WO2023010323A1 - Method for preparing sucralose - Google Patents
Method for preparing sucralose Download PDFInfo
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- WO2023010323A1 WO2023010323A1 PCT/CN2021/110492 CN2021110492W WO2023010323A1 WO 2023010323 A1 WO2023010323 A1 WO 2023010323A1 CN 2021110492 W CN2021110492 W CN 2021110492W WO 2023010323 A1 WO2023010323 A1 WO 2023010323A1
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- Prior art keywords
- tower
- sucralose
- neutralization
- liquid
- reaction
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- 239000004376 Sucralose Substances 0.000 title claims abstract description 169
- 235000019408 sucralose Nutrition 0.000 title claims abstract description 169
- BAQAVOSOZGMPRM-QBMZZYIRSA-N sucralose Chemical compound O[C@@H]1[C@@H](O)[C@@H](Cl)[C@@H](CO)O[C@@H]1O[C@@]1(CCl)[C@@H](O)[C@H](O)[C@@H](CCl)O1 BAQAVOSOZGMPRM-QBMZZYIRSA-N 0.000 title claims abstract description 168
- 238000000034 method Methods 0.000 title claims abstract description 69
- 238000006386 neutralization reaction Methods 0.000 claims abstract description 145
- 239000007788 liquid Substances 0.000 claims abstract description 140
- 238000000605 extraction Methods 0.000 claims abstract description 132
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims abstract description 132
- 238000006460 hydrolysis reaction Methods 0.000 claims abstract description 113
- 238000005660 chlorination reaction Methods 0.000 claims abstract description 105
- 238000002425 crystallisation Methods 0.000 claims abstract description 73
- 230000008025 crystallization Effects 0.000 claims abstract description 72
- 239000007864 aqueous solution Substances 0.000 claims abstract description 66
- 239000000243 solution Substances 0.000 claims abstract description 60
- 238000007254 oxidation reaction Methods 0.000 claims abstract description 56
- 230000003647 oxidation Effects 0.000 claims abstract description 52
- 239000003513 alkali Substances 0.000 claims abstract description 32
- 238000000746 purification Methods 0.000 claims abstract description 27
- 238000001704 evaporation Methods 0.000 claims abstract description 12
- 230000008020 evaporation Effects 0.000 claims abstract description 11
- 239000002699 waste material Substances 0.000 claims abstract description 9
- 238000005904 alkaline hydrolysis reaction Methods 0.000 claims abstract description 7
- 239000011877 solvent mixture Substances 0.000 claims abstract description 4
- XEKOWRVHYACXOJ-UHFFFAOYSA-N Ethyl acetate Chemical compound CCOC(C)=O XEKOWRVHYACXOJ-UHFFFAOYSA-N 0.000 claims description 168
- HEMHJVSKTPXQMS-UHFFFAOYSA-M Sodium hydroxide Chemical compound [OH-].[Na+] HEMHJVSKTPXQMS-UHFFFAOYSA-M 0.000 claims description 168
- 238000004821 distillation Methods 0.000 claims description 90
- 235000011121 sodium hydroxide Nutrition 0.000 claims description 56
- 239000012452 mother liquor Substances 0.000 claims description 41
- 230000007062 hydrolysis Effects 0.000 claims description 40
- KWYUFKZDYYNOTN-UHFFFAOYSA-M Potassium hydroxide Chemical compound [OH-].[K+] KWYUFKZDYYNOTN-UHFFFAOYSA-M 0.000 claims description 30
- 230000003472 neutralizing effect Effects 0.000 claims description 30
- 239000012295 chemical reaction liquid Substances 0.000 claims description 28
- 238000002360 preparation method Methods 0.000 claims description 20
- 239000012074 organic phase Substances 0.000 claims description 17
- 239000003795 chemical substances by application Substances 0.000 claims description 15
- 239000003518 caustics Substances 0.000 claims description 14
- VEXZGXHMUGYJMC-UHFFFAOYSA-N Hydrochloric acid Chemical compound Cl VEXZGXHMUGYJMC-UHFFFAOYSA-N 0.000 claims description 13
- CBENFWSGALASAD-UHFFFAOYSA-N Ozone Chemical compound [O-][O+]=O CBENFWSGALASAD-UHFFFAOYSA-N 0.000 claims description 13
- QAOWNCQODCNURD-UHFFFAOYSA-N Sulfuric acid Chemical compound OS(O)(=O)=O QAOWNCQODCNURD-UHFFFAOYSA-N 0.000 claims description 12
- 239000007800 oxidant agent Substances 0.000 claims description 12
- 238000011084 recovery Methods 0.000 claims description 12
- 239000000945 filler Substances 0.000 claims description 11
- NBIIXXVUZAFLBC-UHFFFAOYSA-N Phosphoric acid Chemical compound OP(O)(O)=O NBIIXXVUZAFLBC-UHFFFAOYSA-N 0.000 claims description 10
- 239000005708 Sodium hypochlorite Substances 0.000 claims description 10
- 238000000066 reactive distillation Methods 0.000 claims description 10
- SUKJFIGYRHOWBL-UHFFFAOYSA-N sodium hypochlorite Chemical compound [Na+].Cl[O-] SUKJFIGYRHOWBL-UHFFFAOYSA-N 0.000 claims description 10
- 150000007522 mineralic acids Chemical class 0.000 claims description 7
- DKPFZGUDAPQIHT-UHFFFAOYSA-N Butyl acetate Natural products CCCCOC(C)=O DKPFZGUDAPQIHT-UHFFFAOYSA-N 0.000 claims description 5
- 229910000147 aluminium phosphate Inorganic materials 0.000 claims description 5
- FUZZWVXGSFPDMH-UHFFFAOYSA-N hexanoic acid Chemical compound CCCCCC(O)=O FUZZWVXGSFPDMH-UHFFFAOYSA-N 0.000 claims description 5
- 239000012141 concentrate Substances 0.000 claims description 4
- 230000001590 oxidative effect Effects 0.000 claims description 3
- 150000002148 esters Chemical class 0.000 abstract description 7
- 230000007935 neutral effect Effects 0.000 abstract description 5
- 239000012071 phase Substances 0.000 description 40
- 239000000463 material Substances 0.000 description 35
- 239000000047 product Substances 0.000 description 33
- ZMXDDKWLCZADIW-UHFFFAOYSA-N N,N-Dimethylformamide Chemical compound CN(C)C=O ZMXDDKWLCZADIW-UHFFFAOYSA-N 0.000 description 29
- 238000012856 packing Methods 0.000 description 29
- OKKJLVBELUTLKV-UHFFFAOYSA-N Methanol Chemical compound OC OKKJLVBELUTLKV-UHFFFAOYSA-N 0.000 description 24
- 239000002904 solvent Substances 0.000 description 21
- 230000008569 process Effects 0.000 description 20
- 238000010979 pH adjustment Methods 0.000 description 17
- WQDUMFSSJAZKTM-UHFFFAOYSA-N Sodium methoxide Chemical compound [Na+].[O-]C WQDUMFSSJAZKTM-UHFFFAOYSA-N 0.000 description 14
- FACOTAQCKSDLDE-YKEUTPDRSA-N [(2R,3R,4R,5R,6R)-6-[(2R,3S,4S,5S)-2,5-bis(chloromethyl)-3,4-dihydroxyoxolan-2-yl]oxy-3-chloro-4,5-dihydroxyoxan-2-yl]methyl acetate Chemical compound O[C@@H]1[C@@H](O)[C@@H](Cl)[C@@H](COC(=O)C)O[C@@H]1O[C@@]1(CCl)[C@@H](O)[C@H](O)[C@@H](CCl)O1 FACOTAQCKSDLDE-YKEUTPDRSA-N 0.000 description 14
- 239000012046 mixed solvent Substances 0.000 description 14
- 238000006243 chemical reaction Methods 0.000 description 13
- 239000000284 extract Substances 0.000 description 13
- 238000004065 wastewater treatment Methods 0.000 description 11
- 238000001035 drying Methods 0.000 description 10
- 239000002994 raw material Substances 0.000 description 10
- 238000000926 separation method Methods 0.000 description 10
- 239000010865 sewage Substances 0.000 description 10
- VHUUQVKOLVNVRT-UHFFFAOYSA-N Ammonium hydroxide Chemical compound [NH4+].[OH-] VHUUQVKOLVNVRT-UHFFFAOYSA-N 0.000 description 9
- 235000011114 ammonium hydroxide Nutrition 0.000 description 9
- UOCLXMDMGBRAIB-UHFFFAOYSA-N 1,1,1-trichloroethane Chemical compound CC(Cl)(Cl)Cl UOCLXMDMGBRAIB-UHFFFAOYSA-N 0.000 description 8
- 230000000694 effects Effects 0.000 description 8
- 238000004519 manufacturing process Methods 0.000 description 8
- 229910001220 stainless steel Inorganic materials 0.000 description 8
- 239000010935 stainless steel Substances 0.000 description 8
- 239000002351 wastewater Substances 0.000 description 8
- 239000012535 impurity Substances 0.000 description 7
- 238000001556 precipitation Methods 0.000 description 7
- 238000004064 recycling Methods 0.000 description 7
- 150000002895 organic esters Chemical class 0.000 description 6
- 229930006000 Sucrose Natural products 0.000 description 5
- CZMRCDWAGMRECN-UGDNZRGBSA-N Sucrose Chemical compound O[C@H]1[C@H](O)[C@@H](CO)O[C@@]1(CO)O[C@@H]1[C@H](O)[C@@H](O)[C@H](O)[C@@H](CO)O1 CZMRCDWAGMRECN-UGDNZRGBSA-N 0.000 description 5
- XKMRRTOUMJRJIA-UHFFFAOYSA-N ammonia nh3 Chemical compound N.N XKMRRTOUMJRJIA-UHFFFAOYSA-N 0.000 description 5
- 239000007789 gas Substances 0.000 description 5
- 238000004128 high performance liquid chromatography Methods 0.000 description 5
- 239000005720 sucrose Substances 0.000 description 5
- 238000012546 transfer Methods 0.000 description 5
- 239000000126 substance Substances 0.000 description 4
- QGZKDVFQNNGYKY-UHFFFAOYSA-N Ammonia Chemical compound N QGZKDVFQNNGYKY-UHFFFAOYSA-N 0.000 description 3
- 230000008901 benefit Effects 0.000 description 3
- 239000006227 byproduct Substances 0.000 description 3
- 239000003153 chemical reaction reagent Substances 0.000 description 3
- 238000004807 desolvation Methods 0.000 description 3
- IJGRMHOSHXDMSA-UHFFFAOYSA-N Atomic nitrogen Chemical compound N#N IJGRMHOSHXDMSA-UHFFFAOYSA-N 0.000 description 2
- BTBUEUYNUDRHOZ-UHFFFAOYSA-N Borate Chemical compound [O-]B([O-])[O-] BTBUEUYNUDRHOZ-UHFFFAOYSA-N 0.000 description 2
- OKTJSMMVPCPJKN-UHFFFAOYSA-N Carbon Chemical compound [C] OKTJSMMVPCPJKN-UHFFFAOYSA-N 0.000 description 2
- LFQSCWFLJHTTHZ-UHFFFAOYSA-N Ethanol Chemical compound CCO LFQSCWFLJHTTHZ-UHFFFAOYSA-N 0.000 description 2
- 239000002253 acid Substances 0.000 description 2
- 230000002378 acidificating effect Effects 0.000 description 2
- 238000010923 batch production Methods 0.000 description 2
- 230000000052 comparative effect Effects 0.000 description 2
- 239000008367 deionised water Substances 0.000 description 2
- 229910021641 deionized water Inorganic materials 0.000 description 2
- 238000010586 diagram Methods 0.000 description 2
- JKWMSGQKBLHBQQ-UHFFFAOYSA-N diboron trioxide Chemical compound O=BOB=O JKWMSGQKBLHBQQ-UHFFFAOYSA-N 0.000 description 2
- ZPWVASYFFYYZEW-UHFFFAOYSA-L dipotassium hydrogen phosphate Chemical compound [K+].[K+].OP([O-])([O-])=O ZPWVASYFFYYZEW-UHFFFAOYSA-L 0.000 description 2
- 238000005516 engineering process Methods 0.000 description 2
- 238000010812 external standard method Methods 0.000 description 2
- 239000000203 mixture Substances 0.000 description 2
- 238000005580 one pot reaction Methods 0.000 description 2
- 239000003960 organic solvent Substances 0.000 description 2
- 230000001376 precipitating effect Effects 0.000 description 2
- 238000000638 solvent extraction Methods 0.000 description 2
- FYSNRJHAOHDILO-UHFFFAOYSA-N thionyl chloride Chemical compound ClS(Cl)=O FYSNRJHAOHDILO-UHFFFAOYSA-N 0.000 description 2
- KPZGRMZPZLOPBS-UHFFFAOYSA-N 1,3-dichloro-2,2-bis(chloromethyl)propane Chemical compound ClCC(CCl)(CCl)CCl KPZGRMZPZLOPBS-UHFFFAOYSA-N 0.000 description 1
- QTBSBXVTEAMEQO-UHFFFAOYSA-M Acetate Chemical compound CC([O-])=O QTBSBXVTEAMEQO-UHFFFAOYSA-M 0.000 description 1
- 208000024172 Cardiovascular disease Diseases 0.000 description 1
- YGYAWVDWMABLBF-UHFFFAOYSA-N Phosgene Chemical compound ClC(Cl)=O YGYAWVDWMABLBF-UHFFFAOYSA-N 0.000 description 1
- PMZURENOXWZQFD-UHFFFAOYSA-L Sodium Sulfate Chemical compound [Na+].[Na+].[O-]S([O-])(=O)=O PMZURENOXWZQFD-UHFFFAOYSA-L 0.000 description 1
- 238000010521 absorption reaction Methods 0.000 description 1
- 230000009471 action Effects 0.000 description 1
- 238000006136 alcoholysis reaction Methods 0.000 description 1
- 238000004458 analytical method Methods 0.000 description 1
- 239000008346 aqueous phase Substances 0.000 description 1
- 230000009286 beneficial effect Effects 0.000 description 1
- 235000013361 beverage Nutrition 0.000 description 1
- 238000009835 boiling Methods 0.000 description 1
- 239000012267 brine Substances 0.000 description 1
- 208000026106 cerebrovascular disease Diseases 0.000 description 1
- 238000004891 communication Methods 0.000 description 1
- 238000010276 construction Methods 0.000 description 1
- 239000012043 crude product Substances 0.000 description 1
- 239000013078 crystal Substances 0.000 description 1
- 238000000354 decomposition reaction Methods 0.000 description 1
- 230000007547 defect Effects 0.000 description 1
- 230000007812 deficiency Effects 0.000 description 1
- 238000001514 detection method Methods 0.000 description 1
- 230000002526 effect on cardiovascular system Effects 0.000 description 1
- 239000000706 filtrate Substances 0.000 description 1
- 238000001914 filtration Methods 0.000 description 1
- 239000012467 final product Substances 0.000 description 1
- 239000012847 fine chemical Substances 0.000 description 1
- 235000013305 food Nutrition 0.000 description 1
- 235000003599 food sweetener Nutrition 0.000 description 1
- 239000008187 granular material Substances 0.000 description 1
- 230000005484 gravity Effects 0.000 description 1
- JEGUKCSWCFPDGT-UHFFFAOYSA-N h2o hydrate Chemical compound O.O JEGUKCSWCFPDGT-UHFFFAOYSA-N 0.000 description 1
- 230000003301 hydrolyzing effect Effects 0.000 description 1
- 238000009776 industrial production Methods 0.000 description 1
- 229910017053 inorganic salt Inorganic materials 0.000 description 1
- 238000009434 installation Methods 0.000 description 1
- 238000009413 insulation Methods 0.000 description 1
- 239000000543 intermediate Substances 0.000 description 1
- 230000016507 interphase Effects 0.000 description 1
- 150000002500 ions Chemical class 0.000 description 1
- 239000007791 liquid phase Substances 0.000 description 1
- 238000000622 liquid--liquid extraction Methods 0.000 description 1
- 230000004060 metabolic process Effects 0.000 description 1
- 239000011259 mixed solution Substances 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 229910052757 nitrogen Inorganic materials 0.000 description 1
- 238000005192 partition Methods 0.000 description 1
- 239000000843 powder Substances 0.000 description 1
- 238000011085 pressure filtration Methods 0.000 description 1
- 238000011403 purification operation Methods 0.000 description 1
- 239000000376 reactant Substances 0.000 description 1
- 238000001953 recrystallisation Methods 0.000 description 1
- 238000011160 research Methods 0.000 description 1
- 230000000717 retained effect Effects 0.000 description 1
- 239000012266 salt solution Substances 0.000 description 1
- 229920006395 saturated elastomer Polymers 0.000 description 1
- HPALAKNZSZLMCH-UHFFFAOYSA-M sodium;chloride;hydrate Chemical compound O.[Na+].[Cl-] HPALAKNZSZLMCH-UHFFFAOYSA-M 0.000 description 1
- 239000007787 solid Substances 0.000 description 1
- -1 sucralose diester Chemical class 0.000 description 1
- 239000003765 sweetening agent Substances 0.000 description 1
- 238000010998 test method Methods 0.000 description 1
- 229910021642 ultra pure water Inorganic materials 0.000 description 1
- 239000012498 ultrapure water Substances 0.000 description 1
- 238000010977 unit operation Methods 0.000 description 1
Images
Classifications
-
- C—CHEMISTRY; METALLURGY
- C07—ORGANIC CHEMISTRY
- C07H—SUGARS; DERIVATIVES THEREOF; NUCLEOSIDES; NUCLEOTIDES; NUCLEIC ACIDS
- C07H1/00—Processes for the preparation of sugar derivatives
-
- C—CHEMISTRY; METALLURGY
- C07—ORGANIC CHEMISTRY
- C07H—SUGARS; DERIVATIVES THEREOF; NUCLEOSIDES; NUCLEOTIDES; NUCLEIC ACIDS
- C07H1/00—Processes for the preparation of sugar derivatives
- C07H1/06—Separation; Purification
-
- C—CHEMISTRY; METALLURGY
- C07—ORGANIC CHEMISTRY
- C07H—SUGARS; DERIVATIVES THEREOF; NUCLEOSIDES; NUCLEOTIDES; NUCLEIC ACIDS
- C07H5/00—Compounds containing saccharide radicals in which the hetero bonds to oxygen have been replaced by the same number of hetero bonds to halogen, nitrogen, sulfur, selenium, or tellurium
- C07H5/02—Compounds containing saccharide radicals in which the hetero bonds to oxygen have been replaced by the same number of hetero bonds to halogen, nitrogen, sulfur, selenium, or tellurium to halogen
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P20/00—Technologies relating to chemical industry
- Y02P20/10—Process efficiency
Definitions
- the invention belongs to the technical field of fine chemicals, and in particular relates to a preparation method of sucralose.
- Sucralose commonly known as sucralose, is white crystalline powder or granules in appearance, and its sweetness is about 600 times that of sucrose.
- sucralose is the only one that uses sucrose as raw material.
- Calorie does not participate in human metabolism, can be used by diabetics, patients with cardiovascular and cerebrovascular diseases and the elderly as "zero-calorie" sugar.
- the products have the characteristics of high stability, acid and alkali resistance, high temperature resistance, long shelf life and high safety, and are widely used in food, beverage, daily chemical, pharmaceutical and other fields.
- Sucralose-6-ester is one of the important intermediates for the preparation of sucralose, which is obtained by chlorination of sucralose-6-ester and chlorination reagent at high temperature, because a large number of by-products and impurities will be produced during the chlorination process , these by-products and impurities affect the purity of the final product sucralose.
- a preparation method of sucralose is provided, which abandons the traditional intermittent neutralization, precipitation, hydrolysis, and lengthy sucralose-6-acetate purification process, and realizes the sucralose Continuous preparation of sucrose to overcome the deficiencies in the prior art.
- a method for preparing sucralose comprising:
- Neutralization step make the chlorination reaction solution for preparing sucralose-6 ester, the first liquid caustic soda and the first reused water enter the neutralization reaction distillation tower in sections, and after the neutralization reaction is carried out under the evaporation condition, from the neutralization reaction Extract the solvent mixture from the top of the rectifying tower; extract the chlorination reaction neutralizing liquid from the bottom of the column of the neutralization reaction rectification;
- Hydrolysis step make the chlorination reaction neutralization liquid, the second liquid alkali and the second recycled water enter the hydrolysis reaction rectification tower, carry out the alkaline hydrolysis reaction under the evaporation condition, and extract from the top of the hydrolysis reaction rectification tower The aqueous solution is discarded, and the sucralose aqueous solution is extracted from the bottom of the hydrolysis reaction distillation tower;
- Extraction and purification step after adjusting the sucralose aqueous solution to neutrality, sequentially perform extraction, oxidation and back extraction for purification;
- Crystallization step Concentrate, crystallize and filter the purified sucralose aqueous solution to obtain crude sucralose product and crystallization mother liquor.
- the above method also includes:
- Mother liquor circulation recovery step the crystallization mother liquor is recycled into the sucralose aqueous solution to enter the crystallization step, and the number of recycling is 1 to 5 times.
- the height of the neutralization reactive distillation tower is 10-30m;
- the feeding position of the chlorination reaction liquid is at a position of 3/10 to 2/5 of the height of the tower from the top of the tower, and the feeding position of the first liquid alkali is at a position of 1/2 to 3/5 of the height of the tower from the top of the tower , the feeding position of the first recycled water is at a position of 7/10 to 4/5 of the tower height from the top of the tower.
- the top temperature of the neutralization reaction distillation tower is set to 30-40°C, and the bottom temperature is set to 50-60°C.
- the tower height of the hydrolysis reaction distillation tower is 10-30m;
- the feed position of the chlorinated liquid neutralizing liquid is 2/5 to 3/7 of the height of the tower from the top of the tower, and the feed position of the second liquid alkali is 1/2 to 3/5 of the height of the tower from the top of the tower.
- the position of the feed of the second return water is at a position of 4/5 to 9/10 of the height of the tower from the top of the tower.
- the temperature at the top of the neutralization reaction distillation column is set at 30-40°C, and the temperature at the bottom of the column is set at 50-60°C.
- both the neutralization reaction rectification tower and the hydrolysis reaction rectification tower are packed towers or plate towers, preferably packed towers, wherein the filler in the packed tower is polytetrafluoro corrugated plate or ⁇ ring ,
- the height of the packing is 1/3 ⁇ 2/3 of the height of the packed tower.
- the volume ratio of the chlorination reaction solution, the first liquid caustic soda and the first recycled water is 10-15:1:1;
- the volume ratio of the chlorination reaction neutralizing solution, the second liquid caustic soda and the second recycled water is 40-60:1:10-20.
- both the first liquid alkali and the second liquid alkali are aqueous solutions of sodium hydroxide or potassium hydroxide, preferably aqueous solutions of sodium hydroxide.
