CN1482148A - Manufacturing method of fusible polyacrylonitrile resin - Google Patents
Manufacturing method of fusible polyacrylonitrile resin Download PDFInfo
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- CN1482148A CN1482148A CNA021369550A CN02136955A CN1482148A CN 1482148 A CN1482148 A CN 1482148A CN A021369550 A CNA021369550 A CN A021369550A CN 02136955 A CN02136955 A CN 02136955A CN 1482148 A CN1482148 A CN 1482148A
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Abstract
The preparation of fusible polyacrylonitrile resin adopts water as medium for suspension polymerization, acrylonitrile and crotononitrile in the amount of 10-15 wt% as monomer to be copolymerized, monomer feeding density of 10-50 wt%, reaction temperature 50-100 deg.c and reaction time 1-20 hr. Crotononitrile used as copolymerized monomer has one more methylene group than acrylonitrile and thus can damage the hexatomic ring structure formed with adjacent acrylonitrile monomer and lower the ring forming probability in the molecular chain. In addition, the two kinds of unsaturated olefine monomer with cyano group have very high compatibility and near reactivity ratio, and this results in the easy control of reaction, fusible polymer for fusion processing and fusion spinning to produce polyacrylonitrile fiber. The addition of the copolymerized component has no influence to the spinning performance and the physical performance of fiber.
Description
Technical field
The present invention relates to a kind of manufacture method of high molecular polymer, particularly polymerization single polymerization monomer is the manufacture method of the high molecular polymer of third rare nitrile.
Background technology
Polyacrylonitrile resin is the wider superpolymer of a kind of purposes, and particularly the fibre property of acrylic resin manufacturing exactly likes wool, occupies very big proportion in the synthon production.But a defective of polyacrylonitrile resin is a fusing point (theoretical value is 319 ℃) is higher than decomposition temperature (being generally 250 ℃), therefore it can't be processed with the fused method, polyacrylonitrile fibre also can only be used the method manufacturing of solvent spinning usually, this spinning processes will use a large amount of poisonous and harmfuls or mordant solvent, must carry out the recovery and the purification of solvent in process of production, and must wash and drying etc. fiber, so complex process and environmental pollution are serious.
For many years, reduce the research of polyacrylonitrile fusing point and quite paid close attention to, and obtained gratifying progress.In prior art, more in the past is to adopt the water plasticising method of (comprising low molecular solvent plasticising), water or other low molecular solvent can make this mixture be molten state under lower temperature after polyacrylonitrile resin is soaked into, but when adopting this kind method to carry out melt-spinning, easily produce cavity filament, fracture of wire, lousiness, fiber also can exist internal capillary and surface imperfection, thereby causes fibre property to descend greatly, so also there is more problem in suitability for industrialized production.
Become the focus of exploitation fusible polyacrylonitrile resin in recent years as the chemical modification method of non-plasticizing, it is to introduce the comonomer that can form flexible chain on the polyacrylonitrile macromolecular chain, by the sequential structure of control multipolymer and the fusing point that molecular weight reduces polyacrylonitrile, to make fusible polyacrylonitrile resin.Chinese patent 94118175.8 and 94118177.4 has proposed to prepare with methacrylonitrile and acrylonitrile compolymer and methacrylonitrile, ethylenically unsaturated monomer and acrylonitrile compolymer the method for the polyacrylonitrile of melt-processable respectively, provided the fusion moment of torsion of product under 200 ℃ in the application documents, the not play-by-play of other performance.
We know, acrylonitrile unit is joined in mode end to end in the polyacrylonitrile macromolecular chain, and this makes and easily forms the cyclic amidino compound when polyacrylonitrile is heated between link units.Simultaneously, polyacrylonitrile side group CN polarity owing to molecular chain in heat-processed is bigger, make intermolecular reactive force very strong, when the energy of external force also is not enough to overcome the intermolecular time spent of doing, the primary valence chain of macromolecular chain is earlier destroyed before a part of fusion, produce thermolysis, it is generally acknowledged that this is the basic reason that the polyacrylonitrile resin fusing point is higher than decomposition temperature.Second comonomer that fusible polyacrylonitrile resin adopted that existing chemical modification method makes fails to address this problem from structure, therefore can not obtain very ideal effect when being used for melt-spinning manufactured polyacrylonitrile fibre.
