CN1990542A - Halogen-free phosphide-free flame resisting thermosetting macromolecule material composition - Google Patents
Halogen-free phosphide-free flame resisting thermosetting macromolecule material composition Download PDFInfo
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Abstract
The invention discloses a halogen- free and phosphorous- free epoxy resin combination, which can reach to UL- 94 Vo inflambility. The combination comprises: an epoxy resin, a sclerosing agent, a coupling agent, a catalyst and an inprganic burning resistance powder. The burning resistance powder comprises modified aluminum hydroxide. The combination can be used for circuit preparation or preparing material that demands UL- 94 Vo inflambility and high glass transmission point (TG).
Description
Technical field
The invention relates to a kind of resin combination with difficult combustion grade UL-94V0 and high Tg, it can apply to circuit board making.
Background technology
Traditional incombustible agent is nothing more than adding halogenide, phosphide or metal derivative as incombustible agent.Yet halogenide is poisoned the destiny of considering to have faced down comprehensive forbidding because can produce the material that poisons human body in the time of incendiary based on environmental protection.And the interpolation regular meeting of phosphide causes the decline of material character such as water-absorbent sheet material tolerance etc., also can cause the pollution of water resources simultaneously in the waste process.Therefore present incombustible agent replacement scheme is to reach difficult combustion effect with higher inorganic incombustible agent powder addition.But bigger inorganic incombustible agent addition can cause inorganic incombustible agent powder to be difficult for being dispersed in resin combination, and thereby the rubber water (varnish) that causes being prepared inorganic incombustible agent powder free settling is arranged, and the problem that reduces of the mechanical properties behind the rubber water hardening.
Beijing University of Chemical Technology is old to be built people such as peak and delivered superfine modified aluminium hydroxide and preparation method thereof (WO02094715) in 2002, is to be raw material with saturated sodium aluminate aqueous solution, feeds CO in supergravity reactor
2Criticize formula chemical reaction preparation nano-aluminum hydroxide powder earlier, carry out modified-reaction with oxalic acid or oxalate again, the modified aluminium hydroxide superfine powder that is obtained, its heat decomposition temperature is risen near 270~300 ℃ 230~235 ℃ of scopes by the heat decomposition temperature of original unmodified aluminium hydroxide, so improved the application potential of aluminium hydroxide as the inorganic no-halogen incombustible agent greatly.
Japanese Patent JP2002226558 has disclosed the substrate preparation method that reaches the anti-combustion of non-halogen non-phosphate UL-94V0 with the interpolation of aluminium hydroxide, its mode is to reach with the addition of two kinds of different hydro aluminum oxide, in detail the preparation method is prepared into middle layer film (prepreg) for the rubber water that the resin compound that contains promise Buddhist clarke (Novolac) the type novolac epoxy that is dipped in per 100 weight parts and promise Buddhist clarke (Novolac) type resol stiffening agent with glass cloth is added with the aluminium hydroxide of 200~300 weight parts, containing with glass cloth and to be dipped in the rubber water that per 100 parts by weight of epoxy resin are added with the aluminium hydroxide of 30~100 weight parts and to be prepared into outer film, is circuit substrate with the arrangement mode hot compacting of sandwich.Its flame retardancy can reach UL-94 V0, and welding thermotolerance test aspect display base plate can be 260 ℃ of tin stove plate bursting test tolerances 180 seconds after 2 hours via pressure cooker water absorption test (PCT).
Japanese Patent JP2000313738 has disclosed the preparation method who reaches the substrate of the anti-combustion of non-halogen non-phosphate UL-94 V0 with the interpolation of aluminium hydroxide, the novolac epoxy that comprises promise Buddhist clarke (Novolac) type that uses per 100 weight parts is added with the aluminium hydroxide greater than 150 weight parts, and the rubber water of poly-triphenol methane (polytriphenolmethane) stiffening agent.
More than two pieces of Japanese Patents use high-load aluminium-hydroxide powder, inevitably have the problem that inorganic incombustible agent powder is difficult for being dispersed in resin combination and causes the rubber water of being prepared to have the mechanical properties behind inorganic incombustible agent powder free settling and the rubber water hardening to reduce.