- adjusting the sucralose aqueous solution to neutrality includes:
- the pH value of the sucralose aqueous solution is adjusted to 6-8 by adopting inorganic acid, wherein the inorganic acid is one of hydrochloric acid, sulfuric acid or phosphoric acid.
- the extractant used for extraction is ethyl acetate and/or butyl acetate
- the ratio of the volumetric dosage of the extractant to the neutralizing solution for the chlorination reaction is 1-5:1.
- the oxidant used for oxidation is sodium hypochlorite or ozone; wherein, the mass dosage of sodium hypochlorite is 0.01% to 0.1% of the volume of the organic phase obtained by extraction; the volume dosage of ozone is 0.01 to 0.1% of the volume of the obtained organic phase;
- the oxidation time for oxidation is 3-12 hours.
- the back-extraction agent for back-extraction is water, and the volume ratio of the back-extraction agent to the volume of the extracted organic phase is 1-5:1.
- the concentration temperature is 40-60°C
- the concentration vacuum is -0.1--0.5Mpa
- the sucralose concentration in the sucralose aqueous solution is 80-140g /L.
- the beneficial effect of the present application is that the present application uses the untreated chlorinated reaction liquid obtained during the preparation of sucralose-6-ester as a raw material, and uses a neutralization reaction rectification tower to realize the neutralization and precipitation of the chlorinated liquid, and then uses the hydrolysis
- the rectification tower achieves the purpose of desolvation and hydrolysis of sucralose-6-ester to prepare sucralose, and finally through extraction-oxidation-back extraction, the continuous preparation of sucralose is realized.
- This application abandons the traditional batch process And, precipitation, hydrolysis, and lengthy sucralose-6-acetate purification process, significantly improved the efficiency of the preparation and purification of sucralose; and compared with the prior art, the application uses liquid caustic soda to The reaction solution is neutralized, and the use of ammonia water and sodium methoxide is discarded. On the one hand, it reduces the pressure brought by the ammonia nitrogen content in the later biochemical treatment; on the other hand, it avoids the use and production of methanol, which is highly environmentally friendly and is An efficient, green and continuous sucralose preparation process has extremely high application value and practicability.
- Figure 1 shows a schematic structural view of a device for preparing sucralose according to an embodiment of the present application
- Fig. 2 shows a schematic flow diagram of a method for preparing sucralose-6-ester according to an embodiment of the present application.
- sucralose-6-ester in the chlorination reaction solution must be released after being neutralized by alkali.
- Sucralose-6-ester cannot be obtained from the chlorination reaction solution, and sucralose can be prepared from it; after neutralization, solvents such as DMF and trichloroethane must be evaporated to prevent alkaline hydrolysis in the later stage.
- solvents such as DMF and trichloroethane must be evaporated to prevent alkaline hydrolysis in the later stage.
- the process of sucralose leads to the decomposition of DMF; there must be a purification operation in the process of preparing sucralose from sucralose-6-ester, otherwise the pure product of sucralose cannot be successfully obtained through crystallization, and the mother liquor cannot be recycled.
- the ammonia water used in the neutralization process will lead to high pressure of ammonia nitrogen in the later biochemical treatment, and the use of sodium methoxide and methanol will affect the crystallization quality of the later product; the purification process requires a lot of complicated purification
- the technology has the defects of complex operation, low degree of continuity, high economic and time costs, and low yield of sucralose.
- the present application proposes a continuous preparation method of sucralose.
- the technical concept is: through a two-stage reactive distillation tower, effectively combine neutralization and precipitating, effectively combine precipitating and hydrolysis, and improve the process continuity, reducing operation difficulty and production cost; using liquid caustic soda as neutralization and hydrolysis agent, reducing the difficulty of biochemical treatment of ammonia nitrogen in the later stage, and the influence of methanol/sodium methoxide on the crystallization quality of later products; using extraction-oxidation-stripping
- the purification process ensures the crystallization efficiency of sucralose. After the above steps are used to treat the chlorinated solution containing sucralose-6-acetate, a relatively pure sucralose product can be obtained.
- FIG. 1 shows a schematic structural diagram of the equipment for preparing sucralose according to an embodiment of the application.
- the equipment given in 1 is for illustrative purposes only and does not limit the application.
- the equipment 100 for sucralose shown in FIG. 1 includes: a neutralization reaction rectification tower R-1, a hydrolysis reaction rectification tower R-2, a pH adjustment tank V-1, and a rotating disk extraction tower connected in sequence R-3, oxidation kettle V-2, rotary disk extraction tower R-4, concentration kettle V-3, crystallization kettle V-4 and plate and frame filter press E-1.
- Fig. 2 shows a schematic flow chart of a method for preparing sucralose according to an embodiment of the present application. It can be seen from Fig. 2 that the method at least includes steps S210 to S240:
- Neutralization step S210 the chlorination reaction solution for preparing sucralose-6 ester, the first liquid caustic soda and the first reused water are put into the neutralization reaction distillation tower in sections, and after the neutralization reaction is carried out under evaporation conditions, the neutralization The solvent mixture is extracted from the top of the reactive distillation tower; the chlorination reaction neutralizing liquid is extracted from the bottom of the neutralized reactive distillation column.
- the neutralization reaction rectification tower R-1 includes three feeding sections, the upper section is the chlorination reaction liquid feeding section, the middle section is the first liquid alkali feeding section, and the lower section is the first recycled water Feed section.
- the chlorination reaction solution in the present application is a chlorination reaction between sucrose-6-carboxylate and a chlorination reagent, and the resulting mixed solution of reactants is called a chlorination reaction solution.
- This application is suitable for preparing the reaction solution produced in the chlorination reaction stage of sucralose by various methods in the prior art, such as single-group protection method, multi-group protection method, etc., for the chlorination of sucrose-6-carboxylate
- the source of the reaction solution is not limited in the present application, and it may be the reaction solution produced in the chlorination reaction stage in the preparation of sucralose in the laboratory or in industrial production.
- sucrose-6-carboxylate chlorination reaction solution usually adopts ammonia water or directly adopts ammonia gas, and the use of ammonia water or ammonia gas increases a large amount of nitrogen elements in the system, which is not conducive to Subsequent separation and recovery of waste liquid.
- liquid caustic soda is used instead of ammonia water or ammonia gas.
- liquid caustic soda can be obtained by dissolving sodium hydroxide and potassium hydroxide in water, or can be directly used Commercially available products, such as 32wt% sodium hydroxide solution.
- the purpose of selecting the upper section of the neutralization reaction rectification tower for the chlorination reaction liquid is to first evaporate and remove the trichloroethane solvent (trichloroethane with a low boiling point) after the material enters the neutralization reaction rectification tower. , 75°C, insoluble in water), the first liquid caustic soda is fed from the middle stage to ensure that the chlorination reaction liquid can be completely neutralized, and the first recycled water is fed from the lower stage to make use of its azeotropic characteristics with DMF to increase the DMF removal efficiency.
- trichloroethane solvent trichloroethane with a low boiling point
- the chlorination reaction solution is acidic, and the chlorination reaction solution, the first liquid alkali and the first recycled water undergo a neutralization reaction in the neutralization reaction distillation tower, and the sucralose-6-ester is released.
- sucralose-6-acetate is the most widely used, and the following is an example of sucralose-6-acetate.
- the solvent can be removed by evaporation and other means.
- the solvent is mainly DMF, trichloroethane, and a mixed solvent formed by a large amount of water.
- a vacuum pump can be used to reduce the neutralization reaction. The pressure of the rectification column to promote the evaporation of mixed solvents.
- chlorination reaction neutralization solution After the chlorination reaction solution reacts with the first liquid caustic soda, most of the mixed solvent is removed, and the remaining solution obtained is called chlorination reaction neutralization solution.
- Hydrolysis step S220 Make the chlorination reaction neutralization liquid, the second liquid alkali and the second reused water enter the hydrolysis reaction rectification tower in stages, and carry out the alkaline hydrolysis reaction under the evaporation condition, and extract from the top of the hydrolysis reaction rectification tower The waste aqueous solution is extracted, and the sucralose aqueous solution is extracted from the bottom of the hydrolysis reaction distillation tower.
- the hydrolysis reaction rectification tower R-2 comprises three processes In the feeding section, the upper section is the chlorination reaction neutralization liquid feeding section, the middle section is the second liquid alkali feeding section, and the lower section is the second recycled water feeding section.
- the purpose of selecting the feed from the upper section of the hydrolysis reaction distillation tower for the chlorination reaction neutralization liquid is to first evaporate and remove the remaining trichloroethane solvent after the material enters the neutralization reaction rectification tower, and the second liquid Alkali is fed from the middle section to ensure that the neutralization liquid in the chlorination reaction can be completely hydrolyzed, and the second reuse water is fed from the lower section to improve the removal efficiency of DMF by utilizing its azeotropic characteristics with DMF.
- the chlorination reaction neutralizing liquid is subjected to alkaline hydrolysis reaction in the presence of the second liquid alkali, and in the process of alkaline hydrolysis, evaporation means are used to further evaporate the mixed solvent.
- sucralose-6- Esters complete hydrolysis to sucralose.
- the function of the second recycling water is the same as that of the first recycling water, and the second recycling water and the mixed solvent generate a waste aqueous solution, which can be extracted from the top of the hydrolysis reaction distillation tower.
- the sucralose-6-ester is released from the chlorination reaction solution, and solvents such as DMF and trichloroethane are removed, so that the sucralose-6-ethyl
- the acid ester is hydrolyzed into sucralose, realizing the continuous operation of neutralization, solvent removal and hydrolysis.
- Extraction and purification step S230 After adjusting the sucralose aqueous solution to neutrality, extraction, oxidation and back extraction are performed in sequence for purification.
- Extraction also known as solvent extraction or liquid-liquid extraction, also known as extraction, is a unit operation that uses the different solubility of the components in the system to separate the mixture; A method in which a solute substance is transferred from one solvent to another due to the difference in solubility or partition coefficient in a slightly soluble solvent.
- the extractant used for extraction is organic ester, such as ethyl acetate and/or butyl acetate, sucralose in aqueous solution, the target product sucralose dissolved in the extractant and sucralose similar in structure
- organic ester is extracted into the extractant, the aqueous phase obtained by extraction is sent to waste water treatment, and the obtained organic phase is subjected to subsequent steps.
- an oxidizing agent is added to the obtained organic phase.
- the purpose of the oxidizing agent is to oxidize organic ester impurities such as sucralose tetrachloride to the target product sucralose, thereby achieving the purpose of greatly increasing the yield of sucralose.
- back extraction is the process of returning the extract from the loaded organic phase to the water phase with a back extraction agent. It is the reverse process of extraction.
- the sucralose can be obtained from the extraction process.
- the organic phase is transferred to the stripping agent.
- water or deionized water can be used as the stripping agent, especially the use of deionized water is more conducive to the subsequent crystallization effect.
- crystallization step S240 Concentrate, crystallize and filter the purified sucralose aqueous solution to obtain crude sucralose product and crystallization mother liquor.
- the purified sucralose aqueous solution is subjected to a crystallization step to obtain the crude sucralose product and the remaining primary crystallization mother liquor.
- a crystallization step to obtain the crude sucralose product and the remaining primary crystallization mother liquor.
- the stripping agent usually uses water, in the crystallization step, it is actually a water crystallization process, the crystallization process is easier to control, and the crystallization effect is good.
- the mixture formed by extracting a small amount of DMF and water from the top of the tower is used for sewage treatment, and the aqueous solution of sucralose is extracted from the bottom of the tower and input into the lower neutralization reactor V-1; adding inorganic acid to the neutralization reactor V-1 to adjust the pH to neutral properties, and then input to the lower rotary disk extraction tower R-3; in the upper and lower sections of the rotary disk extraction tower R-3, the sucralose aqueous solution and organic ester materials are respectively input as extraction agents, and the trichloro
- the organic phase of the sucrose extract is extracted from the bottom of the rotary extraction tower R-3 with high brine; the organic phase extract containing sucralose and the oxidant are input into the oxidation kettle V-2 together, and after a period of reaction under certain conditions , into the lower section of the rotary extraction tower R-4; input pure water into the upper section of the rotary disk extraction tower R-4, and extract it countercurrently with the organic phase, and extract the organic phase from the top of the
- the sucralose solution is extracted from the tower bottom of R-4 to the concentration tank V-3; the sucralose aqueous solution is concentrated in the concentration tank V-3, and the sucralose is concentrated to a certain concentration under certain conditions and then input to the lower crystallization tank V- 4.
- the material is input into the plate and frame filter press E-1 for pressure filtration and separation, and the obtained solid is sucralose crystals, and the primary crystallization mother liquor and multiple crystallization mother liquors are returned to the concentration tank V-3 to continue to concentrate, and repeated several times Finally, the final mother liquor is used as waste sugar water for sewage treatment.
- this application uses the untreated chlorinated reaction liquid obtained when preparing sucralose-6-ester as raw material, and uses a neutralization reaction rectification tower to realize the neutralization and precipitation of the chlorinated liquid , and then use the hydrolysis rectification tower to achieve the purpose of desolventization and hydrolysis of sucralose-6-ester to prepare sucralose, and finally through extraction-oxidation-back extraction, the continuous preparation of sucralose is realized.
- This application abandons The traditional intermittent neutralization, precipitation, hydrolysis, and lengthy sucralose-6-acetate purification process have significantly improved the efficiency of the preparation and purification of sucralose; and compared with the prior art, this application uses liquid Alkali neutralizes the chlorination reaction liquid, abandoning the use of ammonia water and sodium methoxide, on the one hand, it reduces the pressure brought by the ammonia nitrogen content in the later biochemical treatment; on the other hand, it avoids the use and production of methanol, which is environmentally friendly It is a high-efficiency, green and continuous sucralose preparation process with high application value and practicability.
- the above-mentioned method further includes: a mother liquor recycling step: recycling the crystallization mother liquor into the sucralose aqueous solution to enter the crystallization step, and the recycling times are 1-5 times.
- the mother liquor retained after the first crystallization is called the primary crystallization mother liquor.
- the primary crystallization mother liquor is recrystallized after removing impurities, and the remaining mother liquor after the secondary crystallization is called the secondary crystallization mother liquor.
- a small amount of crystallization can be obtained after the secondary crystallization mother liquor removes impurities again.
- Both the secondary crystallization mother liquor and the mother liquor remaining after recrystallization are called multiple crystallization mother liquors.
- the crystallization mother liquor in order to further increase the yield of sucralose, can be recycled multiple times, so as to crystallize the target product in the mother liquor more thoroughly.
- the neutralization reaction distillation tower can be a packed tower or plate type tower.
- the packed tower uses packing as the basic component of gas-liquid contact and mass transfer.
- the liquid flows from top to bottom in the form of a film on the surface of the packing, and the gas flows in a continuous phase from bottom to top with the liquid, and the gas and liquid two Mass and heat transfer between phases.
- the component concentrations and temperatures of the two phases vary continuously along the height of the column.
- the packed tower is a differential contact type gas and liquid mass transfer equipment.
- the packing in the packed tower is polytetrafluoro corrugated plate or ⁇ ring, and the packing height is 1/3-2/3 of the height of the packed tower.
- Tray tower is a kind of graded contact mass transfer equipment used in gas-liquid or liquid-liquid system. It consists of a cylindrical tower body and a number of trays installed horizontally in the tower at a certain distance. Widely used in rectification and absorption, some types (such as sieve plate column) are also used for extraction, and can also be used as a reactor for gas-liquid phase reaction process.
- the liquid flows through each layer of trays from top to bottom in sequence under the action of gravity, and is discharged from the bottom of the tower; the gas is pushed through the layers from bottom to top under the push of pressure difference Tray plate, to the top of the tower to discharge. A certain depth of liquid layer is maintained on each tray, and the gas is dispersed into the liquid layer through the tray for interphase contact and mass transfer.
- the specifications of the neutralization reaction distillation tower are not limited.
- the tower height of the neutralization reaction distillation tower is 10-30m; wherein, the chlorination reaction
- the liquid feeding position is at a position of 3/10 to 2/5 of the tower height from the top of the tower, and the feeding position of the first liquid caustic soda is at a position of 1/2 to 3/5 of the tower height from the top of the tower.
- the feeding position of the recycled water is 7/10-4/5 of the height of the tower from the top of the tower.
- reaction conditions of the neutralization reaction are not limited, as long as the neutralization reaction can be carried out thoroughly, in some embodiments of the application, considering the reaction effect of the neutralization reaction, the neutralization reaction rectification
- the tower top temperature of the tower is set at 30-40°C, and the tower bottom temperature is set at 50-60°C.
- the hydrolysis reaction distillation column there is no limitation on the type of the hydrolysis reaction distillation column, any distillation column that can realize hydrolysis and distillation at the same time is sufficient.
- the hydrolysis reaction distillation column can be a packed column or a tray column.
- the specifications of the hydrolysis reaction distillation tower are not limited.
- the tower height of the hydrolysis reaction distillation tower is 10-30m; wherein, the chlorination liquid neutralizing liquid
- the feeding position is at a position of 2/5 to 3/7 of the tower height from the top of the tower, and the feeding position of the second liquid caustic soda is at a position of 1/2 to 3/5 of the tower height from the top of the tower.
- the feeding position of water is at a position of 4/5-9/10 of the tower height from the top of the tower.
- the conditions of the hydrolysis reaction are not limited, but the hydrolysis can be carried out thoroughly.
- the temperature at the top of the neutralization reaction distillation tower is set to 30-40°C, and the temperature at the bottom of the tower is set at 50-60°C.
- the material ratio of the chlorination reaction liquid, the first liquid caustic soda and the first recycled water is the material ratio of the chlorination reaction liquid, the first liquid caustic soda and the first recycled water
- the neutralization step there is no limitation to the material ratio of the chlorination reaction liquid, the first liquid alkali and the first recycled water.
- the chlorination reaction liquid, the first liquid alkali and the second The volume ratio of primary water is 10-15:1:1.
- neutralization can be carried out completely, and most of the solvent can be taken out by the primary water without waste of raw materials.
- the material ratio of the chlorination reaction neutralizing liquid, the second liquid alkali and the second recycled water there is no limitation on the material ratio of the chlorination reaction neutralizing liquid, the second liquid alkali and the second recycled water.
- the chlorination reaction neutralizing liquid, the second liquid The volume ratio of the alkali to the second water is 40-60:1:10-20.
- the hydrolysis can be carried out completely, and most of the solvent can be taken out by the second water without causing Raw material wastage.
- an organic ester in the extraction and purification step, in order to extract sucralose, an organic ester can be selected as the extractant, such as ethyl acetate and/or butyl acetate.
- the amount of extractant is not limited, it can be determined according to the amount of chlorination reaction neutralization liquid, such as the ratio of the volume of extraction agent to chlorination reaction neutralization liquid is 1 to 5:1 , within the range of the above-mentioned dosage ratio, the extraction can achieve a better technical effect without causing waste of the extractant.
- the oxidizing agent is screened, and it is found that sodium hypochlorite or ozone is used for selection, and the selective oxidation is relatively good, that is, tetrachlorosucrose can be oxidized to sucralose, and simultaneously Does not further oxidize sucralose.
- the mass fraction and dosage of the oxidizing agent are not limited.
- the mass dosage of sodium hypochlorite is 0.01% to 0.1% of the volume of the extracted organic phase;
- the volumetric dosage of ozone is 0.01-0.1% of the volume of the organic phase obtained by extraction. If the amount of oxidizing agent is less than the lower limit of the above range, the amount is too small, the oxidation reaction is not carried out thoroughly, affecting the yield of sucralose; if the amount of oxidizing agent is greater than the upper limit of the above range, then the amount is too much, may cause excessive oxidation.
- the oxidation temperature and oxidation time of the oxidation reaction are not limited, and in other embodiments, the oxidation time of oxidation is 3-12 hours; the oxidation temperature can be at room temperature.
- the amount of stripping agent is not limited, and can be determined according to the amount of neutralizing liquid in the chlorination reaction, such as the ratio of the volume of stripping agent to the volume of the organic phase obtained by extraction is 1 ⁇ 5:1. Within the range of the above-mentioned dosage ratio, the stripping can achieve better technical effect without causing waste of stripping agent.
- the crystallization conditions are not limited, and one or more combinations of the prior art may be referred to.
- the concentrated concentration temperature is 40-60 °C
- the vacuum degree of concentration is -0.1 ⁇ -0.5Mpa
- the concentration of sucralose in the sucralose aqueous solution is 80 ⁇ 140g/L.
- each material content adopts the high performance liquid chromatography (High Performance Liquid Chromatography, HPLC) method to adopt the external standard method to record under the following conditions, no longer repeat them in each embodiment.
- HPLC High Performance Liquid Chromatography
- the neutralization reaction distillation tower R-1 is a packed tower with a tower height of 10m, and the packing is polytetrafluoro corrugated board, and the packing height is 1/3 of the tower height.
- the chlorination reaction liquid, the first liquid caustic soda, and the first recycled water are respectively input into the neutralization reaction distillation tower at positions 3m, 5m, and 7m away from the tower top.
- the temperature at the top of the neutralization reaction distillation column R-1 is 30°C, and the temperature at the bottom of the column is 50°C.
- the mixed solvent is extracted from the top of the neutralization reactive distillation tower R-1 for separation, and the chlorination reaction neutralization liquid extracted from the bottom of the neutralization reactive distillation tower R-1 is input into the hydrolysis reactive distillation tower R-2.
- the hydrolysis reaction rectification tower R-2 is a plate tower with a tower height of 10m, and the filler is a stainless steel ⁇ ring, and the height of the filler is 1/3 of the height of the tower;
- Reuse water is input into the hydrolysis reaction distillation tower R-2 at the positions of 4m, 5m and 8m from the top of the tower respectively.
- the temperature at the top of the hydrolysis reaction distillation column is 30°C, and the temperature at the bottom of the column is 50°C.
- the waste water is extracted from the top of the tower for sewage treatment, and the sucralose aqueous solution is extracted from the bottom of the tower and input into the pH adjustment kettle V-1.
- the water phase is output from the lower section of the rotary disk extraction tower R-3 for high-salt wastewater treatment, and the ethyl acetate phase is output from the upper section and enters the oxidation tank V-2 for oxidation treatment.
- Crystallization step input the sucralose aqueous solution into the concentration tank V-3 for concentration, the concentration temperature is 40°C, the vacuum degree is -0.1Mpa, the concentrated sucralose concentration is 80g/L, and then the concentrated solution is input into the crystallization tank V-4 Crystallization at room temperature, sucralose mother liquor was reused 4 times, and the purity of sucralose after drying is shown in Table 1.
- the neutralization reaction distillation tower R-1 is a packed tower with a tower height of 15m, and the packing is polytetrafluorotheta ring, and the packing height is 1/2 of the tower height.
- the chlorination reaction liquid, the first liquid caustic soda, and the first reused water are respectively input into the neutralization reaction distillation column R-1 at positions 6m, 9m, and 12m away from the tower top.