Summary of the invention
The invention provides a kind of method of new employing chemical modification manufactured fusible polyacrylonitrile resin, technical problem to be solved is that second comonomer that adopts can reduce in the polyacrylonitrile molecular chain probability of Cheng Huan between link units, the resin that makes has tangible fusing point, has good flowing property after the heating, applicable to general melt-processed and melt-spinning.
Below be the technical scheme that the present invention solves the problems of the technologies described above:
A kind of manufacture method of fusible polyacrylonitrile resin, it is that medium carries out suspension polymerization that this method adopts water, polymerization single polymerization monomer is the third rare nitrile and the second comonomer crotononitrile, the content of crotononitrile is 10~15wt% in the monomer total amount, monomeric input concentration is 10~50wt%, and temperature of reaction is 50~100 ℃, and the reaction times is 1~20 hour, the initiator that reaction is used is water miscible oxygenant and/or reductive agent, and the chain-transfer agent of molecular weight of being used to adjust is thio-alcohol and different alkanols compound
Above-mentioned monomeric input concentration is preferably 20~30wt%; Temperature of reaction is preferably 70~80 ℃; Reaction times is preferably 3~6 hours; Oxygenant can be Potassium Persulphate, ammonium persulphate, sodium chlorate or hydrogen peroxide usually in the initiator that reaction is used, and reductive agent can be Sodium Pyrosulfite, S-WAT or sodium bisulfite usually; Chain-transfer agent can be Virahol and dodecyl mercaptans usually.
The polyacrylonitrile resin that obtains generally no longer needs other to improve the second flexible monomer when being used to make polyacrylonitrile fibre, but in order to obtain good dyeing behavior, the 3rd monomer that is used for dyeing, modifying will need.Therefore, above-mentioned polymerization single polymerization monomer can be third rare nitrile, the second comonomer crotononitrile and the rare sodium sulfonate of the 3rd comonomer methyl-prop, and the content of the rare sodium sulfonate of methyl-prop is 0.2~1.0wt% in the monomer total amount.
Usually temperature of reaction is 50~100 ℃, and the temperature height helps the raising of reaction conversion ratio, but too high, wastes energy.Preferably should be controlled at 70~80 ℃.Monomeric input concentration generally can be 10~50wt%, higher monomer concentration helps the raising of reaction conversion ratio, but too high input concentration can make the viscosity of reaction system become big, and is mobile poor, operational difficulty is so best input concentration is 20~30wt%.
The add-on of initiator can be decided according to processing requirement, and weight ratio general and the monomer total amount is (0.05~10): 100, be preferably (0.5~1.5): 100.The chain-transfer agent add-on also is decided by processing requirement, and weight ratio general and the monomer total amount is (0.02~10): 100, be preferably (2.0~4.0): 100.In copolyreaction, can also add necessary auxiliary agent or additive, for example other properties-correcting agent such as light-colored agent, stablizer, antioxidant, delustering agent.These aspects are all basic identical with general polyacrylonitrile polymerization technique, should be the present technique field and know.
The slurries that polyreaction obtains after filtration, washing, drying, just obtain white granular or Powdered acrylic resin product.
Selecting crotononitrile for use is key point of the present invention as the modified copolymer monomer of polyacrylonitrile, because crotononitrile has been Duoed a methylene than third rare nitrile, destroy it and adjacent third rare nitrile unit forms the structure of six-ring, thereby reduced in the whole polyacrylonitrile molecular chain probability of Cheng Huan between link units.In addition, comonomer all is ethylenic unsaturation hydrocarbon monomers of cyano-containing, so both consistencies are very good, and the reactivity ratio of copolyreaction is close, and reaction is control easily.The polymkeric substance melt-processable that obtains, or with melt-spinning manufactured polyacrylonitrile fibre, can not influence the physicals of spinning properties and fiber because of the adding of copolymerization component.