Summary of the invention
A main purpose of the present invention is to propose the thermosetting macromolecule material compositions that a kind of halogen that does not have background skill shortcoming does not have phosphide tool flame retardancy.
The thermosetting macromolecule material that the present invention selectes is promise Buddhist clarke (Novolac) type novolac epoxy, utilize the modified aluminium hydroxide powder incombustible agent collocation inorganic incombustible agent powder commonly used of high temperature resistant type, finish the rubber water prescription of favorable dispersity, finish the into film and the substrate technology of preparing on rank simultaneously.Learn from the test result of laboratory sample, all reach the demand of following Higher-Order Circuit plate in character such as flame retardancy, glass tansition temperature, water-absorbent, tin stove thermotolerances.
Outside the characteristic that is based on aforesaid macromolecular material of flame retardancy matter in the present invention, and based on the absorbed hot gas that is added and discharge the fire-retardant mode of aqueous vapor.Reduce the consumption of inorganic powder simultaneously and use modified aluminium hydroxide to suppress inorganic powder dispersed not phenomenon of good free settling in resin.Following three advantages of tool of the present invention: (1) inorganic incombustible agent powder commonly used can stop that the transmission of heat, the non-flame properties coke layer that penetrates and form of minimizing inflammable gas are covered in the combustionmaterial surface.(2) the modified aluminium hydroxide powder can be high temperature resistant to just discharging the effect that aqueous vapor reaches the halogen incombustible agent greater than 300 ℃, therefore the substrate after the sclerosis can tolerate the welding test.(3), also can promote every physical properties of substrate simultaneously because inorganic powder dispersed preferable in resin.
Embodiment
Preferred embodiment of the present invention including (but not limited to):
1. a halogen does not have the thermosetting macromolecule material compositions of phosphide tool flame retardancy, comprises:
A) mixture of promise Buddhist clarke (Novolac) type novolac epoxy or itself and other Resins, epoxy;
B) epoxy resin hardener;
C) epoxy resin catalyst;
D) an inorganic powder of anti-the combustion;
It is characterized in that this inorganic powder of anti-the combustion comprises d1) modified aluminium hydroxide powder and d2) be selected from the powder of metal oxide, metal hydroxides, carbonic acid metal salt, borate metal salt and group that silicon-dioxide is formed, the composition of wherein per 100 weight parts a) and b) the weight summation use the ingredient d 1 of 50~120 weight parts) and the d2 of 20~50 weight fraction).
2. as the composition of project 1, wherein ingredient d 1) the modified aluminium hydroxide powder be size (particlesize) between 0.2~1 μ m and the aluminium-hydroxide powder of aluminum hydroxide grain size (grain size) between 40~80nm carry out the functionalization and modification reaction winner of institute with organic dibasic acid or its dibasic acid anhydride.
3. as the composition of project 2, aluminum hydroxide grain wherein has bayerite (bayerite), boemite or pseudoboemite crystal formation.
4. as the composition of project 2, wherein this organic dibasic acid or its dibasic acid anhydride are oxalic acid, propanedioic acid, maleic acid, MALEIC ANHYDRIDE MIN 99.5, FUMARIC ACID TECH GRADE, oxysuccinic acid, succsinic acid, tartrate, pentanedioic acid, hexanodioic acid, citric acid, m-phthalic acid, phthalic acid, Tetra hydro Phthalic anhydride or terephthalic acid.
5. as the composition of project 2, wherein this functionalization and modification is reflected in the water and carries out, the carboxylic-acid functional base of this organic dibasic acid or its dibasic acid anhydride is 0.1~2 to the mol ratio of aluminium hydroxide, this organic dibasic acid or its dibasic acid anhydride and the total concn of aluminium hydroxide in water are 2~40 weight %, the functionalization and modification temperature of reaction is between 100~300 ℃, and between 0.5~5 hour functionalization and modification reaction times.
6. as the composition of project 1, wherein ingredient d 2) be barium titanium oxide (barium titanium oxide), silicon-dioxide (silica), titanium dioxide (titanium oxide), magnesium hydroxide (magnesium hydroxide) or zinc carbonate (zinc carbonate).