- the temperature at the top of the neutralization reaction distillation column R-1 is 35°C, and the temperature at the bottom of the column is 55°C.
- the mixed solvent is extracted from the top of the neutralization reaction rectification tower R-1 for separation, and the neutralization liquid of the chlorination reaction at the bottom of the tower is input into the hydrolysis reaction rectification tower R-2.
- the hydrolysis reaction rectification tower R-2 is a plate tower with a tower height of 15m, and the packing is stainless steel corrugated plate, and the packing height is 1/3 of the tower height;
- the secondary water is input into the hydrolysis reaction distillation column R-2 at positions 6.5m, 9m, and 13.5m from the top of the tower respectively.
- the temperature at the top of the hydrolysis reaction distillation column R-2 is 35°C, and the temperature at the bottom of the column is 55°C.
- the waste water is extracted from the top of the hydrolysis reaction distillation column R-2 for sewage treatment, and the sucralose aqueous solution is extracted from the bottom of the column and input into the pH adjustment tank V-1.
- the water phase is output from the lower section of the rotary disk extraction tower R-3 for high-salt wastewater treatment, and the ethyl acetate phase is output from the upper section into the oxidation tank V-2 for oxidation treatment.
- Crystallization step input the sucralose aqueous solution into the concentration tank V-3 for concentration, the concentration temperature is 60°C, the vacuum degree is -0.05Mpa, the concentrated sucralose concentration is 100g/L, and then the concentrated solution is input into the crystallization tank V-4 Crystallization at room temperature, sucralose mother liquor was reused 4 times, and the purity of sucralose after drying is shown in Table 2.
- the neutralization reaction distillation tower R-1 is a packed tower with a tower height of 20m, and the packing is polytetrafluoro corrugated board, and the packing height is 2/3 of the tower height.
- the chlorination reaction liquid, the first liquid caustic soda, and the first reused water are respectively input into the neutralization reaction distillation column R-1 at positions 7m, 11m, and 15m away from the tower top.
- the temperature at the top of the neutralization reaction distillation column R-1 is 40°C, and the temperature at the bottom of the column is 55°C.
- the mixed solvent is taken from the top of the neutralization reaction distillation tower R-1 for separation, and the neutralization liquid from the chlorination reaction is taken from the bottom of the tower and input into the hydrolysis reaction distillation tower R-2.
- the hydrolysis reaction rectification tower R-2 is a plate tower with a tower height of 20m, and the packing is stainless steel corrugated plate, and the packing height is 2/3 of the tower height;
- the secondary water is input into the hydrolysis reaction distillation tower R-2 at the positions of 8.2m, 11m and 17m from the top of the tower respectively.
- the temperature at the top of the hydrolysis reaction distillation column R-2 is 35°C, and the temperature at the bottom of the column is 60°C.
- the tower top of the hydrolysis reaction rectification tower R-2 extracts waste water for sewage treatment, and extracts the sucralose aqueous solution from the tower bottom to input the pH adjustment kettle V-1.
- the water phase is output from the lower section of the rotary disk extraction tower R-3 for high-salt wastewater treatment, and the ethyl acetate phase is output from the upper section into the oxidation tank V-2 for oxidation treatment.
- Crystallization step input the sucralose aqueous solution into the concentration tank V-3 for concentration, the concentration temperature is 50°C, the vacuum degree is -0.07Mpa, the concentrated sucralose concentration is 120g/L, and then the concentrated solution is input into the crystallization tank V-4 Crystallization at room temperature, sucralose mother liquor was reused 5 times, and the purity of sucralose after drying is shown in Table 3.
- the neutralization reaction distillation tower R-1 is a packed tower with a tower height of 25m, and the packing is polytetrafluorotheta ring, and the packing height is 3/5 of the tower height.
- the chlorination reaction liquid, the first liquid caustic soda, and the first reused water are respectively input into the neutralization reaction distillation column R-1 at positions 8m, 13m, and 18m away from the tower top.
- the temperature at the top of the neutralization reaction distillation column R-1 is 33°C, and the temperature at the bottom of the column is 58°C.
- the mixed solvent is taken from the top of the neutralization reaction distillation tower R-1 for separation, and the neutralization liquid from the chlorination reaction is taken from the bottom of the tower and input into the hydrolysis reaction distillation tower R-2.
- the hydrolysis reaction distillation tower R-2 is a plate tower with a tower height of 25m, and the filler is a stainless steel ⁇ ring, and the height of the filler is 1/3 of the height of the tower;
- the secondary water is input into the hydrolysis reaction distillation tower R-2 at the positions of 10.5m, 13m and 20.5m from the top of the tower respectively.
- the temperature at the top of the hydrolysis reaction distillation column R-2 was 32°C, and the temperature at the bottom of the column was 56°C.
- the waste water is extracted from the top of the hydrolysis reaction distillation column R-2 for sewage treatment, and the sucralose aqueous solution is extracted from the bottom of the column and input into the pH adjustment tank V-1.
- the water phase is output from the lower section of the rotary disk extraction tower R-3 for high-salt wastewater treatment, and the ethyl acetate phase is output from the upper section into the oxidation tank V-2 for oxidation treatment.
- Crystallization step input the sucralose aqueous solution into the concentration tank V-3 for concentration, the concentration temperature is 45°C, the vacuum degree is -0.09Mpa, the concentrated sucralose concentration is 110g/L, and then the concentrated solution is input into the crystallization tank V-4 Crystallization at room temperature, sucralose mother liquor was reused 5 times, and the purity of sucralose after drying is shown in Table 4.
- the neutralization reaction distillation tower R-1 is a packed tower with a tower height of 30m, and the packing is polytetrafluorotheta ring, and the packing height is 1/3 of the tower height.
- the chlorination reaction liquid, the first liquid caustic soda, and the first reused water are respectively input into the neutralization reactive distillation column R-1 at positions 10.2m, 16.2m, and 22.2m away from the tower top.
- the temperature at the top of the neutralization reaction distillation column R-1 is 40°C, and the temperature at the bottom of the column is 60°C.
- the mixed solvent is taken from the top of the neutralization reaction distillation tower R-1 for separation, and the neutralization liquid from the chlorination reaction is taken from the bottom of the tower and input into the hydrolysis reaction distillation tower R-2.
- the hydrolysis reaction rectification tower R-2 is a plate tower with a tower height of 30m, and the packing is stainless steel corrugated plate, and the packing height is 3/5 of the tower height;
- the recycled water is input into the hydrolysis reaction distillation tower R-2 at the positions of 12.3m, 16.2m and 25.2m from the top of the tower respectively.
- the temperature at the top of the hydrolysis reaction distillation column R-2 is 40°C, and the temperature at the bottom of the column is 60°C.
- the waste water is extracted from the top of the hydrolysis reaction distillation column R-2 for sewage treatment, and the sucralose aqueous solution is extracted from the bottom of the column and input into the pH adjustment tank V-1.
- the water phase is output from the lower section of the rotary disk extraction tower R-3 for high-salt wastewater treatment, and the ethyl acetate phase is output from the upper section into the oxidation tank V-2 for oxidation treatment.
- Crystallization step input the sucralose aqueous solution into the concentration tank V-3 for concentration, the concentration temperature is 55°C, the vacuum degree is -0.06Mpa, the concentrated sucralose concentration is 140g/L, and then the concentrated solution is input into the crystallization tank V-4 Crystallization at room temperature, sucralose mother liquor was reused 4 times, and the purity of sucralose after drying is shown in Table 5.
- the neutralization reaction distillation tower R-1 is a packed tower with a tower height of 16m, and the packing is polytetrafluoro corrugated board, and the packing height is 2/3 of the tower height.
- the chlorination reaction liquid, the first liquid caustic soda, and the first recycled water are respectively input into the neutralization reaction distillation column R-1 at positions 6.2m, 9.5m, and 12.9m away from the tower top.
- the temperature at the top of the neutralization reaction distillation column R-1 is 38°C, and the temperature at the bottom of the column is 52°C.
- the mixed solvent is taken from the top of the neutralization reaction distillation tower R-1 for separation, and the neutralization liquid from the chlorination reaction is taken from the bottom of the tower and input into the hydrolysis reaction distillation tower R-2.
- the hydrolysis reaction distillation tower R-2 is a plate tower with a tower height of 16m, and the filler is a stainless steel ⁇ ring, and the height of the filler is 3/5 of the height of the tower;
- the recycled water is input into the hydrolysis reaction distillation tower R-2 at the positions of 7.8m, 9.5m and 14.6m from the top of the tower respectively.
- the temperature at the top of the hydrolysis reaction distillation column R-2 is 34°C, and the temperature at the bottom of the column is 57°C.
- the waste water is extracted from the top of the hydrolysis reaction distillation column R-2 for sewage treatment, and the sucralose aqueous solution is extracted from the bottom of the column and input into the pH adjustment tank V-1.
- the water phase is output from the lower section of the rotary disk extraction tower R-3 for high-salt wastewater treatment, and the ethyl acetate phase is output from the upper section into the oxidation tank V-2 for oxidation treatment.
- Crystallization step input the sucralose aqueous solution into the concentration tank V-3 for concentration, the concentration temperature is 60°C, the vacuum degree is -0.05Mpa, the concentrated sucralose concentration is 140g/L, and then the concentrated solution is input into the crystallization tank V-4 Crystallization at room temperature, sucralose mother liquor was reused 5 times, and the purity of sucralose after drying is shown in Table 6.
- the neutralization reaction distillation tower R-1 is a packed tower with a tower height of 28m.
- the packing is polytetrafluorotheta ring, and the packing height is 1/3 of the tower height.
- the chlorination reaction liquid, the first liquid caustic soda, and the first recycled water are respectively input into the neutralization reactive distillation column R-1 at positions 8.4m, 15.4m, and 20.2m away from the tower top.
- the temperature at the top of the neutralization reaction distillation column R-1 is 39°C, and the temperature at the bottom of the column is 56°C.
- the mixed solvent is taken from the top of the neutralization reaction distillation tower R-1 for separation, and the neutralization liquid from the chlorination reaction is taken from the bottom of the tower and input into the hydrolysis reaction distillation tower R-2.
- the hydrolysis reaction distillation tower R-2 is a plate tower with a tower height of 28m, and the filler is a stainless steel ⁇ ring, and the height of the filler is 2/5 of the height of the tower;
- Reuse water is input into the hydrolysis reaction distillation tower R-2 at the positions of 11.2m, 16m and 23.8m from the top of the tower respectively.
- the temperature at the top of the hydrolysis reaction distillation column R-2 is 30°C, and the temperature at the bottom of the column is 51°C.
- the waste water is extracted from the top of the hydrolysis reaction distillation column R-2 for sewage treatment, and the sucralose aqueous solution is extracted from the bottom of the column and input into the pH adjustment tank V-1.
- the water phase is output from the lower section of the rotary disk extraction tower R-3 for high-salt wastewater treatment, and the ethyl acetate phase is output from the upper section into the oxidation tank V-2 for oxidation treatment.
- Crystallization step input the sucralose aqueous solution into the concentration tank V-3 for concentration, the concentration temperature is 50°C, the vacuum degree is -0.08Mpa, the concentrated sucralose concentration is 130g/L, and then the concentrated solution is input into the crystallization tank V-4 Crystallization at room temperature, sucralose mother liquor was reused 4 times, and the purity of sucralose after drying is shown in Table 7.
- the neutralization reaction distillation tower R-1 is a packed tower with a tower height of 22m, and the packing is polytetrafluoro corrugated board, and the packing height is 2/5 of the tower height.
- the chlorination reaction liquid, the first liquid caustic soda, and the first recycled water are respectively input into the neutralization reaction distillation column R-1 at positions 8.8m, 11m, and 17m away from the tower top.
- the temperature at the top of the neutralization reaction distillation column R-1 is 36°C, and the temperature at the bottom of the column is 59°C.
- the mixed solvent is taken from the top of the neutralization reaction distillation tower R-1 for separation, and the neutralization liquid from the chlorination reaction is taken from the bottom of the tower and input into the hydrolysis reaction distillation tower R-2.
- the hydrolysis reaction rectification tower R-2 is a plate tower with a tower height of 22m, and the packing is stainless steel corrugated plate, and the packing height is 2/3 of the tower height;
- the recycled water is input into the hydrolysis reaction distillation tower R-2 at the positions of 9m, 12m and 19m from the top of the tower respectively.
- the temperature at the top of the hydrolysis reaction distillation column R-2 is 33°C, and the temperature at the bottom of the column is 58°C.
- the waste water is extracted from the top of the hydrolysis reaction distillation column R-2 for sewage treatment, and the sucralose aqueous solution is extracted from the bottom of the column and input into the pH adjustment tank V-1.
- the water phase is output from the lower section of the rotary disk extraction tower R-3 for high-salt wastewater treatment, and the ethyl acetate phase is output from the upper section into the oxidation tank V-2 for oxidation treatment.
- Crystallization step input the sucralose aqueous solution into the concentration tank V-3 for concentration, the concentration temperature is 55°C, the vacuum degree is -0.1Mpa, the concentrated sucralose concentration is 125g/L, and then the concentrated solution is input into the crystallization tank V-4 Crystallization at room temperature, sucralose mother liquor was reused 4 times, and the purity of sucralose after drying is shown in Table 8.
- the existing process for preparing sucralose from sucralose-6-acetate is a batch process, which mainly neutralizes the chlorinated liquid, then purifies to obtain sucralose-6-acetate, and then uses sucralose-6- Pure acetate as raw material is hydrolyzed into sucralose in a sodium methoxide/methanol system, and finally purified to obtain fine sucralose.
- Ethyl acetate is added to the concentrated dry aqueous solution for extraction, the water phase after extraction is used for wastewater treatment, the ester phase is concentrated until the content of sucralose-6-acetate is greater than 20wt%, and the temperature is cooled to crystallize to obtain sucralose-6-acetate The crude product is then further crystallized with ethyl acetate and water respectively to obtain the fine product of sucralose-6-acetate with a content of about 90% and a water content of about 10%.
- Sucralose-6-acetate refined product is used as raw material, sodium methoxide/methanol is added to it for hydrolysis, after hydrolysis is completed, it is extracted with butyl acetate, then the ester phase is concentrated to dryness, after concentration is dried, it is dissolved in water and concentrated to three When the concentration of sucralose reaches 20wt%, it crystallizes at room temperature, repeats twice, and applies the mother liquor 4 times.
- the purity of sucralose after drying is shown in Table 9.
- this application uses the untreated chlorinated reaction liquid obtained during the preparation of sucralose-6-ester as a raw material, and uses a neutralization reaction rectification tower to achieve neutralization and precipitation of the chlorinated liquid, and then uses hydrolytic rectification
- the tower achieves the purpose of desolvation and hydrolysis of sucralose-6-ester to prepare sucralose, and finally through extraction-oxidation-back extraction, the continuous preparation of sucralose is realized.
- This application abandons the traditional batch neutralization, Precipitation, hydrolysis, and lengthy sucralose-6-acetate purification process significantly improved the efficiency of the preparation and purification of sucralose; For neutralization, the use of ammonia water and sodium methoxide is discarded.
- sucralose reduces the pressure brought by the ammonia nitrogen content in the later biochemical treatment; on the other hand, it avoids the use and production of methanol, and is highly environmentally friendly. It is a kind of The efficient, green and continuous preparation process of sucralose has extremely high application value and practicability.
- connection should be understood in a broad sense, for example, it can be a fixed connection or a detachable connection. Connected, or integrally connected; it can be mechanically connected or electrically connected; it can be directly connected or indirectly connected through an intermediary, and it can be the internal communication of two components. Those of ordinary skill in the art can understand the specific meanings of the above terms in this application in specific situations.
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Abstract
Provided is a method for preparing sucralose. The method comprises the steps of: feeding a chlorination reaction solution for preparing sucralose-6 ester, a first liquid alkali and first reuse water into a neutralization reaction rectifying column in sections, subjecting same to a neutralization reaction under evaporation conditions, and then extracting a solvent mixture from the top of the neutralization reaction rectifying column; extracting a chlorination reaction neutralization solution from the bottom of the neutralization reaction rectifying column; feeding the chlorination reaction neutralization solution, a second liquid alkali and second reuse water into a hydrolysis reaction rectifying column in sections, subjecting same to an alkaline hydrolysis reaction under evaporation conditions, extracting a waste aqueous solution from the top of the hydrolysis reaction rectifying column, and extracting a sucralose aqueous solution from the bottom of the hydrolysis reaction rectifying column; adjusting the sucralose aqueous solution to be neutral, then successively subjecting same to extraction, oxidation and back extraction for purification; and crystallization.
Description
本发明属于精细化工技术领域,具体涉及一种三氯蔗糖的制备方法。The invention belongs to the technical field of fine chemicals, and in particular relates to a preparation method of sucralose.
发明背景Background of the invention
三氯蔗糖,俗称蔗糖素,外观为白色结晶粉末或颗粒,甜度约为蔗糖的600倍,作为新一代的甜味剂,三氯蔗糖是唯一一种以蔗糖为原料,口感纯正,无热量,不参与人体新陈代谢,可供糖尿病人,心脑血管疾病患者及老年人使用的“零卡”糖。产品具有稳定性高、耐酸碱、耐高温、货架期长、安全性高等特点,广泛应用于食品、饮料、日化、医药等多个领域。Sucralose, commonly known as sucralose, is white crystalline powder or granules in appearance, and its sweetness is about 600 times that of sucrose. As a new generation of sweetener, sucralose is the only one that uses sucrose as raw material. Calorie, does not participate in human metabolism, can be used by diabetics, patients with cardiovascular and cerebrovascular diseases and the elderly as "zero-calorie" sugar. The products have the characteristics of high stability, acid and alkali resistance, high temperature resistance, long shelf life and high safety, and are widely used in food, beverage, daily chemical, pharmaceutical and other fields.
三氯蔗糖-6-酯是制备三氯蔗糖的重要中间体之一,其由蔗糖-6-酯与氯化试剂在高温下氯化得来,由于氯化过程中会产生大量副产物及杂质,这些副产物和杂质影响终产品三氯蔗糖的纯度,在现有技术中,想要获得纯净的三氯蔗糖,通常需要经过中和、浓干、萃取结晶、酯结、水结、醇解、提纯、浓缩、结晶等操作对生产三氯蔗糖-6-酯氯代中和液进行处提纯,该过程连续性差,人工操作繁琐,氨水使用量大,后期生化处理困难。Sucralose-6-ester is one of the important intermediates for the preparation of sucralose, which is obtained by chlorination of sucralose-6-ester and chlorination reagent at high temperature, because a large number of by-products and impurities will be produced during the chlorination process , these by-products and impurities affect the purity of the final product sucralose. In the prior art, to obtain pure sucralose usually requires neutralization, concentrated drying, extraction crystallization, ester knot, water knot, alcoholysis , Purification, concentration, crystallization and other operations to purify the chlorinated neutralization solution for the production of sucralose-6-ester, the process has poor continuity, cumbersome manual operation, large amount of ammonia water, and difficult biochemical treatment in the later stage.
目前也有关于连续式或一锅法由含三氯蔗糖-6-乙酸酯的氯化液制备三氯蔗糖的方法的报道,如中国专利CN103113426报道了一种以蔗糖,硼酐为原料一锅法制备三氯蔗糖的工艺,工艺中制备成硼酸六氯二蔗糖酯,经饱和无机盐水溶液水解硼酸六氯二蔗糖酯得到三氯蔗糖,再经乙酸乙酯萃取,无水硫酸钠干燥,过滤后得到含三氯蔗糖的乙酸乙酯溶液,再经95wt%的乙醇,活性炭脱色,过滤。最后滤液结晶得到三氯蔗糖纯品。该法虽然连续性强,收率高,但使用硼酐作为原料,成本高,回收困难,后续废水处理难度大,工业化前景渺茫。综上所述,亟需一种三氯蔗糖的制备方法以解决上述问题。需要说明的是,这里的陈述仅提供与本申请有关的背景信息,而不必然地构成现有技术。At present, there are also reports about the continuous or one-pot method of preparing sucralose from chlorinated liquid containing sucralose-6-acetate, such as Chinese patent CN103113426, which reports a one-pot method using sucrose and boric anhydride as raw materials. The process of preparing sucralose by method, in which hexachlorosucrose borate is prepared, hexachlorosucrose borate is hydrolyzed by saturated inorganic salt solution to obtain sucralose, then extracted with ethyl acetate, dried over anhydrous sodium sulfate, filtered Finally, an ethyl acetate solution containing sucralose was obtained, and then decolorized by 95 wt% ethanol and activated carbon, and then filtered. Finally, the filtrate was crystallized to obtain pure sucralose. Although this method has strong continuity and high yield, it uses boric anhydride as a raw material, which is costly, difficult to recycle, difficult to follow-up wastewater treatment, and has little prospect for industrialization. In summary, there is an urgent need for a preparation method of sucralose to solve the above problems. It should be noted that the statements herein only provide background information related to the present application and do not necessarily constitute prior art.
发明内容Contents of the invention
鉴于现有技术,提供了一种三氯蔗糖的制备方法,该方法摒弃了传统的间歇中和、脱溶、水解,以及冗长的三氯蔗糖-6-乙酸酯提纯工艺,实现了三氯蔗糖的连续制备,以克服现有技术中的不足。In view of the existing technology, a preparation method of sucralose is provided, which abandons the traditional intermittent neutralization, precipitation, hydrolysis, and lengthy sucralose-6-acetate purification process, and realizes the sucralose Continuous preparation of sucrose to overcome the deficiencies in the prior art.
根据本申请的第一方面,提供了一种三氯蔗糖的制备方法,包括:According to the first aspect of the present application, a method for preparing sucralose is provided, comprising:
中和步骤:使制备三氯蔗糖-6酯的氯化反应液,第一液碱和第一回用水分段进入中和反应精馏塔,在蒸发条件下进行中和反应后,从中和反应精馏的塔顶采出溶剂混合物;从中和反应精馏的塔底采出氯化反应中和液;Neutralization step: make the chlorination reaction solution for preparing sucralose-6 ester, the first liquid caustic soda and the first reused water enter the neutralization reaction distillation tower in sections, and after the neutralization reaction is carried out under the evaporation condition, from the neutralization reaction Extract the solvent mixture from the top of the rectifying tower; extract the chlorination reaction neutralizing liquid from the bottom of the column of the neutralization reaction rectification;
水解步骤:使氯化反应中和液、第二液碱和第二回用水分段进入水解反应精馏塔,在蒸发条件下进行碱性水解反应,从水解反应精馏塔的塔顶采出废弃水溶液,从水解反应精馏塔的塔底采出三氯蔗糖水溶液;Hydrolysis step: make the chlorination reaction neutralization liquid, the second liquid alkali and the second recycled water enter the hydrolysis reaction rectification tower, carry out the alkaline hydrolysis reaction under the evaporation condition, and extract from the top of the hydrolysis reaction rectification tower The aqueous solution is discarded, and the sucralose aqueous solution is extracted from the bottom of the hydrolysis reaction distillation tower;
萃取提纯步骤:将三氯蔗糖水溶液调节至中性后,依次进行萃取、氧化和反萃取以进行提纯;和Extraction and purification step: after adjusting the sucralose aqueous solution to neutrality, sequentially perform extraction, oxidation and back extraction for purification; and
结晶步骤:将提纯后的三氯蔗糖水溶液经浓缩、结晶、过滤,得到三氯蔗糖粗产品和结晶母液。Crystallization step: Concentrate, crystallize and filter the purified sucralose aqueous solution to obtain crude sucralose product and crystallization mother liquor.