Embodiment [embodiment 1~7]
In the reactor that has reflux exchanger, electric mixer and electric heating temperature controller, be that medium carries out suspension polymerization with water.Drop into vinyl cyanide/crotononitrile mix monomer by the composition in the table 1 in the mode that drips charging, monomer feed concentration is 30%, the add-on of oxygenant ammonium persulphate is that the weight ratio of oxygenant and monomer total amount is 1: 100 in the initiator, reductive agent Sodium Pyrosulfite add-on is that the weight ratio of reductive agent and monomer total amount is 1: 100, according to the molecular weight of product requirement, add an amount of molecular weight regulator Virahol.Temperature of reaction is 75 ℃, after 3 hours reaction mixture is filtered, washs, then in vacuum drying oven in 80 ℃ dry 10 hours down, obtain white powder acrylic resin product.
The viscosity-average molecular weight and the fusing point that obtain the acrylic resin product are listed in table 2, and fusing point is measured with the micro-thermal analyzer of WRX-1S, are fusing point with the temperature during the whole fusion of polymkeric substance on the instrument.Viscosity-average molecular weight adopts Ubbelohde viscometer to measure specific viscosity η
Sp, obtain by conversion then.Table 1.
Table 2.
Crotononitrile content (wt%) in the monomer total amount | |
Embodiment 1 | ????10 |
Embodiment 2 | ????12 |
Embodiment 3 | ????13 |
Embodiment 4 | ????14 |
Embodiment 5 | ????15 |
Embodiment 6 | ????15 |
Embodiment 7 | ????15 |
Viscosity-average molecular weight (* 10 4) | Fusing point (℃) | |
Embodiment 1 | ?????3.83 | ????245 |
Embodiment 2 | ?????3.07 | ????238 |
Embodiment 3 | ?????3.12 | ????231 |
Embodiment 4 | ?????3.98 | ????225 |
Embodiment 5 | ?????3.55 | ????221 |
Embodiment 6 | ?????2.10 | ????205 |
Embodiment 7 | ?????5.85 | ????270 |
Because other parts are basic identical with the manufacturing of general polyacrylonitrile in the polymerization technique, this knows for those skilled in the art's right and wrong Changshu, so embodiment is no longer enumerated respectively this.
Claims (7)
1, a kind of manufacture method of fusible polyacrylonitrile resin, it is that medium carries out suspension polymerization that this method adopts water, polymerization single polymerization monomer is the third rare nitrile and the second comonomer crotononitrile, the content of crotononitrile is 10~15wt% in the monomer total amount, monomeric input concentration is 10~50wt%, temperature of reaction is 50~100 ℃, reaction times is 1~20 hour, the initiator that reaction is used is water miscible oxygenant and/or reductive agent, and the chain-transfer agent of molecular weight of being used to adjust is thio-alcohol and different alkanols compound.
2, the manufacture method of fusible polyacrylonitrile resin according to claim 1 is characterized in that described monomeric input concentration is 20~30wt%.
3, the manufacture method of fusible polyacrylonitrile resin according to claim 1 is characterized in that in described temperature of reaction be 70~80 ℃.
4, the manufacture method of fusible polyacrylonitrile resin according to claim 1 is characterized in that in the described reaction times be 3~6 hours.
5, the manufacture method of fusible polyacrylonitrile resin according to claim 1, it is characterized in that oxygenant is Potassium Persulphate, ammonium persulphate, sodium chlorate or hydrogen peroxide in described initiator, reductive agent is Sodium Pyrosulfite, S-WAT or sodium bisulfite.
6, the manufacture method of fusible polyacrylonitrile resin according to claim 1 is characterized in that at described chain-transfer agent be Virahol and dodecyl mercaptans.
7, according to the manufacture method of claim 1,2,3,4,5 or 6 described fusible polyacrylonitrile resins, it is characterized in that at described polymerization single polymerization monomer be third rare nitrile, the second comonomer crotononitrile and the rare sodium sulfonate of the 3rd comonomer methyl-prop, the content of the rare sodium sulfonate of methyl-prop is 0.2~1.0wt% in the monomer total amount.
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CNB021369550A CN1181115C (en) | 2002-09-12 | 2002-09-12 | Manufacturing method of fusible polyacrylonitrile resin |
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CNB021369550A CN1181115C (en) | 2002-09-12 | 2002-09-12 | Manufacturing method of fusible polyacrylonitrile resin |
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CN1181115C CN1181115C (en) | 2004-12-22 |
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Granted publication date: 20041222 Termination date: 20100912 |