7. as the composition of project 1, wherein composition a) comprises and is selected from bisphenol A epoxide resin (bisphenol Aepoxy resin), bisphenol F epoxy resin (bisphenol F epoxy resin), promise Buddhist clarke type cresoform Resins, epoxy (cresol-formaldehyde novolac epoxy resin), promise Buddhist clarke type phenol formaldehyde Resins, epoxy (phenol-formaldehyde novolac epoxy resin), the two phenyl aldehyde Resins, epoxy (phenol biphenyl-formaldehyde novolac epoxy resin) of promise Buddhist clarke type phenol, promise Buddhist clarke type phenol p-Xylol formaldehyde Resins, epoxy (phenol p-xylene formaldehyde novolac epoxy resin), the inferior diphenylmethyl formaldehyde epoxy resin (phenol biphenylene formaldehyde novolac epoxy resin) of promise Buddhist clarke type phenol, promise Buddhist clarke type phenol Dicyclopentadiene (DCPD) formaldehyde Resins, epoxy (phenol dicyclopentadiene formaldehydenovolac epoxy resin) is formed one or more Resins, epoxy of group, and wherein at least a is promise Buddhist clarke type novolac epoxy.
8. as the composition of project 7, wherein composition is a promise Buddhist clarke type phenol formaldehyde Resins, epoxy a), or the mixture of promise Buddhist clarke type phenol formaldehyde Resins, epoxy and bisphenol A epoxide resin, wherein promise Buddhist clarke type phenol formaldehyde Resins, epoxy accounts for 60~80 weight % of this mixture and 20~40 weight % that this bisphenol A epoxide resin accounts for this mixture.
9. as the composition of project 1, composition b wherein) epoxy resin hardener is a promise Buddhist clarke type Cresol Formaldehyde Resin (cresol-formaldehyde novolac resin), promise Buddhist clarke type fluosite (phenol-formaldehyde novolac resin), the two phenyl aldehyde resins (phenolbiphenyl-formaldehyde novolac resin) of promise Buddhist clarke type phenol, promise Buddhist clarke type phenol p-Xylol formaldehyde resin (phenolp-xylene formaldehyde novolac resin), the inferior phenylbenzene formaldehyde fat (phenolbiphenylene formaldehyde novolac resin) of promise Buddhist clarke type phenol, promise Buddhist clarke type phenol Dicyclopentadiene (DCPD) formaldehyde resin (phenol dicyclopentadiene formaldehyde novolac resin), trimeric cyanamide fluosite (melamine phenol-formaldehyde novolac resin).
10. the functional group of epoxy resin hardener as the composition of project 1, composition b wherein) and the mole ratio of composition epoxy group(ing) a) are 1.
11. composition as project 1, composition c wherein) epoxy resin catalyst is methylimidazole (2-methylimidazole), diethyl tetramethyl-imidazoles (2-ethyl-4-methylimidazole), diphenyl-imidazole (2-phenyl imidazole), dimethylamino ethyl phenol (dimethylamino ethyl phenol), three (dimethylamino methyl) phenol (tris (dimethylaminomethyl) phenol), or benzyl dimethyl amine (benzyldimethylamine), and the composition of per 100 weight parts a) and b) the weight summation use the composition c of 0.01~2.0 weight part).
More than described to have bayerite (bayerite), boemite or pseudoboemite crystal formation aluminium-hydroxide powder be prepared via a kind of preparation method of crystal formation of may command aluminum hydroxide grain as project 3, comprise the novel supergravity reactor that uses this case applicant to be disclosed in the novel patent 205722 of TaiWan, China (Chinese novel patent 598954), the content of this patent is merged in this case in the reference mode.This method comprises sodium aluminate (NaAlO
2) aqueous solution and Tai-Ace S 150 (Al
2(SO
4)
3) aqueous solution injects this novel super gravity field reactor simultaneously and carries out following liquid-phase chemical reaction:
6NaAlO
2+ Al
2(SO
4)
3+ 12H
2O → 8Al (OH)
3+ 3Na
2SO
4And
Collect the reaction product slurry that is obtained;
The pH value and the temperature of the slurry that adjustment is collected have the aluminum hydroxide grain that is selected from one of bayerite (bayerite), boemite or pseudoboemite crystal formation with formation.