可选的,上述方法还包括:Optionally, the above method also includes:
母液循环回收步骤:将结晶母液回收至要进入结晶步骤的三氯蔗糖水溶液中,回收次数为1~5次。Mother liquor circulation recovery step: the crystallization mother liquor is recycled into the sucralose aqueous solution to enter the crystallization step, and the number of recycling is 1 to 5 times.
可选的,在上述方法中,中和反应精馏塔的塔高为10~30m;Optionally, in the above method, the height of the neutralization reactive distillation tower is 10-30m;
氯化反应液进料位置处于距离塔顶为塔高的3/10~2/5的位置,第一液碱的进料位置处于距离塔顶为塔高的1/2~3/5的位置,第一回用水的进料位置处于距离塔顶为塔高的7/10~4/5的位置。The feeding position of the chlorination reaction liquid is at a position of 3/10 to 2/5 of the height of the tower from the top of the tower, and the feeding position of the first liquid alkali is at a position of 1/2 to 3/5 of the height of the tower from the top of the tower , the feeding position of the first recycled water is at a position of 7/10 to 4/5 of the tower height from the top of the tower.
可选的,在上述方法中,在中和步骤中,在进行中和反应时,将中和反应精馏塔的塔顶温度设为30~40℃,塔底温度设为50~60℃。Optionally, in the above method, in the neutralization step, during the neutralization reaction, the top temperature of the neutralization reaction distillation tower is set to 30-40°C, and the bottom temperature is set to 50-60°C.
可选的,在上述方法中,在水解步骤中,水解反应精馏塔的塔高为10~30m;Optionally, in the above method, in the hydrolysis step, the tower height of the hydrolysis reaction distillation tower is 10-30m;
氯化液中和液进料位置处于距离塔顶为塔高的2/5~3/7的位置,第二液碱的进料位置处于距离塔顶为塔高的1/2~3/5的位置,第二回用水的进料位置处于距离塔顶为塔高的4/5~9/10的位置。The feed position of the chlorinated liquid neutralizing liquid is 2/5 to 3/7 of the height of the tower from the top of the tower, and the feed position of the second liquid alkali is 1/2 to 3/5 of the height of the tower from the top of the tower The position of the feed of the second return water is at a position of 4/5 to 9/10 of the height of the tower from the top of the tower.
可选的,在上述方法中,在水解步骤中,在进行水解反应时,将中和反应精馏塔的塔顶温度设为30~40℃,塔底温度设为50~60℃。Optionally, in the above method, in the hydrolysis step, during the hydrolysis reaction, the temperature at the top of the neutralization reaction distillation column is set at 30-40°C, and the temperature at the bottom of the column is set at 50-60°C.
可选的,在上述方法中,中和反应精馏塔和水解反应精馏塔均为填料塔或板式塔,优选为填料塔,其中,填料塔中的填料为聚四氟波纹板或θ环,填料高度为填料塔塔高的1/3~2/3。Optionally, in the above method, both the neutralization reaction rectification tower and the hydrolysis reaction rectification tower are packed towers or plate towers, preferably packed towers, wherein the filler in the packed tower is polytetrafluoro corrugated plate or θ ring , The height of the packing is 1/3~2/3 of the height of the packed tower.
可选的,在上述方法中,在中和步骤中,氯化反应液、第一液碱和第一回用水的体积比为10~15:1:1;Optionally, in the above method, in the neutralization step, the volume ratio of the chlorination reaction solution, the first liquid caustic soda and the first recycled water is 10-15:1:1;
在水解步骤中,氯化反应中和液、第二液碱和第二回用水的体积比为 40~60:1:10~20。In the hydrolysis step, the volume ratio of the chlorination reaction neutralizing solution, the second liquid caustic soda and the second recycled water is 40-60:1:10-20.
可选的,在上述方法中,第一液碱和第二液碱均为氢氧化钠或氢氧化钾的水溶液,优选为氢氧化钠的水溶液。Optionally, in the above method, both the first liquid alkali and the second liquid alkali are aqueous solutions of sodium hydroxide or potassium hydroxide, preferably aqueous solutions of sodium hydroxide.
可选的,在上述方法中,在萃取提纯步骤中,将三氯蔗糖水溶液调节至中性包括:Optionally, in the above method, in the extraction and purification step, adjusting the sucralose aqueous solution to neutrality includes:
采用无机酸将三氯蔗糖水溶液的pH值调节至6~8,其中无机酸为盐酸、硫酸或磷酸中的一种。The pH value of the sucralose aqueous solution is adjusted to 6-8 by adopting inorganic acid, wherein the inorganic acid is one of hydrochloric acid, sulfuric acid or phosphoric acid.
可选的,在上述方法中,在萃取提纯步骤中,进行萃取所用的萃取剂为乙酸乙酯和/或乙酸丁酯;Optionally, in the above method, in the extraction and purification step, the extractant used for extraction is ethyl acetate and/or butyl acetate;
萃取剂的体积用量与氯化反应中和液的比为1~5:1。The ratio of the volumetric dosage of the extractant to the neutralizing solution for the chlorination reaction is 1-5:1.
可选的,在上述方法中,在萃取提纯步骤中,氧化所用的氧化剂为次氯酸钠或臭氧;其中,次氯酸钠的质量用量为萃取得到的有机相的体积的0.01~0.1%;臭氧的体积用量为萃取得到的有机相的体积的0.01~0.1%;Optionally, in the above method, in the extraction and purification step, the oxidant used for oxidation is sodium hypochlorite or ozone; wherein, the mass dosage of sodium hypochlorite is 0.01% to 0.1% of the volume of the organic phase obtained by extraction; the volume dosage of ozone is 0.01 to 0.1% of the volume of the obtained organic phase;
氧化的氧化时间为3~12h。The oxidation time for oxidation is 3-12 hours.
可选的,在上述方法中,在萃取提纯步骤中,反萃取的反萃取剂为水,反萃取剂的体积用量与萃取得到的有机相的体积的比为1~5:1。Optionally, in the above method, in the extraction and purification step, the back-extraction agent for back-extraction is water, and the volume ratio of the back-extraction agent to the volume of the extracted organic phase is 1-5:1.
可选的,在上述方法中,在结晶步骤中,浓缩的浓缩温度为40~60℃,浓缩真空度为-0.1~-0.5Mpa,浓缩至三氯蔗糖水溶液中三氯蔗糖浓度为80~140g/L。Optionally, in the above method, in the crystallization step, the concentration temperature is 40-60°C, the concentration vacuum is -0.1--0.5Mpa, and the sucralose concentration in the sucralose aqueous solution is 80-140g /L.
本申请的有益效果在于,本申请采用制备三氯蔗糖-6-酯时得到的未处理氯化反应液为原料,采用中和反应精馏塔实现氯化液中和、脱溶,然后使用水解精馏塔实现脱溶、以及三氯蔗糖-6-酯的水解制备三氯蔗糖的目的,最后经萃取-氧化-反萃取,实现了三氯蔗糖的连续制备,本申请摒弃了传统的间歇中和、脱溶、水解、以及冗长的三氯蔗糖-6-乙酸酯提纯工艺,显著提高了三氯蔗糖的制备和提纯的效率;且相对于现有技术,该申请采用液碱对氯化反应液进行中和,舍弃了氨水、以及甲醇钠的使用,一方面降低了后期生化处理中,氨氮含量带来的压力;另一方面避免了甲醇的使用和产生,对环境友好性高,是一种高效、绿色、连续的三氯蔗糖制备工艺,具有极高的应用价值和实用性。The beneficial effect of the present application is that the present application uses the untreated chlorinated reaction liquid obtained during the preparation of sucralose-6-ester as a raw material, and uses a neutralization reaction rectification tower to realize the neutralization and precipitation of the chlorinated liquid, and then uses the hydrolysis The rectification tower achieves the purpose of desolvation and hydrolysis of sucralose-6-ester to prepare sucralose, and finally through extraction-oxidation-back extraction, the continuous preparation of sucralose is realized. This application abandons the traditional batch process And, precipitation, hydrolysis, and lengthy sucralose-6-acetate purification process, significantly improved the efficiency of the preparation and purification of sucralose; and compared with the prior art, the application uses liquid caustic soda to The reaction solution is neutralized, and the use of ammonia water and sodium methoxide is discarded. On the one hand, it reduces the pressure brought by the ammonia nitrogen content in the later biochemical treatment; on the other hand, it avoids the use and production of methanol, which is highly environmentally friendly and is An efficient, green and continuous sucralose preparation process has extremely high application value and practicability.
上述说明仅是本申请技术方案的概述,为了能够更清楚了解本申请的技术手段,而可依照说明书的内容予以实施,并且为了让本申请的上述和其它目的、特征和优点能够更明显易懂,以下特举本申请的具体实施方式。The above description is only an overview of the technical solution of the present application. In order to better understand the technical means of the present application, it can be implemented according to the contents of the description, and in order to make the above and other purposes, features and advantages of the present application more obvious and understandable , the following specifically cites the specific implementation manner of the present application.
附图简要说明Brief description of the drawings
通过阅读下文优选实施方式的详细描述,各种其他的优点和益处对于本领域普通技术人员将变得清楚明了。附图仅用于示出优选实施方式的目的,而并不认为是对本申请的限制。而且在整个附图中,用相同的参考符号表示相同的部件。在附图中:Various other advantages and benefits will become apparent to those of ordinary skill in the art upon reading the following detailed description of the preferred embodiment. The drawings are only for the purpose of illustrating the preferred embodiments and are not to be considered as limiting the application. Also throughout the drawings, the same reference numerals are used to designate the same components. In the attached picture:
图1示出了根据本申请的一个实施例的制备三氯蔗糖的设备的结构示意图;Figure 1 shows a schematic structural view of a device for preparing sucralose according to an embodiment of the present application;
图2示出了根据本申请的一个实施例的三氯蔗糖-6-酯的制备方法的流程示意图。Fig. 2 shows a schematic flow diagram of a method for preparing sucralose-6-ester according to an embodiment of the present application.
实施本发明的方式Modes of Carrying Out the Invention
申请人通过对传统方法由氯化反应液制备三氯蔗糖的生产工艺的研究发现:氯化反应液中的三氯蔗糖-6-酯必须在经过碱中和后方能释放出来,未经中和的氯化反应液是无法获得三氯蔗糖-6-酯,并以此制备三氯蔗糖的;在中和完毕后必须将DMF和三氯乙烷等溶剂蒸发出来,防止在后期碱性水解制备三氯蔗糖的过程中导致DMF的分解;在三氯蔗糖-6-酯制备三氯蔗糖的工艺流程中必须存在提纯操作,否则三氯蔗糖纯品无法顺利通过结晶获得,母液无法回收利用。The applicant found through research on the production process of sucralose prepared from the chlorination reaction solution by the traditional method: the sucralose-6-ester in the chlorination reaction solution must be released after being neutralized by alkali. Sucralose-6-ester cannot be obtained from the chlorination reaction solution, and sucralose can be prepared from it; after neutralization, solvents such as DMF and trichloroethane must be evaporated to prevent alkaline hydrolysis in the later stage. The process of sucralose leads to the decomposition of DMF; there must be a purification operation in the process of preparing sucralose from sucralose-6-ester, otherwise the pure product of sucralose cannot be successfully obtained through crystallization, and the mother liquor cannot be recycled.
因而,采用传统工艺制备三氯蔗糖的过程中,中和过程当中使用的氨水会导致后期生化处理氨氮压力大,甲醇钠及甲醇的使用会影响后期产品结晶品质;提纯过程需要经过大量复杂的提纯工艺,存在操作复杂、连续化程度低、经济和时间成本高、三氯蔗糖收率低的缺陷。Therefore, in the process of preparing sucralose by adopting the traditional process, the ammonia water used in the neutralization process will lead to high pressure of ammonia nitrogen in the later biochemical treatment, and the use of sodium methoxide and methanol will affect the crystallization quality of the later product; the purification process requires a lot of complicated purification The technology has the defects of complex operation, low degree of continuity, high economic and time costs, and low yield of sucralose.
针对上述问题,本申请提出了一种三氯蔗糖的连续制备方法,其技术构思是:通过两级反应精馏塔,将中和及脱溶有效结合,将脱溶及水解有效结合,提高工艺的连续性,降低操作难度及生产成本;采用液碱作中和及水解剂,降低后期生化处理氨氮的难度,及甲醇/甲醇钠对后期产品结晶品质的影响;采用萃取-氧化-反萃取的提纯工艺,确保三氯蔗糖的结晶效率,经以上步骤处理含有三氯蔗糖-6-乙酸酯的氯化液之后,即可获得较为纯净的三氯蔗糖产品。In view of the above problems, the present application proposes a continuous preparation method of sucralose. The technical concept is: through a two-stage reactive distillation tower, effectively combine neutralization and precipitating, effectively combine precipitating and hydrolysis, and improve the process continuity, reducing operation difficulty and production cost; using liquid caustic soda as neutralization and hydrolysis agent, reducing the difficulty of biochemical treatment of ammonia nitrogen in the later stage, and the influence of methanol/sodium methoxide on the crystallization quality of later products; using extraction-oxidation-stripping The purification process ensures the crystallization efficiency of sucralose. After the above steps are used to treat the chlorinated solution containing sucralose-6-acetate, a relatively pure sucralose product can be obtained.
本申请对于用于实现本申请提供的方法的设备不作限制,本领域技术人员可根据工艺流程选择,图1示出了根据本申请的一个实施例的制备三氯蔗糖的设备的结构示意图,图1给出的设备仅作为示例性说明,不对本申请构成限制。如1所示,图1所示的三氯蔗糖的设备100包括:依次连接的中和反应精馏塔R-1、水解反应精馏塔R-2、pH调节釜V-1、转盘萃取塔R-3、氧化釜V-2、转盘萃取塔R-4、浓 缩釜V-3、结晶釜V-4和板框压滤机E-1。The present application does not limit the equipment used to implement the method provided by the application. Those skilled in the art can choose according to the process flow. Figure 1 shows a schematic structural diagram of the equipment for preparing sucralose according to an embodiment of the application. The equipment given in 1 is for illustrative purposes only and does not limit the application. As shown in 1, the equipment 100 for sucralose shown in FIG. 1 includes: a neutralization reaction rectification tower R-1, a hydrolysis reaction rectification tower R-2, a pH adjustment tank V-1, and a rotating disk extraction tower connected in sequence R-3, oxidation kettle V-2, rotary disk extraction tower R-4, concentration kettle V-3, crystallization kettle V-4 and plate and frame filter press E-1.
图2示出了根据本申请的一个实施例的三氯蔗糖的制备方法的流程示意图,从图2可以看出,该方法至少包括步骤S210~步骤S240:Fig. 2 shows a schematic flow chart of a method for preparing sucralose according to an embodiment of the present application. It can be seen from Fig. 2 that the method at least includes steps S210 to S240:
中和步骤S210:使制备三氯蔗糖-6酯的氯化反应液、第一液碱和第一回用水分段进入中和反应精馏塔,在蒸发条件下进行中和反应后,从中和反应精馏的塔顶采出溶剂混合物;从中和反应精馏的塔底采出氯化反应中和液。Neutralization step S210: the chlorination reaction solution for preparing sucralose-6 ester, the first liquid caustic soda and the first reused water are put into the neutralization reaction distillation tower in sections, and after the neutralization reaction is carried out under evaporation conditions, the neutralization The solvent mixture is extracted from the top of the reactive distillation tower; the chlorination reaction neutralizing liquid is extracted from the bottom of the neutralized reactive distillation column.
从图1可以看出,中和反应精馏塔R-1包括三个进料段,上段为氯化反应液进料段、中间段为第一液碱进料段、下段为第一回用水进料段。As can be seen from Figure 1, the neutralization reaction rectification tower R-1 includes three feeding sections, the upper section is the chlorination reaction liquid feeding section, the middle section is the first liquid alkali feeding section, and the lower section is the first recycled water Feed section.
本申请中的氯代反应液为蔗糖-6-羧酸酯与氯化试剂进行氯代反应,得到的反应物混合溶液,称为氯代反应液。本申请适用于用现有技术中各种方法制备三氯蔗糖中氯代反应阶段产生的反应液,如单基团保护法、多基团保护法等,对于蔗糖-6-羧酸酯氯代反应液的来源本申请不做限制,可为实验室或工业生产中的制备三氯蔗糖中氯代反应阶段产生的反应液。The chlorination reaction solution in the present application is a chlorination reaction between sucrose-6-carboxylate and a chlorination reagent, and the resulting mixed solution of reactants is called a chlorination reaction solution. This application is suitable for preparing the reaction solution produced in the chlorination reaction stage of sucralose by various methods in the prior art, such as single-group protection method, multi-group protection method, etc., for the chlorination of sucrose-6-carboxylate The source of the reaction solution is not limited in the present application, and it may be the reaction solution produced in the chlorination reaction stage in the preparation of sucralose in the laboratory or in industrial production.
由于在氯代反应过程中,使用了强的氯代试剂,如氯化亚砜和光气等,在氯代保温阶段温度高,会产生一系列的副产物,如一氯代蔗糖-6-羧酸酯、二氯代蔗糖-6-羧酸酯、四氯代蔗糖-6-羧酸酯、三氯蔗糖双酯等,还含有一些有机杂质如N,N-二甲基甲酰胺(DMF)和三氯乙烷,以及大量的水。Due to the use of strong chlorination reagents, such as thionyl chloride and phosgene, during the chlorination reaction, the high temperature in the chlorination insulation stage will produce a series of by-products, such as monochlorosucrose-6-carboxylic acid ester, dichlorosucrose-6-carboxylate, tetrachlorosucrose-6-carboxylate, sucralose diester, etc., also contains some organic impurities such as N,N-dimethylformamide (DMF) and trichloroethane, and large quantities of water.
目前,现有技术中,对蔗糖-6-羧酸酯氯代反应液的中和通常采用氨水或直接采用氨气,氨水或氨气的使用,使得体系中增加了大量的氮元素,不利于后续废液的分离和回收。At present, in the prior art, the neutralization of sucrose-6-carboxylate chlorination reaction solution usually adopts ammonia water or directly adopts ammonia gas, and the use of ammonia water or ammonia gas increases a large amount of nitrogen elements in the system, which is not conducive to Subsequent separation and recovery of waste liquid.
区别于现有技术,在本申请中,采用液碱代替氨水或氨气,在本申请的一些实施例中,液碱可通过将氢氧化钠和氢氧化钾溶解于水获得,也可以直接采用市售产品,如32wt%的氢氧化钠溶液。Different from the prior art, in this application, liquid caustic soda is used instead of ammonia water or ammonia gas. In some embodiments of this application, liquid caustic soda can be obtained by dissolving sodium hydroxide and potassium hydroxide in water, or can be directly used Commercially available products, such as 32wt% sodium hydroxide solution.
在本申请中,出于经济考虑,采用回用水作为水源,从中和反应精馏塔的下段进入。之所以加入第一回用水,是由于水与DMF能够混溶,在将第一回用水从液态水蒸发成气态的过程中,第一回用水能够快速将DMF带出。In this application, due to economical considerations, reused water is used as the water source, which enters from the lower section of the neutralization reaction distillation tower. The reason why the first water is added is that water and DMF are miscible. During the process of evaporating the first water from liquid water to gaseous state, the first water can quickly take out the DMF.
在中和反应过程中,氯化反应液选择中和反应精馏塔上段进料的目的是为了物料进入中和反应精馏塔后,率先蒸发去除三氯乙烷溶剂(三氯乙烷沸点低,75℃,不溶于水),第一液碱从中段进料是为确保氯化反应液能够完全被中和,第一回用水从下段进料,是利用其与DMF共沸特性,提高DMF的脱除效率。In the neutralization reaction process, the purpose of selecting the upper section of the neutralization reaction rectification tower for the chlorination reaction liquid is to first evaporate and remove the trichloroethane solvent (trichloroethane with a low boiling point) after the material enters the neutralization reaction rectification tower. , 75°C, insoluble in water), the first liquid caustic soda is fed from the middle stage to ensure that the chlorination reaction liquid can be completely neutralized, and the first recycled water is fed from the lower stage to make use of its azeotropic characteristics with DMF to increase the DMF removal efficiency.
氯化反应液是酸性的,氯化反应液、第一液碱和第一回用水在中和反应精馏塔 中发生中和反应,三氯蔗糖-6-酯被释放出来,在现有技术中,三氯蔗糖-6-乙酸酯的应用最广,以下以三氯蔗糖-6-乙酸酯为例。The chlorination reaction solution is acidic, and the chlorination reaction solution, the first liquid alkali and the first recycled water undergo a neutralization reaction in the neutralization reaction distillation tower, and the sucralose-6-ester is released. In the prior art Among them, sucralose-6-acetate is the most widely used, and the following is an example of sucralose-6-acetate.
在中和反应的同时,可采用蒸发等手段除去溶剂,溶剂主要为DMF、三氯乙烷,以及大量的水形成的混合溶剂,在本申请的一些实施例中,可采用真空泵降低中和反应精馏塔的压力,以促进混合溶剂的蒸发。At the same time of the neutralization reaction, the solvent can be removed by evaporation and other means. The solvent is mainly DMF, trichloroethane, and a mixed solvent formed by a large amount of water. In some embodiments of the application, a vacuum pump can be used to reduce the neutralization reaction. The pressure of the rectification column to promote the evaporation of mixed solvents.
氯化反应液与第一液碱反应后,绝大部分混合溶剂被除去,得到的剩余溶液称为氯化反应中和液。After the chlorination reaction solution reacts with the first liquid caustic soda, most of the mixed solvent is removed, and the remaining solution obtained is called chlorination reaction neutralization solution.
水解步骤S220:使氯化反应中和液、第二液碱和第二回用水分段进入水解反应精馏塔,在蒸发条件下进行碱性水解反应,从水解反应精馏塔的塔顶采出废弃水溶液,从水解反应精馏塔的塔底采出三氯蔗糖水溶液。Hydrolysis step S220: Make the chlorination reaction neutralization liquid, the second liquid alkali and the second reused water enter the hydrolysis reaction rectification tower in stages, and carry out the alkaline hydrolysis reaction under the evaporation condition, and extract from the top of the hydrolysis reaction rectification tower The waste aqueous solution is extracted, and the sucralose aqueous solution is extracted from the bottom of the hydrolysis reaction distillation tower.
