute; Step (3), by composition amine curing agent a and b in B component at room temperature with the speed mechanical dispersed with stirring 5-10 minute of 600-800 rev/min; Step (4), adding promoter, primary antioxidant and aid anti-oxidants while stirring, at room temperature with the speed mechanical dispersed with stirring 5-10 minute of 600-800 rev/min; Step (5), at room temperature by component A and B component mixing, with the speed mechanical dispersed with stirring 3-5 minute of 3000-3500 rev/min; Namely high temperature resistant weathering performance composition epoxy resin is obtained after step (6), vacuum defoamation;
Step 4, after impregnation, glass fibre is outer at carbon fiber core by being wound around district (6) voluble wrapping, and one-sided thickness is 0.5mm-2mm, and speed of wrap is by Serve Motor Control and pultrusion speed synchronised;
Step 5, carbon fiber complex core by the second curing oven (7), regulates temperature to make both fully solidifications together with after glass fibre protective layer compound;
Step 6, composite material cable core goods, by after hauling machine (8), are collected at closed reel (9) place;
Amine curing agent described in described protective layer (13) is the combination of amine curing agent a and amine curing agent b, and the mass ratio of amine curing agent a and amine curing agent b is: 20-40:5-25; Described amine curing agent a is the polyether monoamine compound comprising two or more amido functional groups, is selected from: molecular weight ranges 200-2500, one or more in the polyether monoamine compound of 25 DEG C of range of viscosities: 5-300mPas; Described amine curing agent b is one or more of aliphat amine and modified aliphatic aminated compounds, is selected from: one or more in diethylenetriamine, triethylene tetramine, TEPA, diamines, methylol ethylenediamine, methylol diethylenetriamine, beta-hydroxyethyl ethylenediamine; Described in described protective layer (13), coupling agent is the silane coupling agent comprising epoxy functionality; Elect gamma-aminopropyl-triethoxy-silane as, the one in γ-glycidyl ether oxygen propyl trimethoxy silicane or γ-(methacryloxy) propyl trimethoxy silicane; Inorganic filler in described load-bearing core (12) is selected from: one or more in calcium carbonate, diatomite, bentonite, talcum powder.
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CN201510552794.7A Withdrawn CN105244116A (en) | 2013-02-05 | 2013-02-05 | Cable wire manufacturing method |
CN201510552859.8A Pending CN105199316A (en) | 2013-02-05 | 2013-02-05 | Manufacturing method for carbon fiber composite material cable |
CN201310044263.8A Active CN103093896B (en) | 2013-02-05 | 2013-02-05 | A kind of manufacture method of carbon fiber composite material cable wire |
CN201510549107.6A Pending CN105374466A (en) | 2013-02-05 | 2013-02-05 | Cable making method |
CN201510549544.8A Pending CN105336429A (en) | 2013-02-05 | 2013-02-05 | Method for manufacturing composite-material cable |
CN201510548681.XA Pending CN105118573A (en) | 2013-02-05 | 2013-02-05 | Method of manufacturing cable with good anti-ultraviolet performance |
CN201510549159.3A Pending CN105118574A (en) | 2013-02-05 | 2013-02-05 | Manufacturing method for cable with excellent heatproof and mechanical properties |
CN201510549516.6A Pending CN105118576A (en) | 2013-02-05 | 2013-02-05 | Manufacturing method of composite-material-based cable |
CN201510549295.2A Withdrawn CN105118575A (en) | 2013-02-05 | 2013-02-05 | Manufacturing method of carbon-fiber-contained composite material cable |
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CN201310044263.8A Active CN103093896B (en) | 2013-02-05 | 2013-02-05 | A kind of manufacture method of carbon fiber composite material cable wire |
CN201510549107.6A Pending CN105374466A (en) | 2013-02-05 | 2013-02-05 | Cable making method |
CN201510549544.8A Pending CN105336429A (en) | 2013-02-05 | 2013-02-05 | Method for manufacturing composite-material cable |
CN201510548681.XA Pending CN105118573A (en) | 2013-02-05 | 2013-02-05 | Method of manufacturing cable with good anti-ultraviolet performance |
CN201510549159.3A Pending CN105118574A (en) | 2013-02-05 | 2013-02-05 | Manufacturing method for cable with excellent heatproof and mechanical properties |
CN201510549516.6A Pending CN105118576A (en) | 2013-02-05 | 2013-02-05 | Manufacturing method of composite-material-based cable |
CN201510549295.2A Withdrawn CN105118575A (en) | 2013-02-05 | 2013-02-05 | Manufacturing method of carbon-fiber-contained composite material cable |
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CN113278179B (en) * | 2021-05-21 | 2022-08-12 | 四川东材科技集团股份有限公司 | High-temperature-resistance epoxy glass fiber insulating layer, molded part and preparation method thereof |
CN113278180B (en) * | 2021-05-21 | 2022-08-12 | 四川东材科技集团股份有限公司 | High-temperature-resistance epoxy carbon fiber insulating layer, molded part and preparation method thereof |
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CN105118576A (en) | 2015-12-02 |
CN105118574A (en) | 2015-12-02 |
CN105118575A (en) | 2015-12-02 |
CN105336429A (en) | 2016-02-17 |
CN103093896B (en) | 2016-08-03 |
CN105118573A (en) | 2015-12-02 |
CN105199316A (en) | 2015-12-30 |
CN103093896A (en) | 2013-05-08 |
CN105374466A (en) | 2016-03-02 |
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