This sodium aluminate and aluminum sulfate aqueous solution concentration are between 0.1~1N, and the temperature of reaction in this super gravity field reactor 100 is between 30~80 ℃, and the G value of super gravity field is between 90~200.Between the pH value of the reaction product slurry in this Receiving bin 50 is controlled in 9~11 and temperature be controlled in and can obtain bayerite (bayerite) crystal formation between 30~80 ℃, temperature is controlled between 30~80 ℃ and can obtains the pseudo-boehmite crystal formation between the pH value is controlled in 6~9.If between the pH value is controlled in 7~9 and temperature be controlled between 80~150 ℃ then can obtain the boehmite crystal formation.
With the 5 described aluminum hydroxide grains after carboxylic acid functionalized modification of beginning a project, initial weightless temperature of its thermolysis and fierce weightless temperature all have tangible rising.If bayerite (bayerite) crystal formation can rise to 270~300 ℃ for 120~235 ℃ by the original not initial weightless temperature of thermolysis of functionalized aluminium hydroxide.
The present invention can further be understood by the following example, and these but not are used to limit the scope of the invention as illustrative purposes only.
The employed super gravity field reactor of the present invention of following examples, 6 on wire netting leaf with 60~80 meshes, the length of blade radial is 4cm, axial height is 2cm; And the inside and outside footpath of reactor is respectively 2cm and 4cm, and axial height is 2cm.
Embodiment
The preparation of the aluminum hydroxide grain of preparation example 1. several different crystal forms
0.25N sodium aluminate aqueous solution, its pH value>11,70 ℃ of temperature, about 0.8 liter/minute of flow, with the 0.25N aluminum sulfate aqueous solution, it is acid that its pH value is, and 50 ℃ of temperature are imported into the charging spout of super gravity field reactor, and the reactor rotating speed is 1800rpm.
I) preparation pseudo-boehmite aluminium hydroxide:
Adjust aluminum sulfate aqueous solution flow (about 0.6 LPM (Liters Per Minute) of flow), make the pH of the slurry in the Receiving bin 50 maintain 6.5 and temperature maintenance at 70 ℃.Filtration is by Receiving bin 50 effusive slurries and wash resultant aluminium hydroxide powder filter cake.With X ray coiling (XRD) analysed for powder, find out the wide ripple of its signal wave crest engrail by XRD spectrum, be atypic pseudo-boehmite crystal formation therefore, its grain size is through calculating about 35~45nm.By this aluminium hydroxide powder of electron microscope observation, it is 30~60nm spherical granules.
Ii) prepare boehmite crystal formation aluminium hydroxide:
Preparation procedure is with above-mentioned i), just the temperature of the slurry in the Receiving bin 50 is maintained at 160 ℃, and pH maintains 9.Product obtains the aluminium hydroxide powder filter cake with washing and filtration.With X ray coiling (XRD) analysed for powder, find out that by XRD spectrum it is the boehmite crystal formation, its grain size is through calculating about 35~45nm.
Iii) prepare gibbsite (bayerite) crystal formation aluminium hydroxide:
Preparation procedure is with above-mentioned i), just adjust aluminum sulfate aqueous solution flow (about 0.4 liter/minute of flow), and make the pH of the slurry in the Receiving bin 50 maintain 9.Survey the particle diameter (particle size) that the particle diameter instrument is measured the aluminium hydroxide powder that is obtained with dynamic laser light scattering method (DLS), obtain the about 209nm of D50.Learn that by its XRD figure spectrum it is the bayerite crystal formation again, this bayerite crystal formation aluminum hydroxide grain size (grainsize) is through calculating about 35~45nm.
2. pairs of preparation examples 1 of preparation example bayerite crystal formation aluminium hydroxide (iii) carries out functional group's modification at reactor 70 with oxalic acid, the preparation example 1 of 100g bayerite crystal formation aluminium hydroxide powder filter cake (iii) adds 90g oxalic acid and 600g water, thorough mixing, carry out carboxylic-acid functional base modified-reaction, 1 hour reaction times in 150~160 ℃.After the product filtration washing that is obtained, analyze with TGA, the result is for being 1 weight % at 80~240 ℃ of its thermal weight losses, and fierce weightless temperature begins near 370 ℃, its thermal weight loss reaches 45 weight % near 430 ℃, be higher than 500 ℃ after its thermal weight losses ease up.Powder sample is with the XRD instrumental analysis after the modification, it is that 4.727,6.512 and 3.733 have the diffraction peak that its XRD spectrum is presented at the D value, its 2 θ angle is respectively 18.758,13.588 and 23.817, is respectively 32.98% and 29.96% of 2 θ angles 18.758 and be respectively 13.588 and 23.817 diffraction peak intensity at 2 θ angles.