然后使氯化反应中和液、第二液碱和第二回用水分段进入水解反应精馏塔R-2,从图1中可以看出,水解反应精馏塔R-2包括三个进料段,上段为氯化反应中和液进料段、中间段为第二液碱进料段、下段为第二回用水进料段。Then make the chlorination reaction neutralizing liquid, the second liquid caustic soda and the second reused water section enter the hydrolysis reaction rectification tower R-2, as can be seen from Fig. 1, the hydrolysis reaction rectification tower R-2 comprises three processes In the feeding section, the upper section is the chlorination reaction neutralization liquid feeding section, the middle section is the second liquid alkali feeding section, and the lower section is the second recycled water feeding section.
在水解反应过程中,氯化反应中和液选择从水解反应精馏塔上段进料的目的是为了物料进入中和反应精馏塔后,率先蒸发去除残存的三氯乙烷溶剂,第二液碱从中段进料是为确保氯化反应中和液能够完全被水解,第二回用水从下段进料,是利用其与DMF共沸特性,提高DMF的脱除效率。In the process of hydrolysis reaction, the purpose of selecting the feed from the upper section of the hydrolysis reaction distillation tower for the chlorination reaction neutralization liquid is to first evaporate and remove the remaining trichloroethane solvent after the material enters the neutralization reaction rectification tower, and the second liquid Alkali is fed from the middle section to ensure that the neutralization liquid in the chlorination reaction can be completely hydrolyzed, and the second reuse water is fed from the lower section to improve the removal efficiency of DMF by utilizing its azeotropic characteristics with DMF.
氯化反应中和液在第二液碱存在的条件下进行碱性水解反应,且在碱性水解的过程中,同时采用蒸发手段使得混合溶剂进一步蒸发,水解反应后,三氯蔗糖-6-酯完成水解生成三氯蔗糖。The chlorination reaction neutralizing liquid is subjected to alkaline hydrolysis reaction in the presence of the second liquid alkali, and in the process of alkaline hydrolysis, evaporation means are used to further evaporate the mixed solvent. After the hydrolysis reaction, sucralose-6- Esters complete hydrolysis to sucralose.
第二回用水与第一回用水的作用一致,第二回用水与混合溶剂生成废弃水溶液,可从水解反应精馏塔的塔顶采出。The function of the second recycling water is the same as that of the first recycling water, and the second recycling water and the mixed solvent generate a waste aqueous solution, which can be extracted from the top of the hydrolysis reaction distillation tower.
通过中和步骤和水解步骤相结合,将三氯蔗糖-6-酯中从氯代反应液中释放出来,并除去其中的DMF和三氯乙烷等溶剂,从而将三氯蔗糖-6-乙酸酯水解成三氯蔗糖,实现了中和、脱溶、水解的连续性操作。Through the combination of the neutralization step and the hydrolysis step, the sucralose-6-ester is released from the chlorination reaction solution, and solvents such as DMF and trichloroethane are removed, so that the sucralose-6-ethyl The acid ester is hydrolyzed into sucralose, realizing the continuous operation of neutralization, solvent removal and hydrolysis.
萃取提纯步骤S230:将三氯蔗糖水溶液调节至中性后,依次进行萃取、氧化和反萃取以进行提纯。Extraction and purification step S230: After adjusting the sucralose aqueous solution to neutrality, extraction, oxidation and back extraction are performed in sequence for purification.
得到的三氯蔗糖水溶液包括但不限于目标产物三氯蔗糖、有机酯杂质、未完全蒸发的有机溶剂,以及碱离子。由于液碱的存在,三氯蔗糖水溶液是碱性的,可采用酸性物质调节至中性。需要说明的是,在本申请中,“中性”并不是指严格意义上的pH=7,pH值在7附近,如pH=6~8均可以认为是中性。在本申请的一些实施例 中,采用无机酸将三氯蔗糖水溶液的pH值调节至6~8,其中无机酸为盐酸、硫酸或磷酸中的一种。The obtained sucralose aqueous solution includes but not limited to the target product sucralose, organic ester impurities, incompletely evaporated organic solvents, and alkali ions. Due to the presence of liquid caustic soda, the aqueous solution of sucralose is alkaline and can be adjusted to neutrality with acidic substances. It should be noted that in this application, "neutral" does not mean pH=7 in the strict sense, and pH values around 7, such as pH=6-8, can be considered as neutral. In some embodiments of the present application, the pH value of the sucralose aqueous solution is adjusted to 6-8 by using an inorganic acid, wherein the inorganic acid is one of hydrochloric acid, sulfuric acid or phosphoric acid.
然后依次采用萃取、氧化和反萃取的流程,对三氯蔗糖水溶液进行处理。萃取,又称溶剂萃取或液液萃取,亦称抽提,是利用系统中组分在溶剂中有不同的溶解度来分离混合物的单元操作;即,是利用物质在两种互不相溶(或微溶)的溶剂中溶解度或分配系数的不同,使溶质物质从一种溶剂内转移到另外一种溶剂中的方法。在本申请中,萃取所用的萃取剂为有机酯,如乙酸乙酯和/或乙酸丁酯,三氯蔗糖水溶液中的,溶解于萃取剂的目标产物三氯蔗糖和与三氯蔗糖结构类似的有机酯被萃取到萃取剂中,将萃取得到的水相去废水处理,得到的有机相进行后续步骤。Then, the aqueous solution of sucralose is treated by successively adopting the processes of extraction, oxidation and stripping. Extraction, also known as solvent extraction or liquid-liquid extraction, also known as extraction, is a unit operation that uses the different solubility of the components in the system to separate the mixture; A method in which a solute substance is transferred from one solvent to another due to the difference in solubility or partition coefficient in a slightly soluble solvent. In the present application, the extractant used for extraction is organic ester, such as ethyl acetate and/or butyl acetate, sucralose in aqueous solution, the target product sucralose dissolved in the extractant and sucralose similar in structure The organic ester is extracted into the extractant, the aqueous phase obtained by extraction is sent to waste water treatment, and the obtained organic phase is subjected to subsequent steps.
然后在得到的有机相中加入氧化剂,氧化剂的目的是为了将有机酯杂质如四氯代蔗糖等氧化为目标产物三氯蔗糖,从而达到极大提高三氯蔗糖的收率的目的。Then, an oxidizing agent is added to the obtained organic phase. The purpose of the oxidizing agent is to oxidize organic ester impurities such as sucralose tetrachloride to the target product sucralose, thereby achieving the purpose of greatly increasing the yield of sucralose.
在氧化反应完成后,进行反萃取,所谓反萃取是用反萃取剂使被萃取物从负载有机相返回水相的过程,为萃取的逆过程,通过反萃取,使得三氯蔗糖从萃取过程得到的有机相中转移至反萃取剂中,在本申请的一些实施例中,可采用水或去离子水作为反萃取剂,尤其采用去离子水更加有利于后续结晶效果。通过萃取提纯步骤,确保了三氯蔗糖的纯度,赋予了该方法的可行性。After the oxidation reaction is completed, back extraction is carried out. The so-called back extraction is the process of returning the extract from the loaded organic phase to the water phase with a back extraction agent. It is the reverse process of extraction. Through back extraction, the sucralose can be obtained from the extraction process. The organic phase is transferred to the stripping agent. In some embodiments of the present application, water or deionized water can be used as the stripping agent, especially the use of deionized water is more conducive to the subsequent crystallization effect. Through the extraction and purification steps, the purity of the sucralose is ensured, which endows the feasibility of the method.
和结晶步骤S240:将提纯后的三氯蔗糖水溶液经浓缩、结晶、过滤,得到三氯蔗糖粗产品和结晶母液。And crystallization step S240: Concentrate, crystallize and filter the purified sucralose aqueous solution to obtain crude sucralose product and crystallization mother liquor.
最后,将纯后的三氯蔗糖水溶液经过结晶步骤,即可得到三氯蔗糖粗产品和剩余的一次结晶母液。对于结晶方法和条件,可参考现有技术,包括但不限于采用浓缩、结晶、过滤等手段以实现结晶的目的。Finally, the purified sucralose aqueous solution is subjected to a crystallization step to obtain the crude sucralose product and the remaining primary crystallization mother liquor. For crystallization methods and conditions, reference can be made to the prior art, including but not limited to the use of means such as concentration, crystallization, and filtration to achieve the purpose of crystallization.
且由于反萃取剂通常采用水,在结晶步骤中,实际为一个水结晶过程,结晶过程更加容易控制,结晶效果好。And because the stripping agent usually uses water, in the crystallization step, it is actually a water crystallization process, the crystallization process is easier to control, and the crystallization effect is good.
采用图1所示的三氯蔗糖的制备设备执行本申请提供的方法可简述如下,首先分别向中和反应精馏塔R-1上、中、下段输入氯化反应液、第一液碱及第一回用水,进行中和、脱溶操作。塔顶采出DMF,三氯乙烷及水形成的混合溶剂去溶剂分离,塔底采出氯化反应中和液输入下级水解反应精馏塔R-2;分别向R-2水解反应精馏塔上、中、下段输入氯化反应中和液、第二液碱及第二回用水,进行水解、脱溶操作。塔顶采出微量DMF和水的形成的混合物去污水处理,塔底采出三氯蔗糖水溶液输入下级中和反应釜V-1;在中和反应釜V-1中加入无机酸调节pH至中性,然后输入下级转盘萃取塔R-3;在转盘萃取塔R-3上下段分别输入三氯蔗糖水溶液及 有机酯物料作为萃取剂,从转盘萃取塔R-3的塔顶采出含有三氯蔗糖萃取液的有机相,从转盘萃取塔R-3的塔底采出高盐水;含有三氯蔗糖的有机相萃取液与氧化剂一并输入氧化釜V-2,在一定条件下反应一段时间后,输入转盘萃取塔R-4下段;向输入转盘萃取塔R-4上段输入纯水,与有机相逆流萃取,从转盘萃取塔R-4的塔顶采出有机相去溶剂回收,从转盘萃取塔R-4的塔底采出三氯蔗糖溶液去浓缩釜V-3;三氯蔗糖水溶液在浓缩釜V-3中,在一定条件下将三氯蔗糖浓缩至一定浓度后输入下级结晶釜V-4;结晶完成后,将物料输入板框压滤机E-1压滤分离,得到的固体为三氯蔗糖晶体,一次结晶母液和多次结晶母液返回浓缩釜V-3继续浓缩,反复多次后,最终的母液作为废糖水去污水处理。从图2所示的方法可以看出,本申请采用制备三氯蔗糖-6-酯时得到的未处理氯化反应液为原料,采用中和反应精馏塔实现氯化液中和、脱溶,然后使用水解精馏塔实现脱溶、以及三氯蔗糖-6-酯的水解制备三氯蔗糖的目的,最后经萃取-氧化-反萃取,实现了三氯蔗糖的连续制备,本申请摒弃了传统的间歇中和、脱溶、水解、以及冗长的三氯蔗糖-6-乙酸酯提纯工艺,显著提高了三氯蔗糖的制备和提纯的效率;且相对于现有技术,该申请采用液碱对氯化反应液进行中和,舍弃了氨水,以及甲醇钠的使用,一方面降低了后期生化处理中,氨氮含量带来的压力;另一方面避免了甲醇的使用和产生,对环境友好性高,是一种高效、绿色、连续的三氯蔗糖制备工艺,具有极高的应用价值和实用性。Adopt the preparation equipment of sucralose shown in Fig. 1 to carry out the method provided by the present application and can briefly describe as follows, at first respectively input chlorination reaction liquid, the first liquid alkali And the first back water for neutralization and desolvation operations. DMF is extracted from the top of the tower, and the mixed solvent formed by trichloroethane and water is desolvated and separated, and the neutralization liquid of the chlorination reaction is extracted from the bottom of the tower and input into the lower hydrolysis reaction distillation tower R-2; The upper, middle and lower sections of the tower input the chlorination reaction neutralization liquid, the second liquid caustic soda and the second recycled water for hydrolysis and solvent removal. The mixture formed by extracting a small amount of DMF and water from the top of the tower is used for sewage treatment, and the aqueous solution of sucralose is extracted from the bottom of the tower and input into the lower neutralization reactor V-1; adding inorganic acid to the neutralization reactor V-1 to adjust the pH to neutral properties, and then input to the lower rotary disk extraction tower R-3; in the upper and lower sections of the rotary disk extraction tower R-3, the sucralose aqueous solution and organic ester materials are respectively input as extraction agents, and the trichloro The organic phase of the sucrose extract is extracted from the bottom of the rotary extraction tower R-3 with high brine; the organic phase extract containing sucralose and the oxidant are input into the oxidation kettle V-2 together, and after a period of reaction under certain conditions , into the lower section of the rotary extraction tower R-4; input pure water into the upper section of the rotary disk extraction tower R-4, and extract it countercurrently with the organic phase, and extract the organic phase from the top of the rotary extraction tower R-4 to remove the solvent and recover it. The sucralose solution is extracted from the tower bottom of R-4 to the concentration tank V-3; the sucralose aqueous solution is concentrated in the concentration tank V-3, and the sucralose is concentrated to a certain concentration under certain conditions and then input to the lower crystallization tank V- 4. After the crystallization is completed, the material is input into the plate and frame filter press E-1 for pressure filtration and separation, and the obtained solid is sucralose crystals, and the primary crystallization mother liquor and multiple crystallization mother liquors are returned to the concentration tank V-3 to continue to concentrate, and repeated several times Finally, the final mother liquor is used as waste sugar water for sewage treatment. As can be seen from the method shown in Figure 2, this application uses the untreated chlorinated reaction liquid obtained when preparing sucralose-6-ester as raw material, and uses a neutralization reaction rectification tower to realize the neutralization and precipitation of the chlorinated liquid , and then use the hydrolysis rectification tower to achieve the purpose of desolventization and hydrolysis of sucralose-6-ester to prepare sucralose, and finally through extraction-oxidation-back extraction, the continuous preparation of sucralose is realized. This application abandons The traditional intermittent neutralization, precipitation, hydrolysis, and lengthy sucralose-6-acetate purification process have significantly improved the efficiency of the preparation and purification of sucralose; and compared with the prior art, this application uses liquid Alkali neutralizes the chlorination reaction liquid, abandoning the use of ammonia water and sodium methoxide, on the one hand, it reduces the pressure brought by the ammonia nitrogen content in the later biochemical treatment; on the other hand, it avoids the use and production of methanol, which is environmentally friendly It is a high-efficiency, green and continuous sucralose preparation process with high application value and practicability.
在本申请的一些实施例中,上述方法还包括:母液循环回收步骤:将结晶母液回收至要进入结晶步骤的三氯蔗糖水溶液中,回收次数为1-5次。In some embodiments of the present application, the above-mentioned method further includes: a mother liquor recycling step: recycling the crystallization mother liquor into the sucralose aqueous solution to enter the crystallization step, and the recycling times are 1-5 times.
首次结晶后留存的母液称为一次结晶母液,一次结晶母液经去除杂质后再次结晶,二次结晶后留存的母液称为二次结晶母液,二次结晶母液再次进行除杂质后可以得到少量结晶,二次结晶母液与二次结晶母液再结晶后留存的母液都称为多次结晶母液。The mother liquor retained after the first crystallization is called the primary crystallization mother liquor. The primary crystallization mother liquor is recrystallized after removing impurities, and the remaining mother liquor after the secondary crystallization is called the secondary crystallization mother liquor. A small amount of crystallization can be obtained after the secondary crystallization mother liquor removes impurities again. Both the secondary crystallization mother liquor and the mother liquor remaining after recrystallization are called multiple crystallization mother liquors.
在本申请的一些实施例中,为了进一步提高三氯蔗糖的收率,可将结晶母液多次回收,以便更加彻底的将母液中的目标产物结晶得出。In some embodiments of the present application, in order to further increase the yield of sucralose, the crystallization mother liquor can be recycled multiple times, so as to crystallize the target product in the mother liquor more thoroughly.
中和反应精馏塔Neutralization reaction distillation column
在本申请中,对中和反应精馏塔的类型不作限制,凡是能够同时实现中和、蒸馏的精馏塔即可,在一些实施例中,中和反应精馏塔可以为填料塔或板式塔。In this application, there is no limitation on the type of neutralization reaction distillation tower, any distillation tower that can realize neutralization and distillation at the same time is sufficient. In some embodiments, the neutralization reaction distillation tower can be a packed tower or plate type tower.
填料塔以填料作为气、液接触和传质的基本构件,液体在填料表面呈膜状自上而下流动,气体呈连续相自下而上与液体作递向流动,并进行气、液两相间的传质 和传热。两相的组分浓度和温度沿塔高连续变化。填料塔属于微分接触型的气、液传质设备。在本申请的一些实施例中,填料塔中的填料为聚四氟波纹板或θ环,填料高度为填料塔塔高的1/3~2/3。The packed tower uses packing as the basic component of gas-liquid contact and mass transfer. The liquid flows from top to bottom in the form of a film on the surface of the packing, and the gas flows in a continuous phase from bottom to top with the liquid, and the gas and liquid two Mass and heat transfer between phases. The component concentrations and temperatures of the two phases vary continuously along the height of the column. The packed tower is a differential contact type gas and liquid mass transfer equipment. In some embodiments of the present application, the packing in the packed tower is polytetrafluoro corrugated plate or θ ring, and the packing height is 1/3-2/3 of the height of the packed tower.
板式塔是一类用于气液或液液系统的分级接触传质设备,由圆筒形塔体和按一定间距水平装置在塔内的若干塔板组成。广泛应用于精馏和吸收,有些类型(如筛板塔)也用于萃取,还可作为反应器用于气液相反应过程。操作时(以气液系统为例),液体在重力作用下,自上而下依次流过各层塔板,至塔底排出;气体在压力差推动下,自下而上依次穿过各层塔板,至塔顶排出。每块塔板上保持着一定深度的液层,气体通过塔板分散到液层中去,进行相际接触传质。Tray tower is a kind of graded contact mass transfer equipment used in gas-liquid or liquid-liquid system. It consists of a cylindrical tower body and a number of trays installed horizontally in the tower at a certain distance. Widely used in rectification and absorption, some types (such as sieve plate column) are also used for extraction, and can also be used as a reactor for gas-liquid phase reaction process. During operation (take the gas-liquid system as an example), the liquid flows through each layer of trays from top to bottom in sequence under the action of gravity, and is discharged from the bottom of the tower; the gas is pushed through the layers from bottom to top under the push of pressure difference Tray plate, to the top of the tower to discharge. A certain depth of liquid layer is maintained on each tray, and the gas is dispersed into the liquid layer through the tray for interphase contact and mass transfer.
在本申请中,对中和反应精馏塔的规格不作限制,在一些实施例中,考虑到中和反应的效果,中和反应精馏塔的塔高为10~30m;其中,氯化反应液进料位置处于距离塔顶为塔高的3/10~2/5的位置,第一液碱的进料位置处于距离塔顶为塔高的1/2~3/5的位置,第一回用水的进料位置处于距离塔顶为塔高的7/10~4/5的位置。In this application, the specifications of the neutralization reaction distillation tower are not limited. In some embodiments, considering the effect of the neutralization reaction, the tower height of the neutralization reaction distillation tower is 10-30m; wherein, the chlorination reaction The liquid feeding position is at a position of 3/10 to 2/5 of the tower height from the top of the tower, and the feeding position of the first liquid caustic soda is at a position of 1/2 to 3/5 of the tower height from the top of the tower. The feeding position of the recycled water is 7/10-4/5 of the height of the tower from the top of the tower.
中和反应条件neutralization reaction conditions
在本申请中,对中和反应的反应条件不作限制,凡是能够使中和反应彻底进行即可,在本申请的一些实施例中,考虑到中和反应的反应效果,将中和反应精馏塔的塔顶温度设为30~40℃,塔底温度设为50~60℃。In the present application, the reaction conditions of the neutralization reaction are not limited, as long as the neutralization reaction can be carried out thoroughly, in some embodiments of the application, considering the reaction effect of the neutralization reaction, the neutralization reaction rectification The tower top temperature of the tower is set at 30-40°C, and the tower bottom temperature is set at 50-60°C.
水解反应精馏塔Hydrolysis reaction distillation column
在本申请中,对水解反应精馏塔的类型不作限制,凡是能够同时实现水解、蒸馏的精馏塔即可,在一些实施例中,水解反应精馏塔可以为填料塔或板式塔。In this application, there is no limitation on the type of the hydrolysis reaction distillation column, any distillation column that can realize hydrolysis and distillation at the same time is sufficient. In some embodiments, the hydrolysis reaction distillation column can be a packed column or a tray column.
在本申请中,对水解反应精馏塔的规格不作限制,在一些实施例中,考虑到水解反应的效果,水解反应精馏塔的塔高为10~30m;其中,氯化液中和液进料位置处于距离塔顶为塔高的2/5~3/7的位置,第二液碱的进料位置处于距离塔顶为塔高的1/2~3/5的位置,第二回用水的进料位置处于距离塔顶为塔高的4/5~9/10的位置。In this application, the specifications of the hydrolysis reaction distillation tower are not limited. In some embodiments, considering the effect of the hydrolysis reaction, the tower height of the hydrolysis reaction distillation tower is 10-30m; wherein, the chlorination liquid neutralizing liquid The feeding position is at a position of 2/5 to 3/7 of the tower height from the top of the tower, and the feeding position of the second liquid caustic soda is at a position of 1/2 to 3/5 of the tower height from the top of the tower. The feeding position of water is at a position of 4/5-9/10 of the tower height from the top of the tower.
水解反应条件Hydrolysis reaction conditions
在本申请中,对水解反应条件不作限制,但是使水解彻底进行即可,在一些实施例中,考虑到水解效果,在进行水解反应时,将中和反应精馏塔的塔顶温度设为30~40℃,塔底温度设为50~60℃。In the present application, the conditions of the hydrolysis reaction are not limited, but the hydrolysis can be carried out thoroughly. In some embodiments, in consideration of the hydrolysis effect, when the hydrolysis reaction is carried out, the temperature at the top of the neutralization reaction distillation tower is set to 30-40°C, and the temperature at the bottom of the tower is set at 50-60°C.
氯化反应液、第一液碱和第一回用水的用料比The material ratio of the chlorination reaction liquid, the first liquid caustic soda and the first recycled water
在本申请中,对中和步骤中,对氯化反应液、第一液碱和第一回用水的用料比不作限制,在一些实施例中,氯化反应液、第一液碱和第一回用水的体积比为 10~15:1:1,在上述用料比中,中和能够达到彻底进行,大部分溶剂能够被第一回用水带出,且不会造成原料的浪费。In the present application, in the neutralization step, there is no limitation to the material ratio of the chlorination reaction liquid, the first liquid alkali and the first recycled water. In some embodiments, the chlorination reaction liquid, the first liquid alkali and the second The volume ratio of primary water is 10-15:1:1. In the above material ratio, neutralization can be carried out completely, and most of the solvent can be taken out by the primary water without waste of raw materials.
氯化反应中和液、第二液碱和第二回用水的用料比The material ratio of chlorination reaction neutralizing liquid, second liquid caustic soda and second recycled water
在本申请中,对水解步骤中,对氯化反应中和液、第二液碱和第二回用水的用料比不作限制,在一些实施例中,氯化反应中和液、第二液碱和第二回用水的体积比为40~60:1:10~20,在上述用料比中,水解能够达到彻底进行,绝大部分溶剂能够被第二回用水带出,且不会造成原料的浪费。In the present application, in the hydrolysis step, there is no limitation on the material ratio of the chlorination reaction neutralizing liquid, the second liquid alkali and the second recycled water. In some embodiments, the chlorination reaction neutralizing liquid, the second liquid The volume ratio of the alkali to the second water is 40-60:1:10-20. In the above material ratio, the hydrolysis can be carried out completely, and most of the solvent can be taken out by the second water without causing Raw material wastage.
萃取剂的种类和用量The type and amount of extractant
在本申请中,在萃取提纯步骤中,在萃取时,为了萃取三氯蔗糖,可选用萃取剂为有机酯,如可以选用乙酸乙酯和/或乙酸丁酯。In the present application, in the extraction and purification step, in order to extract sucralose, an organic ester can be selected as the extractant, such as ethyl acetate and/or butyl acetate.
在本申请的一些实施例中,对萃取剂的用量不作限制,可根据氯化反应中和液的用量确定,如萃取剂的体积用量与氯化反应中和液的比为1~5:1,在上述用量比的范围内,萃取能够达到较好的技术效果,且不会造成萃取剂的浪费。In some embodiments of the present application, the amount of extractant is not limited, it can be determined according to the amount of chlorination reaction neutralization liquid, such as the ratio of the volume of extraction agent to chlorination reaction neutralization liquid is 1 to 5:1 , within the range of the above-mentioned dosage ratio, the extraction can achieve a better technical effect without causing waste of the extractant.
氧化剂的种类和用量Type and amount of oxidizing agent
在本申请的一些实施例中,对氧化剂进行了筛选,在筛选氧化剂的时候发现,选用次氯酸钠或臭氧,选择氧化性是比较好的,即能够将四氯代蔗糖氧化为三氯蔗糖,同时也不会将三氯蔗糖进一步氧化。In some embodiments of the present application, the oxidizing agent is screened, and it is found that sodium hypochlorite or ozone is used for selection, and the selective oxidation is relatively good, that is, tetrachlorosucrose can be oxidized to sucralose, and simultaneously Does not further oxidize sucralose.
在本申请的一些实施例中,对氧化剂的质量分数和用量不作限制,在另一些实施例中,当氧化剂为次氯酸钠时,次氯酸钠的质量用量为萃取得到的有机相的体积的0.01~0.1%;当氧化剂为臭氧时,臭氧的体积用量为萃取得到的有机相的体积的0.01~0.1%。若氧化剂的用量小于上述范围的下限值,则用量过少,氧化反应进行的不彻底,影响三氯蔗糖的收率;若氧化剂的用量大于上述范围的上限值,则用量过多,可能造成过度氧化。In some embodiments of the present application, the mass fraction and dosage of the oxidizing agent are not limited. In other embodiments, when the oxidizing agent is sodium hypochlorite, the mass dosage of sodium hypochlorite is 0.01% to 0.1% of the volume of the extracted organic phase; When the oxidizing agent is ozone, the volumetric dosage of ozone is 0.01-0.1% of the volume of the organic phase obtained by extraction. If the amount of oxidizing agent is less than the lower limit of the above range, the amount is too small, the oxidation reaction is not carried out thoroughly, affecting the yield of sucralose; if the amount of oxidizing agent is greater than the upper limit of the above range, then the amount is too much, may cause excessive oxidation.
氧化反应条件Oxidation reaction conditions
在本申请的一些实施例中,对氧化反应的氧化温度和氧化时间不作限制,在另一些实施例中,氧化的氧化时间为3~12h;氧化温度在室温条件即可。In some embodiments of the present application, the oxidation temperature and oxidation time of the oxidation reaction are not limited, and in other embodiments, the oxidation time of oxidation is 3-12 hours; the oxidation temperature can be at room temperature.
反萃取剂的用量The amount of stripping agent
在本申请的一些实施例中,对反萃取剂的用量不作限制,可根据氯化反应中和液的用量确定,如反萃取剂的体积用量与萃取得到的有机相的体积的比为1~5:1。在上述用量比的范围内,反萃取能够达到较好的技术效果,且不会造成反萃取剂的浪费。In some embodiments of the present application, the amount of stripping agent is not limited, and can be determined according to the amount of neutralizing liquid in the chlorination reaction, such as the ratio of the volume of stripping agent to the volume of the organic phase obtained by extraction is 1 ~ 5:1. Within the range of the above-mentioned dosage ratio, the stripping can achieve better technical effect without causing waste of stripping agent.
结晶的条件crystallization conditions
在本申请的一些实施例中,对结晶条件不作限制,可参考现有技术中的一种或几种的结合,在另一些实施例中,在结晶步骤中,浓缩的浓缩温度为40~60℃,浓缩真空度为-0.1~-0.5Mpa,浓缩至三氯蔗糖水溶液中三氯蔗糖浓度为80~140g/L。In some embodiments of the present application, the crystallization conditions are not limited, and one or more combinations of the prior art may be referred to. In other embodiments, in the crystallization step, the concentrated concentration temperature is 40-60 °C, the vacuum degree of concentration is -0.1~-0.5Mpa, and the concentration of sucralose in the sucralose aqueous solution is 80~140g/L.
本申请中涉及的测试方法Test methods involved in this application
本申请中各实施例和对比例中各物质含量均采用高效液相色谱(High Performance Liquid Chromatography,HPLC)方法在下述条件下采用外标法测得,在各个实施例中不再赘述。In each embodiment and comparative example in the application, each material content adopts the high performance liquid chromatography (High Performance Liquid Chromatography, HPLC) method to adopt the external standard method to record under the following conditions, no longer repeat them in each embodiment.
高效液相色谱的分析测定条件:日本岛津高效液相色谱仪,配RID-10A示差折光检测,LC-10ADVP高压泵,CTO-10ASVP恒温箱;色谱柱:Agilent XDB C18柱(250mm×4.6mm,5μm);流动相:甲醇-0.125%磷酸氢二钾水溶液(4:6);柱温:40℃;流量:1.0mL/min。其中,需要甲醇(色谱纯)、磷酸氢二钾(分析纯)、超纯水等等,各标准物质,外标法测量含量。Analysis and determination conditions of high performance liquid chromatography: Japan Shimadzu high performance liquid chromatography, equipped with RID-10A differential refraction detection, LC-10ADVP high pressure pump, CTO-10ASVP constant temperature box; chromatographic column: Agilent XDB C18 column (250mm×4.6mm , 5 μm); mobile phase: methanol-0.125% dipotassium hydrogen phosphate aqueous solution (4:6); column temperature: 40°C; flow rate: 1.0mL/min. Among them, methanol (chromatographically pure), dipotassium hydrogen phosphate (analytical pure), ultrapure water, etc. are required, and each standard substance is measured by an external standard method.
实施例1Example 1
中和步骤:中和反应精馏塔R-1为填料塔,塔高10m,填料为聚四氟波纹板,填料高度为塔高的1/3。将氯化反应液、第一液碱、第一回用水分别以距离塔顶3m、5m、7m的位置输入中和反应精馏塔。中和反应精馏塔R-1塔顶温度为30℃,塔底温度为50℃。物料进料比(体积比)为氯化反应液:第一液碱:第一回用水=10:1:1,第一液碱为32%(质量百分数,市售)的NaOH水溶液。从中和反应精馏塔R-1的塔顶采出混合溶剂去分离,从中和反应精馏塔R-1的塔底采出的氯化反应中和液输入水解反应精馏塔R-2。Neutralization step: The neutralization reaction distillation tower R-1 is a packed tower with a tower height of 10m, and the packing is polytetrafluoro corrugated board, and the packing height is 1/3 of the tower height. The chlorination reaction liquid, the first liquid caustic soda, and the first recycled water are respectively input into the neutralization reaction distillation tower at positions 3m, 5m, and 7m away from the tower top. The temperature at the top of the neutralization reaction distillation column R-1 is 30°C, and the temperature at the bottom of the column is 50°C. The material feed ratio (volume ratio) is chlorination reaction solution: the first caustic soda: the first water = 10:1:1, and the first caustic is 32% (mass percentage, commercially available) NaOH aqueous solution. The mixed solvent is extracted from the top of the neutralization reactive distillation tower R-1 for separation, and the chlorination reaction neutralization liquid extracted from the bottom of the neutralization reactive distillation tower R-1 is input into the hydrolysis reactive distillation tower R-2.
水解步骤:水解反应精馏塔R-2为板式塔,塔高10m,填料为不锈钢θ环,填料高度为塔高的1/3;将氯化反应中和液、第二液碱、第二回用水分别以距塔顶4m、5m、8m的位置输入水解反应精馏塔R-2。水解反应精馏塔塔顶温度为30℃,塔底温度为50℃。物料进料比(体积比)为氯化反应中和液:第二液碱:第二回用水=40:1:10,第二液碱为32%(质量百分数,市售)的NaOH。塔顶采出废水去污水处理,塔底采出三氯蔗糖水溶液输入pH调节釜V-1。Hydrolysis step: the hydrolysis reaction rectification tower R-2 is a plate tower with a tower height of 10m, and the filler is a stainless steel θ ring, and the height of the filler is 1/3 of the height of the tower; Reuse water is input into the hydrolysis reaction distillation tower R-2 at the positions of 4m, 5m and 8m from the top of the tower respectively. The temperature at the top of the hydrolysis reaction distillation column is 30°C, and the temperature at the bottom of the column is 50°C. The material feed ratio (volume ratio) is chlorination reaction neutralizing liquid: the second liquid caustic soda: the second recycled water = 40:1:10, and the second liquid caustic is 32% (mass percentage, commercially available) NaOH. The waste water is extracted from the top of the tower for sewage treatment, and the sucralose aqueous solution is extracted from the bottom of the tower and input into the pH adjustment kettle V-1.
萃取步骤:向pH调节釜V-1中加入盐酸调节pH至6,然后将物料输入至转盘萃取塔R-3上段,将乙酸乙酯萃取剂从转盘萃取塔R-3输入,萃取比例为(体积比)乙酸乙酯:氯化反应中和液=5:1。萃取完成后,从转盘萃取塔R-3下段输出水相 做高盐废水处理,上段输出乙酸乙酯相进入氧化釜V-2氧化处理。向氧化釜V-2中加入为乙酸乙酯相体积0.01%的臭氧,氧化10h,然后将氧化得到的反应液输入至转盘萃取塔R-4下段。将纯水从转盘萃取塔R-4上段输入,反萃取比例为(体积比)水:乙酸乙酯相=1:1。反萃取完成后,转盘萃取塔R-4的塔顶采出乙酸乙酯去溶剂回收,下段采出的三氯蔗糖水溶液输入浓缩釜V-3。Extraction step: add hydrochloric acid to the pH adjustment kettle V-1 to adjust the pH to 6, then input the material to the upper section of the rotary extraction tower R-3, and input the ethyl acetate extractant from the rotary disk extraction tower R-3, and the extraction ratio is ( Volume ratio) ethyl acetate: chlorination reaction neutralizing solution=5:1. After the extraction is completed, the water phase is output from the lower section of the rotary disk extraction tower R-3 for high-salt wastewater treatment, and the ethyl acetate phase is output from the upper section and enters the oxidation tank V-2 for oxidation treatment. Add 0.01% ozone by volume of the ethyl acetate phase into the oxidation kettle V-2, oxidize for 10 h, and then input the reaction liquid obtained by oxidation into the lower section of the rotary disk extraction tower R-4. Pure water is input from the upper part of the rotary disk extraction tower R-4, and the stripping ratio is (volume ratio) water: ethyl acetate phase = 1:1. After the stripping is completed, ethyl acetate is extracted from the top of the rotary disk extraction tower R-4 to remove the solvent for recovery, and the aqueous sucralose solution extracted in the lower section is input into the concentration tank V-3.
结晶步骤:三氯蔗糖水溶液输入浓缩釜V-3进行浓缩,浓缩温度为40℃,真空度为-0.1Mpa,浓缩后三氯蔗糖浓度为80g/L,然后将浓缩液输入结晶釜V-4室温结晶,三氯蔗糖母液回用次数为4次,三氯蔗糖经烘干后纯度见表1。Crystallization step: input the sucralose aqueous solution into the concentration tank V-3 for concentration, the concentration temperature is 40°C, the vacuum degree is -0.1Mpa, the concentrated sucralose concentration is 80g/L, and then the concentrated solution is input into the crystallization tank V-4 Crystallization at room temperature, sucralose mother liquor was reused 4 times, and the purity of sucralose after drying is shown in Table 1.
表1 三氯蔗糖产品纯度Table 1 Sucralose Product Purity
母液回用次数Mother liquor reuse times | 产品纯度/%Product purity/% | 水含量/wt%Water content/wt% |
00 | 99.8799.87 | 0.130.13 |
11 | 99.7599.75 | 0.250.25 |
22 | 99.8999.89 | 0.110.11 |
33 | 99.9099.90 | 0.100.10 |
44 | 99.8299.82 | 0.180.18 |
实施例2Example 2
中和步骤:中和反应精馏塔R-1为填料塔,塔高15m,填料为聚四氟θ环,填料高度为塔高的1/2。将氯化反应液、第一液碱、第一回用水分别以距离塔顶6m、9m、12m的位置输入中和反应精馏塔R-1。中和反应精馏塔R-1的塔顶温度为35℃,塔底温度为55℃。物料进料比(体积比)为氯化反应液:第一液碱:第一回用水=11:1:1,第一液碱为32%(质量百分数,市售)的KOH。中和反应精馏塔R-1塔顶采出混合溶剂去分离,塔底氯化反应中和液输入水解反应精馏塔R-2。Neutralization step: The neutralization reaction distillation tower R-1 is a packed tower with a tower height of 15m, and the packing is polytetrafluorotheta ring, and the packing height is 1/2 of the tower height. The chlorination reaction liquid, the first liquid caustic soda, and the first reused water are respectively input into the neutralization reaction distillation column R-1 at positions 6m, 9m, and 12m away from the tower top. The temperature at the top of the neutralization reaction distillation column R-1 is 35°C, and the temperature at the bottom of the column is 55°C. The ratio of material to feed (volume ratio) is chlorination reaction solution: first liquid alkali: first water = 11:1:1, and the first liquid alkali is 32% (mass percentage, commercially available) KOH. The mixed solvent is extracted from the top of the neutralization reaction rectification tower R-1 for separation, and the neutralization liquid of the chlorination reaction at the bottom of the tower is input into the hydrolysis reaction rectification tower R-2.
水解步骤:水解反应精馏塔R-2为板式塔,塔高15m,填料为不锈钢波纹板,填料高度为塔高的1/3;将氯化液反应中和液、第二液碱、第二回用水分别以距塔顶6.5m、9m、13.5m的位置输入水解反应精馏塔R-2。水解反应精馏塔R-2的塔顶温度为35℃,塔底温度为55℃。物料进料比(体积比)为氯化反应中和液:第二液碱:第二回用水=50:1:15,第二液碱为32%(质量百分数,市售)的KOH。水解反应精馏塔R-2的塔顶采出废水去污水处理,塔底采出三氯蔗糖水溶液输入pH调节釜V-1。Hydrolysis step: the hydrolysis reaction rectification tower R-2 is a plate tower with a tower height of 15m, and the packing is stainless steel corrugated plate, and the packing height is 1/3 of the tower height; The secondary water is input into the hydrolysis reaction distillation column R-2 at positions 6.5m, 9m, and 13.5m from the top of the tower respectively. The temperature at the top of the hydrolysis reaction distillation column R-2 is 35°C, and the temperature at the bottom of the column is 55°C. The material feed ratio (volume ratio) is chlorination reaction neutralizing liquid: the second liquid caustic soda: the second recycled water = 50:1:15, and the second liquid caustic is 32% (mass percentage, commercially available) KOH. The waste water is extracted from the top of the hydrolysis reaction distillation column R-2 for sewage treatment, and the sucralose aqueous solution is extracted from the bottom of the column and input into the pH adjustment tank V-1.
萃取步骤:向pH调节釜V-1中加入硫酸调节pH至7,然后将物料输入至转 盘萃取塔R-3上段,将乙酸乙酯萃取剂从转盘萃取塔R-3输入,萃取比例为(体积比)乙酸乙酯:氯化反应中和液=4:1。萃取完成后,从转盘萃取塔R-3下段输出水相做高盐废水处理,上段输出乙酸乙酯相进入氧化釜V-2氧化处理。向氧化釜V-2中加入乙酸乙酯相体积0.1%的臭氧,氧化3h,然后将氧化得到的反应液输入至转盘萃取塔R-4下段。将纯水从转盘萃取塔R-4上段输入,反萃取比例为(体积比)水:乙酸乙酯相=5:1。反萃取完成后,转盘萃取塔R-4的塔顶采出乙酸乙酯去溶剂回收,下段采出三氯蔗糖水溶液输入浓缩釜V-3。Extraction step: add sulfuric acid to the pH adjustment kettle V-1 to adjust the pH to 7, then input the material to the upper section of the rotary extraction tower R-3, and input the ethyl acetate extractant from the rotary disk extraction tower R-3, and the extraction ratio is ( Volume ratio) ethyl acetate: chlorination reaction neutralizing solution=4:1. After the extraction is completed, the water phase is output from the lower section of the rotary disk extraction tower R-3 for high-salt wastewater treatment, and the ethyl acetate phase is output from the upper section into the oxidation tank V-2 for oxidation treatment. Add 0.1% ozone in ethyl acetate phase volume to the oxidation kettle V-2, oxidize for 3 hours, and then input the reaction liquid obtained by oxidation into the lower section of the rotary disk extraction tower R-4. Pure water is input from the upper part of the rotary disk extraction tower R-4, and the stripping ratio is (volume ratio) water: ethyl acetate phase = 5:1. After the stripping is completed, ethyl acetate is taken from the top of the rotary disk extraction tower R-4 to remove the solvent for recovery, and the sucralose aqueous solution is taken from the lower section and input into the concentration tank V-3.
结晶步骤:三氯蔗糖水溶液输入浓缩釜V-3进行浓缩,浓缩温度为60℃,真空度为-0.05Mpa,浓缩后三氯蔗糖浓度为100g/L,然后将浓缩液输入结晶釜V-4室温结晶,三氯蔗糖母液回用次数为4次,三氯蔗糖经烘干后纯度见表2。Crystallization step: input the sucralose aqueous solution into the concentration tank V-3 for concentration, the concentration temperature is 60°C, the vacuum degree is -0.05Mpa, the concentrated sucralose concentration is 100g/L, and then the concentrated solution is input into the crystallization tank V-4 Crystallization at room temperature, sucralose mother liquor was reused 4 times, and the purity of sucralose after drying is shown in Table 2.
表2 三氯蔗糖产品纯度Table 2 Sucralose Product Purity
母液回用次数Mother liquor reuse times | 产品纯度/%Product purity/% | 水含量/wt%Water content/wt% |
00 | 99.9199.91 | 0.090.09 |
11 | 99.9399.93 | 0.070.07 |
22 | 99.9099.90 | 0.100.10 |
33 | 99.8099.80 | 0.200.20 |
44 | 99.8499.84 | 0.160.16 |
实施例3Example 3
中和步骤:中和反应精馏塔R-1为填料塔,塔高20m,填料为聚四氟波纹板,填料高度为塔高的2/3。将氯化反应液、第一液碱、第一回用水分别以距离塔顶7m、11m、15m的位置输入中和反应精馏塔R-1。中和反应精馏塔R-1的塔顶温度为40℃,塔底温度为55℃。物料进料比(体积比)为氯化反应液:第一液碱:第一回用水=15:1:1,第一液碱为32%(质量百分数,市售)的NaOH。中和反应精馏塔R-1的塔顶采出混合溶剂去分离,塔底采出氯化反应中和液输入水解反应精馏塔R-2。Neutralization step: The neutralization reaction distillation tower R-1 is a packed tower with a tower height of 20m, and the packing is polytetrafluoro corrugated board, and the packing height is 2/3 of the tower height. The chlorination reaction liquid, the first liquid caustic soda, and the first reused water are respectively input into the neutralization reaction distillation column R-1 at positions 7m, 11m, and 15m away from the tower top. The temperature at the top of the neutralization reaction distillation column R-1 is 40°C, and the temperature at the bottom of the column is 55°C. The ratio of material to feed (volume ratio) is chlorination reaction solution: first liquid caustic soda: first water = 15:1:1, and the first liquid caustic is 32% (mass percentage, commercially available) NaOH. The mixed solvent is taken from the top of the neutralization reaction distillation tower R-1 for separation, and the neutralization liquid from the chlorination reaction is taken from the bottom of the tower and input into the hydrolysis reaction distillation tower R-2.
水解步骤:水解反应精馏塔R-2为板式塔,塔高20m,填料为不锈钢波纹板,填料高度为塔高的2/3;将氯化液反应中和液、第二液碱、第二回用水分别以距塔顶8.2m、11m、17m的位置输入水解反应精馏塔R-2。水解反应精馏塔R-2的塔顶温度为35℃,塔底温度为60℃。物料进料比(体积比)为氯化反应中和液:第二液碱:第二回用水=60:1:20,第二液碱为32%(质量百分数,市售)的KOH。水解反应精馏塔R-2的塔顶采出废水去污水处理,塔底采出三氯蔗糖水溶液输入pH调节 釜V-1。Hydrolysis step: the hydrolysis reaction rectification tower R-2 is a plate tower with a tower height of 20m, and the packing is stainless steel corrugated plate, and the packing height is 2/3 of the tower height; The secondary water is input into the hydrolysis reaction distillation tower R-2 at the positions of 8.2m, 11m and 17m from the top of the tower respectively. The temperature at the top of the hydrolysis reaction distillation column R-2 is 35°C, and the temperature at the bottom of the column is 60°C. The ratio of material to feed (volume ratio) is chlorination reaction neutralizing liquid: second liquid caustic soda: second recycled water = 60:1:20, and the second liquid caustic is 32% (mass percentage, commercially available) KOH. The tower top of the hydrolysis reaction rectification tower R-2 extracts waste water for sewage treatment, and extracts the sucralose aqueous solution from the tower bottom to input the pH adjustment kettle V-1.