3. pairs of preparation examples 1 of preparation example gibbsite crystal formation aluminium hydroxide (iii) carries out functional group's modification with oxalic acid
Except bayerite crystal formation aluminium hydroxide powder is the 50g by decrement, all the other experiment conditions are with preparation example 2.It is 1 weight % that the TGA analytical results of the powder sample that is obtained is presented at 80~270 ℃ of its thermal weight losses, and fierce weightless temperature begins near 385 ℃, and its thermal weight loss reaches 50 weight % near 450 ℃, be higher than 500 ℃ after its thermal weight losses reach and ease up.Powder sample is with the XRD instrumental analysis after the modification, shown in its XRD spectrum, in the D value is that 6.526,4.739 and 4.304 have the diffraction peak, its 2 θ angle is respectively 13.558,18.709 and 20.619, is respectively 30.94% and 46.60% of 2 θ angles 18.709 and be respectively 13.558 and 20.619 diffraction peak intensity at 2 θ angles.Measure bayerite crystal formation aluminium hydroxide powder and carboxylic-acid functional base modification after product sample respectively with infrared rays (IR) instrument, the result is as can be known at 1300cm
-1Near the C-O chemical bond is arranged, at 1700cm
-1Near the C=O chemical bond is arranged, at 2800~3600cm
-1Near the O-H chemical bond is arranged, so between the carboxylic-acid functional base of oxalic acid and the bayerite crystal formation aluminium hydroxide chemical bonded refractory is arranged.
Preparation example 4: preparation example 1 bayerite crystal formation aluminium hydroxide is (iii) carried out functional group's modification with hexanodioic acid
At reactor 70, the preparation example 1 of 100g bayerite crystal formation aluminium hydroxide powder filter cake (iii) adds 73g hexanodioic acid and 1000g water, thorough mixing, carries out carboxylic-acid functional base modified-reaction, 2 hours reaction times in 160 ℃.After the product filtration washing that is obtained, analyze with TGA, it is 2 weight % (unmodified before thermal weight loss are 10 weight %) that the result is presented at 80~260 ℃ of its thermal weight losses, and fierce weightless temperature begins near 380 ℃, and its thermal weight loss reaches 60 weight % near 530 ℃.
5. pairs of preparation examples 1 of preparation example bayerite crystal formation aluminium hydroxide (iii) carries out functional group's modification with FUMARIC ACID TECH GRADE
At reactor 70, the preparation example 1 of 16g bayerite crystal formation aluminium hydroxide powder filter cake (iii) adds 24g FUMARIC ACID TECH GRADE and 300g water, thorough mixing, carries out carboxylic-acid functional base modified-reaction, 2 hours reaction times in 150~160 ℃.After the product filtration washing that is obtained, analyze with TGA, the result shows, at 80~247 ℃ of its thermal weight losses is 1 weight %, fierce weightless temperature begin near 460 ℃, and its thermal weight loss reaches 53 weight % near 600 ℃, is higher than 600 ℃ of later its thermal weight losses and reaches and ease up.Powder sample is with the XRD instrumental analysis after the modification, shown in its XRD spectrum, in the D value is that 8.42035,4.22882 and 2.82229 have the diffraction peak, its 2 θ angle is respectively 10.498,20.991 and 31.678, is respectively 16.37% and 13.07% of 2 θ angles 10.498 and be respectively 20.991 and 31.678 diffraction peak intensity at 2 θ angles.Carry out product sample behind functional group's modified-reaction with IR apparatus measures bayerite crystal formation aluminium hydroxide powder and FUMARIC ACID TECH GRADE, the result is presented at 1400cm
-1Near the C-O chemical bond is arranged, at 1600cm
-1Near the C=O chemical bond is arranged, at 1700cm
-1Near the C=C chemical bond is arranged, at 2800~3600cm
-1Near the O-H chemical bond is arranged, so between FUMARIC ACID TECH GRADE functional group and the bayerite crystal formation aluminium hydroxide chemical bonded refractory is arranged.
The pseudo-boehmite crystal formation aluminium hydroxide of 6. pairs of preparation examples 1 of preparation example (i) carries out functional group's modification with oxalic acid
At reactor 70, the pseudo-boehmite crystal formation aluminum hydroxide slurry of the preparation example 1 (i) of 580g (solid content is 7.72%) with 32g oxalic acid and 1500g water thorough mixing, carries out functional group's modification in 150 ℃ and answers 1 hour reaction times.The powder sample that is obtained is with the TGA instrumental analysis, and it is 5 weight % that the result is presented at 80~360 ℃ of its thermal weight losses, and fierce weightless temperature begins near 390 ℃, and its thermal weight loss reaches 48 weight % near 600 ℃, be higher than 600 ℃ after its thermal weight losses reach and ease up.Powder sample is with the XRD instrumental analysis after the modification, its XRD spectrum shows, in the D value is that 6.7433,4.8427 and 3.8099 have the diffraction peak, its 2 θ angle is respectively 13.1186,18.3052 and 23.3292, is respectively 20.915% and 18.301% of 2 θ angles 18.3052 and be respectively 13.1186 and 23.3292 diffraction peak intensity at 2 θ angles.
Embodiment 1 to 4:
Rubber water (Varnish) preparation process
Get the modified aluminium hydroxide powder of aforementioned preparation example 3 and commercial inorganic difficult combustion powder totally 100 grams insert in the bottle, add acetone solvent and reach an optionally coupler (referring to table one) for 100 milliliters, after stirring, add promise Buddhist clarke type phenol formaldehyde Resins, epoxy (South Asia resin limited-liability company again, code name NPCN-704) 100 gram or promise Buddhist clarke type phenol formaldehyde Resins, epoxy (South Asia resin limited-liability company, code name NPCN-704) with bisphenol A epoxide resin (Shell company, code name epikote 828) mixture 100 grams are stirred to dissolving fully, add identical normal promise Buddhist clarke type fluosite stiffening agent (Bakelite company again, code name 6000IZ) the imidazoles catalyzer (Aldrich company) with 0.05~0.1 gram is stirred to evenly, promptly get rubber water, its gel time (solution gel-time) is after tested: 300 ± 10 seconds.The meaning of gel time is the time that macromolecule mixture begins to produce crosslinking reaction.Rubber water mixed duration of service (pot life) is 7 days.Film (Prepreg) is made flow process
With glasscloth (South Asia resin limited-liability company, code name 7628) inserting in the rubber water impregnation takes out after about 20 minutes, send in 170 ℃ of Hotaircirculatingovens and toasted several minutes, control its crosslinking reaction transformation efficiency about 50% and glue impregnation amount (resin content) be 45~50% (they are benchmark with film weight), promptly get film.
Flow process is made in substrate (Laminate) pressing
With above-mentioned film with five storehouses after, respectively place the not imperial separation cloth of iron, mirror steel plate and kraft paper then up and down after, insert again in 200 ℃ and the moulding press that vacuumizes, carry out heat embrittlement pressing two hours, promptly get the substrate sample that thickness is 1.0 ± 0.02mm.
Following table one is listed every test data of substrate sample.