萃取步骤:向pH调节釜V-1中加入磷酸调节pH至6.5,然后将物料输入至转盘萃取塔R-3上段,将乙酸乙酯萃取剂从转盘萃取塔R-3输入,萃取比例为(体积比)乙酸乙酯:氯化反应中和液=1:1。萃取完成后,从转盘萃取塔R-3下段输出水相做高盐废水处理,上段输出乙酸乙酯相进入氧化釜V-2氧化处理。向氧化釜V-2中加入乙酸乙酯相体积0.01%的次氯酸钠,氧化12h,然后将氧化得到的反应液输入至转盘萃取塔R-4下段。将纯水从转盘萃取塔R-4上段输入,反萃取比例为(体积比)水:乙酸乙酯相=3:1。反萃取完成后,转盘萃取塔R-4的塔顶采出乙酸乙酯去溶剂回收,下段采出三氯蔗糖水溶液输入浓缩釜V-3。Extraction step: add phosphoric acid to the pH adjustment kettle V-1 to adjust the pH to 6.5, then input the material to the upper section of the rotary extraction tower R-3, and input the ethyl acetate extractant from the rotary disk extraction tower R-3, and the extraction ratio is ( Volume ratio) ethyl acetate: chlorination reaction neutralizing solution=1:1. After the extraction is completed, the water phase is output from the lower section of the rotary disk extraction tower R-3 for high-salt wastewater treatment, and the ethyl acetate phase is output from the upper section into the oxidation tank V-2 for oxidation treatment. Add sodium hypochlorite with an ethyl acetate phase volume of 0.01% to the oxidation kettle V-2, oxidize for 12 hours, and then input the reaction liquid obtained by oxidation into the lower section of the rotary disk extraction tower R-4. Pure water is input from the upper part of the rotary disk extraction tower R-4, and the stripping ratio is (volume ratio) water: ethyl acetate phase = 3:1. After the stripping is completed, ethyl acetate is taken from the top of the rotary disk extraction tower R-4 to remove the solvent for recovery, and the sucralose aqueous solution is taken from the lower section and input into the concentration tank V-3.
结晶步骤:三氯蔗糖水溶液输入浓缩釜V-3进行浓缩,浓缩温度为50℃,真空度为-0.07Mpa,浓缩后三氯蔗糖浓度为120g/L,然后将浓缩液输入结晶釜V-4室温结晶,三氯蔗糖母液回用次数为5次,三氯蔗糖经烘干后纯度见表3。Crystallization step: input the sucralose aqueous solution into the concentration tank V-3 for concentration, the concentration temperature is 50°C, the vacuum degree is -0.07Mpa, the concentrated sucralose concentration is 120g/L, and then the concentrated solution is input into the crystallization tank V-4 Crystallization at room temperature, sucralose mother liquor was reused 5 times, and the purity of sucralose after drying is shown in Table 3.
表3 三氯蔗糖产品纯度Table 3 Sucralose Product Purity
母液回用次数Mother liquor reuse times | 产品纯度/%Product purity/% | 水含量/wt%Water content/wt% |
00 | 99.8299.82 | 0.180.18 |
11 | 99.8599.85 | 0.150.15 |
22 | 99.8599.85 | 0.150.15 |
33 | 99.8099.80 | 0.200.20 |
44 | 99.7899.78 | 0.220.22 |
55 | 99.7799.77 | 0.230.23 |
实施例4Example 4
中和步骤:中和反应精馏塔R-1为填料塔,塔高25m,填料为聚四氟θ环,填料高度为塔高的3/5。将氯化反应液、第一液碱、第一回用水分别以距离塔顶8m、13m、18m的位置输入中和反应精馏塔R-1。中和反应精馏塔R-1的塔顶温度为33℃,塔底温度为58℃。物料进料比(体积比)为氯化反应液:第一液碱:第一回用水=13:1:1,第一液碱为32%(质量百分数,市售)的KOH。中和反应精馏塔R-1的塔顶采出混合溶剂去分离,塔底采出氯化反应中和液输入水解反应精馏塔R-2。Neutralization step: The neutralization reaction distillation tower R-1 is a packed tower with a tower height of 25m, and the packing is polytetrafluorotheta ring, and the packing height is 3/5 of the tower height. The chlorination reaction liquid, the first liquid caustic soda, and the first reused water are respectively input into the neutralization reaction distillation column R-1 at positions 8m, 13m, and 18m away from the tower top. The temperature at the top of the neutralization reaction distillation column R-1 is 33°C, and the temperature at the bottom of the column is 58°C. The ratio of material to feed (volume ratio) is chlorination reaction liquid: first liquid alkali: first water = 13:1:1, and the first liquid alkali is 32% (mass percentage, commercially available) KOH. The mixed solvent is taken from the top of the neutralization reaction distillation tower R-1 for separation, and the neutralization liquid from the chlorination reaction is taken from the bottom of the tower and input into the hydrolysis reaction distillation tower R-2.
水解步骤:水解反应精馏塔R-2为板式塔,塔高25m,填料为不锈钢θ环,填料高度为塔高的1/3;将氯化液反应中和液、第二液碱、第二回用水分别以距塔顶10.5m、13m、20.5m的位置输入水解反应精馏塔R-2。水解反应精馏塔R-2的塔顶 温度为32℃,塔底温度为56℃。物料进料比(体积比)为氯化反应中和液:第二液碱:第二回用水=45:1:10,第二液碱为32%(质量百分数,市售)的NaOH。水解反应精馏塔R-2的塔顶采出废水去污水处理,塔底采出三氯蔗糖水溶液输入pH调节釜V-1。Hydrolysis step: the hydrolysis reaction distillation tower R-2 is a plate tower with a tower height of 25m, and the filler is a stainless steel θ ring, and the height of the filler is 1/3 of the height of the tower; The secondary water is input into the hydrolysis reaction distillation tower R-2 at the positions of 10.5m, 13m and 20.5m from the top of the tower respectively. The temperature at the top of the hydrolysis reaction distillation column R-2 was 32°C, and the temperature at the bottom of the column was 56°C. The material feed ratio (volume ratio) is chlorination reaction neutralizing liquid: the second liquid caustic soda: the second recycled water = 45:1:10, and the second liquid caustic is 32% (mass percentage, commercially available) NaOH. The waste water is extracted from the top of the hydrolysis reaction distillation column R-2 for sewage treatment, and the sucralose aqueous solution is extracted from the bottom of the column and input into the pH adjustment tank V-1.
萃取步骤:向pH调节釜V-1中加入盐酸调节pH至8,然后将物料输入至转盘萃取塔R-3上段,将乙酸乙酯萃取剂从转盘萃取塔R-3输入,萃取比例为(体积比)乙酸乙酯:氯化反应中和液=2:1。萃取完成后,从转盘萃取塔R-3下段输出水相做高盐废水处理,上段输出乙酸乙酯相进入氧化釜V-2氧化处理。向氧化釜V-2中加入乙酸乙酯相体积0.1%的臭氧,氧化4h,然后将氧化得到的反应液输入至转盘萃取塔R-4下段。将纯水从转盘萃取塔R-4上段输入,反萃取比例为(体积比)水:乙酸乙酯相=5:1。反萃取完成后,转盘萃取塔R-4的塔顶采出乙酸乙酯去溶剂回收,下段采出三氯蔗糖水溶液输入浓缩釜V-3。Extraction step: add hydrochloric acid to the pH adjustment kettle V-1 to adjust the pH to 8, then input the material to the upper section of the rotary extraction tower R-3, and input the ethyl acetate extractant from the rotary disk extraction tower R-3, and the extraction ratio is ( Volume ratio) ethyl acetate: chlorination reaction neutralizing solution=2:1. After the extraction is completed, the water phase is output from the lower section of the rotary disk extraction tower R-3 for high-salt wastewater treatment, and the ethyl acetate phase is output from the upper section into the oxidation tank V-2 for oxidation treatment. Add 0.1% of the ethyl acetate phase volume of ozone into the oxidation kettle V-2, oxidize for 4 hours, and then input the reaction solution obtained from the oxidation into the lower section of the rotary disk extraction tower R-4. Pure water is input from the upper part of the rotary disk extraction tower R-4, and the stripping ratio is (volume ratio) water: ethyl acetate phase = 5:1. After the stripping is completed, ethyl acetate is taken from the top of the rotary disk extraction tower R-4 to remove the solvent for recovery, and the sucralose aqueous solution is taken from the lower section and input into the concentration tank V-3.
结晶步骤:三氯蔗糖水溶液输入浓缩釜V-3进行浓缩,浓缩温度为45℃,真空度为-0.09Mpa,浓缩后三氯蔗糖浓度为110g/L,然后将浓缩液输入结晶釜V-4室温结晶,三氯蔗糖母液回用次数为5次,三氯蔗糖经烘干后纯度见表4。Crystallization step: input the sucralose aqueous solution into the concentration tank V-3 for concentration, the concentration temperature is 45°C, the vacuum degree is -0.09Mpa, the concentrated sucralose concentration is 110g/L, and then the concentrated solution is input into the crystallization tank V-4 Crystallization at room temperature, sucralose mother liquor was reused 5 times, and the purity of sucralose after drying is shown in Table 4.
表4 三氯蔗糖产品纯度Table 4 Sucralose Product Purity
母液回用次数Mother liquor reuse times | 产品纯度/%Product purity/% | 水含量/wt%Water content/wt% |
00 | 99.8999.89 | 0.110.11 |
11 | 99.8599.85 | 0.150.15 |
22 | 99.9199.91 | 0.090.09 |
33 | 99.9399.93 | 0.070.07 |
44 | 99.9099.90 | 0.100.10 |
55 | 99.8399.83 | 0.170.17 |
实施例5Example 5
中和步骤:中和反应精馏塔R-1为填料塔,塔高30m,填料为聚四氟θ环,填料高度为塔高的1/3。将氯化反应液、第一液碱、第一回用水分别以距离塔顶10.2m、16.2m、22.2m的位置输入中和反应精馏塔R-1。中和反应精馏塔R-1的塔顶温度为40℃,塔底温度为60℃。物料进料比(体积比)为氯化反应液:第一液碱:第一回用水=13:1:1,第一液碱为32%(质量百分数,市售)的NaOH。中和反应精馏塔R-1的塔顶采出混合溶剂去分离,塔底采出氯化反应中和液输入水解反应精馏塔R-2。Neutralization step: The neutralization reaction distillation tower R-1 is a packed tower with a tower height of 30m, and the packing is polytetrafluorotheta ring, and the packing height is 1/3 of the tower height. The chlorination reaction liquid, the first liquid caustic soda, and the first reused water are respectively input into the neutralization reactive distillation column R-1 at positions 10.2m, 16.2m, and 22.2m away from the tower top. The temperature at the top of the neutralization reaction distillation column R-1 is 40°C, and the temperature at the bottom of the column is 60°C. The ratio of material to feed (volume ratio) is chlorination reaction liquid: the first caustic soda: the first water = 13:1:1, and the first caustic is 32% (mass percentage, commercially available) NaOH. The mixed solvent is taken from the top of the neutralization reaction distillation tower R-1 for separation, and the neutralization liquid from the chlorination reaction is taken from the bottom of the tower and input into the hydrolysis reaction distillation tower R-2.
水解步骤:水解反应精馏塔R-2为板式塔,塔高30m,填料为不锈钢波纹板,填料高度为塔高的3/5;将氯化反应中和液、第二液碱、第二回用水分别以距塔顶12.3m、16.2m、25.2m的位置输入水解反应精馏塔R-2。水解反应精馏塔R-2的塔顶温度为40℃,塔底温度为60℃。物料进料比(体积比)为氯化反应中和液:第二液碱:第二回用水=55:1:12,第二液碱为32%(质量百分数,市售)的NaOH。水解反应精馏塔R-2的塔顶采出废水去污水处理,塔底采出三氯蔗糖水溶液输入pH调节釜V-1。Hydrolysis step: the hydrolysis reaction rectification tower R-2 is a plate tower with a tower height of 30m, and the packing is stainless steel corrugated plate, and the packing height is 3/5 of the tower height; The recycled water is input into the hydrolysis reaction distillation tower R-2 at the positions of 12.3m, 16.2m and 25.2m from the top of the tower respectively. The temperature at the top of the hydrolysis reaction distillation column R-2 is 40°C, and the temperature at the bottom of the column is 60°C. The material feed ratio (volume ratio) is chlorination reaction neutralizing liquid: the second liquid caustic soda: the second recycled water = 55:1:12, and the second liquid caustic is 32% (mass percentage, commercially available) NaOH. The waste water is extracted from the top of the hydrolysis reaction distillation column R-2 for sewage treatment, and the sucralose aqueous solution is extracted from the bottom of the column and input into the pH adjustment tank V-1.
萃取步骤:向pH调节釜V-1中加入硫酸调节pH至7.5,然后将物料输入至转盘萃取塔R-3上段,将乙酸乙酯萃取剂从转盘萃取塔R-3输入,萃取比例为(体积比)乙酸乙酯:氯化反应中和液=4:1。萃取完成后,从转盘萃取塔R-3下段输出水相做高盐废水处理,上段输出乙酸乙酯相进入氧化釜V-2氧化处理。向氧化釜V-2中加入乙酸乙酯相体积0.05%的臭氧,氧化6h,然后将氧化得到的反应液输入至转盘萃取塔R-4下段。将纯水从转盘萃取塔R-4上段输入,反萃取比例为(体积比)水:乙酸乙酯相=3:1。反萃取完成后,转盘萃取塔R-4的塔顶采出乙酸乙酯去溶剂回收,下段采出三氯蔗糖水溶液输入浓缩釜V-3。Extraction step: add sulfuric acid to the pH adjustment kettle V-1 to adjust the pH to 7.5, then input the material to the upper section of the rotary extraction tower R-3, and input the ethyl acetate extractant from the rotary disk extraction tower R-3, and the extraction ratio is ( Volume ratio) ethyl acetate: chlorination reaction neutralizing solution=4:1. After the extraction is completed, the water phase is output from the lower section of the rotary disk extraction tower R-3 for high-salt wastewater treatment, and the ethyl acetate phase is output from the upper section into the oxidation tank V-2 for oxidation treatment. Add 0.05% of the ethyl acetate phase volume of ozone into the oxidation kettle V-2, oxidize for 6 hours, and then input the reaction solution obtained by oxidation into the lower section of the rotary disk extraction tower R-4. Pure water is input from the upper part of the rotary disk extraction tower R-4, and the stripping ratio is (volume ratio) water: ethyl acetate phase = 3:1. After the stripping is completed, ethyl acetate is taken from the top of the rotary disk extraction tower R-4 to remove the solvent for recovery, and the sucralose aqueous solution is taken from the lower section and input into the concentration tank V-3.
结晶步骤:三氯蔗糖水溶液输入浓缩釜V-3进行浓缩,浓缩温度为55℃,真空度为-0.06Mpa,浓缩后三氯蔗糖浓度为140g/L,然后将浓缩液输入结晶釜V-4室温结晶,三氯蔗糖母液回用次数为4次,三氯蔗糖经烘干后纯度见表5。Crystallization step: input the sucralose aqueous solution into the concentration tank V-3 for concentration, the concentration temperature is 55°C, the vacuum degree is -0.06Mpa, the concentrated sucralose concentration is 140g/L, and then the concentrated solution is input into the crystallization tank V-4 Crystallization at room temperature, sucralose mother liquor was reused 4 times, and the purity of sucralose after drying is shown in Table 5.
表5 三氯蔗糖产品纯度Table 5 Sucralose Product Purity
母液回用次数Mother liquor reuse times | 产品纯度/%Product purity/% | 水含量/wt%Water content/wt% |
00 | 99.9599.95 | 0.050.05 |
11 | 99.8999.89 | 0.110.11 |
22 | 99.7999.79 | 0.210.21 |
33 | 99.8699.86 | 0.140.14 |
44 | 99.8599.85 | 0.150.15 |
实施例6Example 6
中和步骤:中和反应精馏塔R-1为填料塔,塔高16m,填料为聚四氟波纹板,填料高度为塔高的2/3。将氯化反应液、第一液碱、第一回用水分别以距离塔顶6.2m、9.5m、12.9m的位置输入中和反应精馏塔R-1。中和反应精馏塔R-1的塔顶温度为38℃,塔底温度为52℃。物料进料比(体积比)为氯化反应液:第一液碱:第一回用 水=14:1:1,第一液碱为32%(质量百分数,市售)的KOH。中和反应精馏塔R-1的塔顶采出混合溶剂去分离,塔底采出氯化反应中和液输入水解反应精馏塔R-2。Neutralization step: The neutralization reaction distillation tower R-1 is a packed tower with a tower height of 16m, and the packing is polytetrafluoro corrugated board, and the packing height is 2/3 of the tower height. The chlorination reaction liquid, the first liquid caustic soda, and the first recycled water are respectively input into the neutralization reaction distillation column R-1 at positions 6.2m, 9.5m, and 12.9m away from the tower top. The temperature at the top of the neutralization reaction distillation column R-1 is 38°C, and the temperature at the bottom of the column is 52°C. The ratio of materials to feed (volume ratio) is chlorination reaction liquid: the first caustic soda: the first water = 14:1:1, and the first caustic is 32% (mass percentage, commercially available) KOH. The mixed solvent is taken from the top of the neutralization reaction distillation tower R-1 for separation, and the neutralization liquid from the chlorination reaction is taken from the bottom of the tower and input into the hydrolysis reaction distillation tower R-2.
水解步骤:水解反应精馏塔R-2为板式塔,塔高16m,填料为不锈钢θ环,填料高度为塔高的3/5;将氯化反应中和液、第二液碱、第二回用水分别以距塔顶7.8m、9.5m、14.6m的位置输入水解反应精馏塔R-2。水解反应精馏塔R-2的塔顶温度为34℃,塔底温度为57℃。物料进料比(体积比)为氯化反应中和液:第二液碱:第二回用水=41:1:19,第二液碱为32%(质量百分数,市售)的NaOH。水解反应精馏塔R-2的塔顶采出废水去污水处理,塔底采出三氯蔗糖水溶液输入pH调节釜V-1。Hydrolysis step: the hydrolysis reaction distillation tower R-2 is a plate tower with a tower height of 16m, and the filler is a stainless steel θ ring, and the height of the filler is 3/5 of the height of the tower; The recycled water is input into the hydrolysis reaction distillation tower R-2 at the positions of 7.8m, 9.5m and 14.6m from the top of the tower respectively. The temperature at the top of the hydrolysis reaction distillation column R-2 is 34°C, and the temperature at the bottom of the column is 57°C. The material feed ratio (volume ratio) is chlorination reaction neutralizing liquid: the second liquid caustic soda: the second recycled water = 41:1:19, and the second liquid caustic is 32% (mass percentage, commercially available) NaOH. The waste water is extracted from the top of the hydrolysis reaction distillation column R-2 for sewage treatment, and the sucralose aqueous solution is extracted from the bottom of the column and input into the pH adjustment tank V-1.
萃取步骤:向pH调节釜V-1中加入硫酸调节pH至7,然后将物料输入至转盘萃取塔R-3上段,将乙酸乙酯萃取剂从转盘萃取塔R-3输入,萃取比例为(体积比)乙酸乙酯:氯化反应中和液=1:1。萃取完成后,从转盘萃取塔R-3下段输出水相做高盐废水处理,上段输出乙酸乙酯相进入氧化釜V-2氧化处理。向氧化釜V-2中加入乙酸乙酯相体积0.03%的次氯酸钠,氧化8h,然后将氧化得到的反应液输入至转盘萃取塔R-4下段。将纯水从转盘萃取塔R-4上段输入,反萃取比例为(体积比)水:乙酸乙酯相=5:1。反萃取完成后,转盘萃取塔R-4的塔顶采出乙酸乙酯去溶剂回收,下段采出三氯蔗糖水溶液输入浓缩釜V-3。Extraction step: add sulfuric acid to the pH adjustment kettle V-1 to adjust the pH to 7, then input the material to the upper section of the rotary extraction tower R-3, and input the ethyl acetate extractant from the rotary disk extraction tower R-3, and the extraction ratio is ( Volume ratio) ethyl acetate: chlorination reaction neutralizing solution=1:1. After the extraction is completed, the water phase is output from the lower section of the rotary disk extraction tower R-3 for high-salt wastewater treatment, and the ethyl acetate phase is output from the upper section into the oxidation tank V-2 for oxidation treatment. Add sodium hypochlorite with an ethyl acetate phase volume of 0.03% to the oxidation kettle V-2, oxidize for 8 hours, and then input the reaction solution obtained by oxidation into the lower section of the rotary disk extraction tower R-4. Pure water is input from the upper part of the rotary disk extraction tower R-4, and the stripping ratio is (volume ratio) water: ethyl acetate phase = 5:1. After the stripping is completed, the top of the rotary disk extraction tower R-4 extracts ethyl acetate to remove the solvent for recovery, and extracts the sucralose aqueous solution from the lower section to enter the concentration tank V-3.
结晶步骤:三氯蔗糖水溶液输入浓缩釜V-3进行浓缩,浓缩温度为60℃,真空度为-0.05Mpa,浓缩后三氯蔗糖浓度为140g/L,然后将浓缩液输入结晶釜V-4室温结晶,三氯蔗糖母液回用次数为5次,三氯蔗糖经烘干后纯度见表6。Crystallization step: input the sucralose aqueous solution into the concentration tank V-3 for concentration, the concentration temperature is 60°C, the vacuum degree is -0.05Mpa, the concentrated sucralose concentration is 140g/L, and then the concentrated solution is input into the crystallization tank V-4 Crystallization at room temperature, sucralose mother liquor was reused 5 times, and the purity of sucralose after drying is shown in Table 6.
表6 三氯蔗糖产品纯度Table 6 Sucralose Product Purity
母液回用次数Mother liquor reuse times | 产品纯度/%Product purity/% | 水含量/%Water content/% |
00 | 99.8299.82 | 0.180.18 |
11 | 99.8899.88 | 0.120.12 |
22 | 99.8199.81 | 0.190.19 |
33 | 99.8999.89 | 0.110.11 |
44 | 99.9299.92 | 0.080.08 |
55 | 99.9399.93 | 0.070.07 |
实施例7Example 7
中和步骤:中和反应精馏塔R-1为填料塔,塔高28m,填料为聚四氟θ环,填料高度为塔高的1/3。将氯化反应液、第一液碱、第一回用水分别以距离塔顶8.4m、 15.4m、20.2m的位置输入中和反应精馏塔R-1。中和反应精馏塔R-1的塔顶温度为39℃,塔底温度为56℃。物料进料比(体积比)为氯化反应液:第一液碱:第一回用水=11:1:1,第一液碱为32%(质量百分数,市售)的NaOH。中和反应精馏塔R-1的塔顶采出混合溶剂去分离,塔底采出氯化反应中和液输入水解反应精馏塔R-2。Neutralization step: The neutralization reaction distillation tower R-1 is a packed tower with a tower height of 28m. The packing is polytetrafluorotheta ring, and the packing height is 1/3 of the tower height. The chlorination reaction liquid, the first liquid caustic soda, and the first recycled water are respectively input into the neutralization reactive distillation column R-1 at positions 8.4m, 15.4m, and 20.2m away from the tower top. The temperature at the top of the neutralization reaction distillation column R-1 is 39°C, and the temperature at the bottom of the column is 56°C. The ratio of material to feed (volume ratio) is chlorination reaction solution: first liquid alkali: first water = 11:1:1, and the first liquid alkali is 32% (mass percentage, commercially available) NaOH. The mixed solvent is taken from the top of the neutralization reaction distillation tower R-1 for separation, and the neutralization liquid from the chlorination reaction is taken from the bottom of the tower and input into the hydrolysis reaction distillation tower R-2.