Table one
Embodiment 1 | Embodiment 2 | Embodiment 3 | Embodiment 4 | |
Promise Buddhist clarke type phenol formaldehyde Resins, epoxy (gram) | 60 | 60 | 60 | 100 |
Bisphenol A epoxide resin (gram) | 40 | 40 | 40 | - |
Modified aluminium hydroxide powder (gram) | 100 | 100 | 100 | 100 |
Commercial inorganic difficult combustion powder 1(gram) | 50 | 50 | 50 | 50 |
The amine coupler 2(gram) | - | 10 | - | - |
The silicane coupler 3(gram) | - | - | 3~5 | 3~5 |
The imidazoles catalyzer 4(gram) | 0.05~0.1 | 0.05~0.1 | 0.05~0.1 | 0.05~0.1 |
Glass tansition temperature Tg (℃) | 150~170 | 155~160 | 175~180 | 180~190 |
Thermal expansivity CTE (α 1;ppm) | 30~50 | 30~50 | 30~40 | 30~40 |
Pressure cooker water absorption test (PCT) (%) | 0.3~0.5 | 0.3~0.5 | 0.2~0.35 | 0.3~0.4 |
Carry out tin stove plate bursting test (second) at 288 ℃ behind the PCT test 1hr | >360s | >360s | >360s | >360s |
Thermogravimetric loss (TGA) test, the temperature of 1 weight % loss | 350~360 | 360~380 | 380~390 | 380~390 |
Combustion testing UL-94 | V0 | V0 | V0 | V0 |
1Commercial inorganic difficult combustion powder is silicon-dioxide (Changchun resin limited-liability company, code name NaLs) or magnesium hydroxide (Desunnano company, code name MDH)
2The amine coupler is three amido propyl group, three ethoxy silane (aminopropyltriethoxysilane) (UnionCarbide company, code name A-1100)
3The silicane coupler is a glycidyl oxygen propyl group trimethoxy silane
Glycidoxypropyltrimethoxysilane (Union Carbide company, code name A-187)
4The imidazoles catalyzer is methylimidazole (2-methylimidazole) (an Aldrich company)
Claims (11)
1. a halogen does not have the thermosetting macromolecule material compositions of phosphide tool flame retardancy, comprises:
A) mixture of promise Buddhist clarke (Novolac) type novolac epoxy or itself and other Resins, epoxy;
B) epoxy resin hardener;
C) epoxy resin catalyst;
D) an inorganic powder of anti-the combustion;
It is characterized in that: this inorganic powder of anti-the combustion comprises d1) modified aluminium hydroxide powder and d2) be selected from the powder of metal oxide, metal hydroxides, carbonic acid metal salt, borate metal salt and group that silicon-dioxide is formed, the composition of wherein per 100 weight parts a) and b) the weight summation use the ingredient d 1 of 50~120 weight parts) and the d2 of 20~50 weight fraction).
2. composition as claimed in claim 1, wherein ingredient d 1) the modified aluminium hydroxide powder be size between 0.2~1 μ m and the aluminium-hydroxide powder of aluminum hydroxide grain size between 40~80nm carry out the functionalization and modification reaction winner of institute with organic dibasic acid or its dibasic acid anhydride.
3. composition as claimed in claim 2, aluminum hydroxide grain wherein have bayerite (bayerite), boemite or pseudoboemite crystal formation.
4. composition as claimed in claim 2, wherein this organic dibasic acid or its dibasic acid anhydride are oxalic acid, propanedioic acid, maleic acid, MALEIC ANHYDRIDE MIN 99.5, FUMARIC ACID TECH GRADE, oxysuccinic acid, succsinic acid, tartrate, pentanedioic acid, hexanodioic acid, citric acid, m-phthalic acid, phthalic acid, Tetra hydro Phthalic anhydride or terephthalic acid.
5. composition as claimed in claim 2, wherein this functionalization and modification is reflected in the water and carries out, the carboxylic-acid functional base of this organic dibasic acid or its dibasic acid anhydride is 0.1~2 to the mol ratio of aluminium hydroxide, this organic dibasic acid or its dibasic acid anhydride and the total concn of aluminium hydroxide in water are 2~40 weight %, the functionalization and modification temperature of reaction is between 100~300 ℃, and between 0.5~5 hour functionalization and modification reaction times.
6. composition as claimed in claim 1, wherein ingredient d 2) be barium titanium oxide (barium titaniumoxide), silicon-dioxide (silica), titanium dioxide (titanium oxide), magnesium hydroxide (magnesiumhydroxide) or zinc carbonate (zinc carbonate).
7. composition as claimed in claim 1, wherein composition a) comprises and is selected from bisphenol A epoxide resin (bisphenol A epoxy resin), bisphenol F epoxy resin (bisphenol F epoxy resin), promise Buddhist clarke type cresoform Resins, epoxy (cresol-formaldehyde novolac epoxy resin), promise Buddhist clarke type phenol formaldehyde Resins, epoxy (phenol-formaldehyde novolac epoxy resin), the two phenyl aldehyde Resins, epoxy (phenol biphenyl-formaldehyde novolac epoxy resin) of promise Buddhist clarke type phenol, promise Buddhist clarke type phenol p-Xylol formaldehyde Resins, epoxy (phenol p-xylene formaldehyde novolac epoxy resin), the inferior diphenylmethyl formaldehyde epoxy resin (phenol biphenylene formaldehyde novolacepoxy resin) of promise Buddhist clarke type phenol, promise Buddhist clarke type phenol Dicyclopentadiene (DCPD) formaldehyde Resins, epoxy (phenol dicyclopentadieneformaldehyde novolac epoxy resin) is formed one or more Resins, epoxy of group, and wherein at least a is promise Buddhist clarke type novolac epoxy.
8. composition as claimed in claim 7, wherein composition is a promise Buddhist clarke type phenol formaldehyde Resins, epoxy a), or the mixture of promise Buddhist clarke type phenol formaldehyde Resins, epoxy and bisphenol A epoxide resin, wherein promise Buddhist clarke type phenol formaldehyde Resins, epoxy accounts for 60~80 weight % of this mixture and 20~40 weight % that this bisphenol A epoxide resin accounts for this mixture.
9. composition as claimed in claim 1, wherein composition b) epoxy resin hardener is promise Buddhist clarke type Cresol Formaldehyde Resin (cresol-formaldehyde novolac resin), promise Buddhist clarke type fluosite (phenol-formaldehyde novolac resin), the two phenyl aldehyde resins (phenolbiphenyl-formaldehyde novolac resin) of promise Buddhist clarke type phenol, promise Buddhist clarke type phenol p-Xylol formaldehyde resin (phenolp-xylene formaldehyde novolac resin), the inferior phenylbenzene formaldehyde fat (phenolbiphenylene formaldehyde novolac resin) of promise Buddhist clarke type phenol, promise Buddhist clarke type phenol Dicyclopentadiene (DCPD) formaldehyde resin (phenol dicyclopentadiene formaldehyde novolac resin), trimeric cyanamide fluosite (melamine phenol-formaldehyde novolac resin).
10. composition as claimed in claim 1, wherein composition b) the functional group of epoxy resin hardener and the mole ratio of composition epoxy group(ing) a) be 1.
11. composition as claimed in claim 1, composition c wherein) epoxy resin catalyst is methylimidazole (2-methylimidazole), diethyl tetramethyl-imidazoles (2-ethyl-4-methylimidazole), diphenyl-imidazole (2-phenyl imidazole), dimethylamino ethyl phenol (dimethylamino ethyl phenol), three (dimethylamino methyl) phenol (tris (dimethylaminomethyl) phenol), or benzyl dimethyl amine (benzyldimethylamine), and the composition of per 100 weight parts a) and b) the weight summation use the composition c of 0.01~2.0 weight part).
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CNB2005101352155A CN100513481C (en) | 2005-12-27 | 2005-12-27 | Halogen-free phosphide-free flame resisting thermosetting macromolecule material composition |
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CNB2005101352155A CN100513481C (en) | 2005-12-27 | 2005-12-27 | Halogen-free phosphide-free flame resisting thermosetting macromolecule material composition |
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CN100513481C CN100513481C (en) | 2009-07-15 |
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CN102532810A (en) * | 2010-12-29 | 2012-07-04 | 第一毛织株式会社 | Epoxy resin composition for encapsulating semiconductor device and semiconductor device using the same |
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CN102532810A (en) * | 2010-12-29 | 2012-07-04 | 第一毛织株式会社 | Epoxy resin composition for encapsulating semiconductor device and semiconductor device using the same |
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Effective date of registration: 20170605 Address after: Hsinchu County, Taiwan, China Co-patentee after: Changchun Petrochemical Co., Ltd. Patentee after: Industrial Technology Research Institute Address before: Taiwan County, Hsinchu, China Town, the eastern part of Zhongxing Road, No. four, No. 195 Patentee before: Industrial Technology Research Institute |
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