水解步骤:水解反应精馏塔R-2为板式塔,塔高28m,填料为不锈钢θ环,填料高度为塔高的2/5;将氯化反应中和液、第二液碱、第二回用水分别以距塔顶11.2m、16m、23.8m的位置输入水解反应精馏塔R-2。水解反应精馏塔R-2的塔顶温度为30℃,塔底温度为51℃。物料进料比(体积比)为氯化反应中和液:第二液碱:第二回用水=58:1:11,第二液碱为32%(质量百分数,市售)的NaOH。水解反应精馏塔R-2的塔顶采出废水去污水处理,塔底采出三氯蔗糖水溶液输入pH调节釜V-1。Hydrolysis step: the hydrolysis reaction distillation tower R-2 is a plate tower with a tower height of 28m, and the filler is a stainless steel θ ring, and the height of the filler is 2/5 of the height of the tower; Reuse water is input into the hydrolysis reaction distillation tower R-2 at the positions of 11.2m, 16m and 23.8m from the top of the tower respectively. The temperature at the top of the hydrolysis reaction distillation column R-2 is 30°C, and the temperature at the bottom of the column is 51°C. The material feed ratio (volume ratio) is chlorination reaction neutralizing liquid: the second liquid caustic soda: the second recycled water = 58:1:11, and the second liquid caustic is 32% (mass percentage, commercially available) NaOH. The waste water is extracted from the top of the hydrolysis reaction distillation column R-2 for sewage treatment, and the sucralose aqueous solution is extracted from the bottom of the column and input into the pH adjustment tank V-1.
萃取步骤:向pH调节釜V-1中加入盐酸调节pH至8,然后将物料输入至转盘萃取塔R-3上段,将乙酸乙酯萃取剂从转盘萃取塔R-3输入,萃取比例为(体积比)乙酸乙酯:氯化反应中和液=2:1。萃取完成后,从转盘萃取塔R-3下段输出水相做高盐废水处理,上段输出乙酸乙酯相进入氧化釜V-2氧化处理。向氧化釜V-2中加入乙酸乙酯相体积0.07%的臭氧,氧化5h,然后将氧化得到的反应液输入至转盘萃取塔R-4下段。将纯水从转盘萃取塔R-4上段输入,反萃取比例为(体积比)水:乙酸乙酯相=3:1。反萃取完成后,转盘萃取塔R-4的塔顶采出乙酸乙酯去溶剂回收,下段采出三氯蔗糖水溶液输入浓缩釜V-3。Extraction step: add hydrochloric acid to the pH adjustment kettle V-1 to adjust the pH to 8, then input the material to the upper section of the rotary extraction tower R-3, and input the ethyl acetate extractant from the rotary disk extraction tower R-3, and the extraction ratio is ( Volume ratio) ethyl acetate: chlorination reaction neutralizing solution=2:1. After the extraction is completed, the water phase is output from the lower section of the rotary disk extraction tower R-3 for high-salt wastewater treatment, and the ethyl acetate phase is output from the upper section into the oxidation tank V-2 for oxidation treatment. Add 0.07% of the ethyl acetate phase volume of ozone into the oxidation kettle V-2, oxidize for 5 hours, and then input the reaction solution obtained by oxidation into the lower section of the rotary disk extraction tower R-4. Pure water is input from the upper part of the rotary disk extraction tower R-4, and the stripping ratio is (volume ratio) water: ethyl acetate phase = 3:1. After the stripping is completed, ethyl acetate is taken from the top of the rotary disk extraction tower R-4 to remove the solvent for recovery, and the sucralose aqueous solution is taken from the lower section and input into the concentration tank V-3.
结晶步骤:三氯蔗糖水溶液输入浓缩釜V-3进行浓缩,浓缩温度为50℃,真空度为-0.08Mpa,浓缩后三氯蔗糖浓度为130g/L,然后将浓缩液输入结晶釜V-4室温结晶,三氯蔗糖母液回用次数为4次,三氯蔗糖经烘干后纯度见表7。Crystallization step: input the sucralose aqueous solution into the concentration tank V-3 for concentration, the concentration temperature is 50°C, the vacuum degree is -0.08Mpa, the concentrated sucralose concentration is 130g/L, and then the concentrated solution is input into the crystallization tank V-4 Crystallization at room temperature, sucralose mother liquor was reused 4 times, and the purity of sucralose after drying is shown in Table 7.
表7 三氯蔗糖产品纯度Table 7 Sucralose Product Purity
母液回用次数Mother liquor reuse times | 产品纯度/%Product purity/% | 水含量/wt%Water content/wt% |
00 | 99.7799.77 | 0.230.23 |
11 | 99.7999.79 | 0.210.21 |
22 | 99.8899.88 | 0.120.12 |
33 | 99.8399.83 | 0.170.17 |
44 | 99.8999.89 | 0.110.11 |
实施例8Example 8
中和步骤:中和反应精馏塔R-1为填料塔,塔高22m,填料为聚四氟波纹板,填料高度为塔高的2/5。将氯化反应液、第一液碱、第一回用水分别以距离塔顶8.8m、11m、17m的位置输入中和反应精馏塔R-1。中和反应精馏塔R-1的塔顶温度为36℃,塔底温度为59℃。物料进料比(体积比)为氯化反应液:第一液碱:第一回用水=15:1:1,第一液碱为32%(质量百分数,市售)的KOH。中和反应精馏塔R-1的塔顶采出混合溶剂去分离,塔底采出氯化反应中和液输入水解反应精馏塔R-2。Neutralization step: The neutralization reaction distillation tower R-1 is a packed tower with a tower height of 22m, and the packing is polytetrafluoro corrugated board, and the packing height is 2/5 of the tower height. The chlorination reaction liquid, the first liquid caustic soda, and the first recycled water are respectively input into the neutralization reaction distillation column R-1 at positions 8.8m, 11m, and 17m away from the tower top. The temperature at the top of the neutralization reaction distillation column R-1 is 36°C, and the temperature at the bottom of the column is 59°C. The ratio of material to feed (volume ratio) is chlorination reaction solution: first liquid alkali: first water = 15:1:1, and the first liquid alkali is 32% (mass percentage, commercially available) KOH. The mixed solvent is taken from the top of the neutralization reaction distillation tower R-1 for separation, and the neutralization liquid from the chlorination reaction is taken from the bottom of the tower and input into the hydrolysis reaction distillation tower R-2.
水解步骤:水解反应精馏塔R-2为板式塔,塔高22m,填料为不锈钢波纹板,填料高度为塔高的2/3;将氯化反应中和液、第二液碱、第二回用水分别以距塔顶9m、12m、19m的位置输入水解反应精馏塔R-2。水解反应精馏塔R-2的塔顶温度为33℃,塔底温度为58℃。物料进料比(体积比)为氯化反应中和液:第二液碱:第二回用水=45:1:18,第二液碱为32%(质量百分数,市售)的KOH。水解反应精馏塔R-2的塔顶采出废水去污水处理,塔底采出三氯蔗糖水溶液输入pH调节釜V-1。Hydrolysis step: the hydrolysis reaction rectification tower R-2 is a plate tower with a tower height of 22m, and the packing is stainless steel corrugated plate, and the packing height is 2/3 of the tower height; The recycled water is input into the hydrolysis reaction distillation tower R-2 at the positions of 9m, 12m and 19m from the top of the tower respectively. The temperature at the top of the hydrolysis reaction distillation column R-2 is 33°C, and the temperature at the bottom of the column is 58°C. The material feed ratio (volume ratio) is chlorination reaction neutralizing liquid: the second liquid caustic soda: the second recycled water = 45:1:18, and the second liquid caustic is 32% (mass percentage, commercially available) KOH. The waste water is extracted from the top of the hydrolysis reaction distillation column R-2 for sewage treatment, and the sucralose aqueous solution is extracted from the bottom of the column and input into the pH adjustment tank V-1.
萃取步骤:向pH调节釜V-1中加入磷酸调节pH至6.5,然后将物料输入至转盘萃取塔R-3上段,将乙酸乙酯萃取剂从转盘萃取塔R-3输入,萃取比例为(体积比)乙酸乙酯:氯化反应中和液=1:1。萃取完成后,从转盘萃取塔R-3下段输出水相做高盐废水处理,上段输出乙酸乙酯相进入氧化釜V-2氧化处理。向氧化釜V-2中加入乙酸乙酯相体积0.06%的次氯酸钠,氧化7h,然后将氧化得到的反应液输入至转盘萃取塔R-4下段。将纯水从转盘萃取塔R-4上段输入,反萃取比例为(体积比)水:乙酸乙酯相=4:1。反萃取完成后,转盘萃取塔R-4的塔顶采出乙酸乙酯去溶剂回收,下段采出三氯蔗糖水溶液输入浓缩釜V-3。Extraction step: add phosphoric acid to the pH adjustment kettle V-1 to adjust the pH to 6.5, then input the material to the upper section of the rotary extraction tower R-3, and input the ethyl acetate extractant from the rotary disk extraction tower R-3, and the extraction ratio is ( Volume ratio) ethyl acetate: chlorination reaction neutralizing solution=1:1. After the extraction is completed, the water phase is output from the lower section of the rotary disk extraction tower R-3 for high-salt wastewater treatment, and the ethyl acetate phase is output from the upper section into the oxidation tank V-2 for oxidation treatment. Add sodium hypochlorite with an ethyl acetate phase volume of 0.06% to the oxidation kettle V-2, oxidize for 7 hours, and then input the reaction solution obtained by oxidation into the lower section of the rotary disk extraction tower R-4. Pure water is input from the upper part of the rotary disk extraction tower R-4, and the stripping ratio is (volume ratio) water: ethyl acetate phase = 4:1. After the stripping is completed, ethyl acetate is taken from the top of the rotary disk extraction tower R-4 to remove the solvent for recovery, and the sucralose aqueous solution is taken from the lower section and input into the concentration tank V-3.
结晶步骤:三氯蔗糖水溶液输入浓缩釜V-3进行浓缩,浓缩温度为55℃,真空度为-0.1Mpa,浓缩后三氯蔗糖浓度为125g/L,然后将浓缩液输入结晶釜V-4室温结晶,三氯蔗糖母液回用次数为4次,三氯蔗糖经烘干后纯度见表8。Crystallization step: input the sucralose aqueous solution into the concentration tank V-3 for concentration, the concentration temperature is 55°C, the vacuum degree is -0.1Mpa, the concentrated sucralose concentration is 125g/L, and then the concentrated solution is input into the crystallization tank V-4 Crystallization at room temperature, sucralose mother liquor was reused 4 times, and the purity of sucralose after drying is shown in Table 8.
表8 三氯蔗糖产品纯度Table 8 Sucralose Product Purity
母液回用次数Mother liquor reuse times | 产品纯度/%Product purity/% | 水含量/wt%Water content/wt% |
00 | 99.8299.82 | 0.180.18 |
11 | 99.8599.85 | 0.150.15 |
22 | 99.7999.79 | 0.210.21 |
33 | 99.9199.91 | 0.090.09 |
44 | 99.8399.83 | 0.170.17 |
对比例1Comparative example 1
目前现有三氯蔗糖-6-乙酸酯制备三氯蔗糖工艺为间歇工艺,主要是将氯化液中和,然后提纯获得三氯蔗糖-6-乙酸酯,再用三氯蔗糖-6-乙酸酯纯品做原料在甲醇钠/甲醇体系中水解成三氯蔗糖,最后经提纯获得三氯蔗糖精品。At present, the existing process for preparing sucralose from sucralose-6-acetate is a batch process, which mainly neutralizes the chlorinated liquid, then purifies to obtain sucralose-6-acetate, and then uses sucralose-6- Pure acetate as raw material is hydrolyzed into sucralose in a sodium methoxide/methanol system, and finally purified to obtain fine sucralose.
将3t氯化液冷却至0℃,然后向其加入氨水,温度不超过30℃,调节pH值至10.5,保温1h,然后向其加入稀盐酸调节pH至中性。将中和好的氯化中和液,减压加热浓干去除有机溶剂,然后加入纯水溶解配置成浓干水溶液。向浓干水溶液中加入乙酸乙酯萃取,萃取后水相做废水处理,酯相浓缩至三氯蔗糖-6-乙酸酯含量大于20wt%,降温结晶,获得三氯蔗糖-6-乙酸酯粗品,然后分别用乙酸乙酯,水继续结晶,获得三氯蔗糖-6-乙酸酯精品,含量约90%,水含量约10%。Cool 3t of the chlorinated solution to 0°C, then add ammonia water to it, the temperature does not exceed 30°C, adjust the pH to 10.5, keep it warm for 1 hour, then add dilute hydrochloric acid to adjust the pH to neutral. The neutralized chlorinated neutralization solution is heated under reduced pressure and concentrated to dry to remove the organic solvent, and then dissolved in pure water to form a concentrated dry aqueous solution. Ethyl acetate is added to the concentrated dry aqueous solution for extraction, the water phase after extraction is used for wastewater treatment, the ester phase is concentrated until the content of sucralose-6-acetate is greater than 20wt%, and the temperature is cooled to crystallize to obtain sucralose-6-acetate The crude product is then further crystallized with ethyl acetate and water respectively to obtain the fine product of sucralose-6-acetate with a content of about 90% and a water content of about 10%.
以三氯蔗糖-6-乙酸酯精品为原料,向其加入甲醇钠/甲醇进行水解,水解完成后采用乙酸丁酯萃取,然后将酯相浓干,浓干后加水溶解、浓缩,至三氯蔗糖浓度达到20wt%时室温结晶,反复两次,母液套用4次,三氯蔗糖经烘干后纯度见表9。Sucralose-6-acetate refined product is used as raw material, sodium methoxide/methanol is added to it for hydrolysis, after hydrolysis is completed, it is extracted with butyl acetate, then the ester phase is concentrated to dryness, after concentration is dried, it is dissolved in water and concentrated to three When the concentration of sucralose reaches 20wt%, it crystallizes at room temperature, repeats twice, and applies the mother liquor 4 times. The purity of sucralose after drying is shown in Table 9.
表9 三氯蔗糖产品纯度Table 9 Sucralose Product Purity
母液回用次数Mother liquor reuse times | 产品纯度/%Product purity/% | 水含量/wt%Water content/wt% |
00 | 99.6099.60 | 0.400.40 |
11 | 99.5799.57 | 0.430.43 |
22 | 99.5599.55 | 0.450.45 |
33 | 99.5099.50 | 0.500.50 |
44 | 99.5199.51 | 0.490.49 |
从实施例1~实施例8可以看出,采用本申请的方法生产三氯蔗糖,连续化程度高,稳定性好,三氯蔗糖的纯度均达到99%以上,水含量非常少。It can be seen from Examples 1 to 8 that the production of sucralose by the method of the present application has a high degree of continuity and good stability, the purity of the sucralose is above 99%, and the water content is very small.
综上所述,本申请采用制备三氯蔗糖-6-酯时得到的未处理氯化反应液为原料,采用中和反应精馏塔实现氯化液中和、脱溶,然后使用水解精馏塔实现脱溶、以及三氯蔗糖-6-酯的水解制备三氯蔗糖的目的,最后经萃取-氧化-反萃取,实现了三氯蔗糖的连续制备,本申请摒弃了传统的间歇中和、脱溶、水解、以及冗长的三氯蔗糖-6-乙酸酯提纯工艺,显著提高了三氯蔗糖的制备和提纯的效率;且相对于现有技术,该申请采用液碱对氯化反应液进行中和,舍弃了氨水、以及甲醇钠的使用,一方面降低了后期生化处理中,氨氮含量带来的压力;另一方面避免了甲醇的使用 和产生,对环境友好性高,是一种高效、绿色、连续的三氯蔗糖制备工艺,具有极高的应用价值和实用性。In summary, this application uses the untreated chlorinated reaction liquid obtained during the preparation of sucralose-6-ester as a raw material, and uses a neutralization reaction rectification tower to achieve neutralization and precipitation of the chlorinated liquid, and then uses hydrolytic rectification The tower achieves the purpose of desolvation and hydrolysis of sucralose-6-ester to prepare sucralose, and finally through extraction-oxidation-back extraction, the continuous preparation of sucralose is realized. This application abandons the traditional batch neutralization, Precipitation, hydrolysis, and lengthy sucralose-6-acetate purification process significantly improved the efficiency of the preparation and purification of sucralose; For neutralization, the use of ammonia water and sodium methoxide is discarded. On the one hand, it reduces the pressure brought by the ammonia nitrogen content in the later biochemical treatment; on the other hand, it avoids the use and production of methanol, and is highly environmentally friendly. It is a kind of The efficient, green and continuous preparation process of sucralose has extremely high application value and practicability.
在本申请的描述中,需要说明的是,术语“中心”、“上”、“下”、“左”、“右”、“竖直”、“水平”、“内”、“外”等指示的方位或位置关系为基于附图所示的方位或位置关系,仅是为了便于描述本申请和简化描述,而不是指示或暗示所指的装置或元件必须具有特定的方位、以特定的方位构造和操作,因此不能理解为对本申请的限制。此外,术语“第一”、“第二”、“第三”等仅用于描述目的,而不能理解为指示或暗示相对重要性。In the description of this application, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer" etc. The indicated orientation or positional relationship is based on the orientation or positional relationship shown in the drawings, and is only for the convenience of describing the present application and simplifying the description, rather than indicating or implying that the referred device or element must have a specific orientation, use a specific orientation construction and operation, therefore should not be construed as limiting the application. In addition, the terms "first", "second", "third", etc. are used for descriptive purposes only and should not be construed as indicating or implying relative importance.
在本申请的描述中,需要说明的是,除非另有明确的规定和限定,术语“安装”、“相连”、“连接”应做广义理解,例如,可以是固定连接,也可以是可拆卸连接,或一体地连接;可以是机械连接,也可以是电连接;可以是直接相连,也可以通过中间媒介间接相连,可以是两个元件内部的连通。对于本领域的普通技术人员而言,可以具体情况理解上述术语在本申请中的具体含义。In the description of this application, it should be noted that unless otherwise specified and limited, the terms "installation", "connection", and "connection" should be understood in a broad sense, for example, it can be a fixed connection or a detachable connection. Connected, or integrally connected; it can be mechanically connected or electrically connected; it can be directly connected or indirectly connected through an intermediary, and it can be the internal communication of two components. Those of ordinary skill in the art can understand the specific meanings of the above terms in this application in specific situations.
综上所述,仅为本申请的具体实施方式,在本申请的上述教导下,本领域技术人员可以在上述实施例的基础上进行其他的改进或变形。本领域技术人员应该明白,上述的具体描述只是更好地解释本申请的目的,本申请的保护范围应以权利要求的保护范围为准。To sum up, the above is only a specific implementation manner of the present application. Under the above teaching of the present application, those skilled in the art can make other improvements or modifications on the basis of the above embodiments. Those skilled in the art should understand that the above specific description is only to better explain the purpose of the present application, and the protection scope of the present application should be based on the protection scope of the claims.
此外,本领域的技术人员能够理解,尽管在此所述的一些实施例包括其它实施例中所包括的某些特征而不是其它特征,但是不同实施例的特征的组合意味着处于本申请的范围之内并且形成不同的实施例。例如,在下面的权利要求书中,所要求保护的实施例的任意之一都可以以任意的组合方式来使用。In addition, those skilled in the art will appreciate that although some embodiments described herein include some features included in other embodiments but not others, combinations of features from different embodiments are meant to be within the scope of the present application. and form different embodiments. For example, in the following claims, any of the claimed embodiments may be used in any combination.
Claims (14)
- 一种三氯蔗糖的制备方法,其特征在于,包括:A preparation method of sucralose, characterized in that, comprising:中和步骤:使制备三氯蔗糖-6-酯的氯化反应液、第一液碱和第一回用水分段进入中和反应精馏塔,在蒸发条件下进行中和反应后,从所述中和反应精馏的塔顶采出溶剂混合物;从所述中和反应精馏的塔底采出氯化反应中和液;Neutralization step: make the chlorination reaction liquid, the first liquid caustic soda and the first reused water for preparing sucralose-6-ester enter the neutralization reaction rectification tower in sections, and carry out the neutralization reaction under evaporation conditions, from the The solvent mixture is extracted from the tower top of the neutralization reaction rectification; the chlorination reaction neutralization liquid is extracted from the bottom of the neutralization reaction rectification tower;水解步骤:使所述氯化反应中和液、第二液碱和第二回用水分段进入水解反应精馏塔,在蒸发条件下进行碱性水解反应,从所述水解反应精馏塔的塔顶采出废弃水溶液,从所述水解反应精馏塔的塔底采出三氯蔗糖水溶液;Hydrolysis step: make the chlorination reaction neutralization liquid, the second liquid alkali and the second reused water enter the hydrolysis reaction rectification tower in stages, and carry out the alkaline hydrolysis reaction under the evaporation condition, from the hydrolysis reaction rectification tower The waste aqueous solution is extracted from the top of the tower, and the sucralose aqueous solution is extracted from the bottom of the hydrolysis reaction distillation tower;萃取提纯步骤:将三氯蔗糖水溶液调节至中性后,依次进行萃取、氧化和反萃取以进行提纯;和Extraction and purification step: after adjusting the sucralose aqueous solution to neutrality, sequentially perform extraction, oxidation and back extraction for purification; and结晶步骤:将提纯后的三氯蔗糖水溶液经浓缩、结晶、过滤,得到三氯蔗糖粗产品和结晶母液。Crystallization step: Concentrate, crystallize and filter the purified sucralose aqueous solution to obtain crude sucralose product and crystallization mother liquor.
- 根据权利要求1所述的方法,其特征在于,所述方法还包括:The method according to claim 1, further comprising:母液循环回收步骤:将所述结晶母液回收至要进入所述结晶步骤的三氯蔗糖水溶液中,回收次数为1~5次。Mother liquor circulation recovery step: the crystallization mother liquor is recycled into the sucralose aqueous solution that will enter the crystallization step, and the recovery times are 1 to 5 times.
- 根据权利要求1所述的方法,其特征在于,所述中和反应精馏塔的塔高为10~30m;The method according to claim 1, characterized in that, the tower height of the neutralization reactive distillation tower is 10-30m;所述氯化反应液进料位置处于距离塔顶为塔高的3/10~2/5的位置,所述第一液碱的进料位置处于距离塔顶为塔高的1/2~3/5的位置,所述第一回用水的进料位置处于距离塔顶为塔高的7/10~4/5的位置。The feeding position of the chlorination reaction liquid is at a position of 3/10 to 2/5 of the tower height from the top of the tower, and the feeding position of the first liquid caustic soda is at a position of 1/2 to 3 of the tower height from the tower top. /5 position, the feed position of the first recycled water is at a position of 7/10 to 4/5 of the tower height from the top of the tower.
- 根据权利要求1所述的方法,其特征在于,在所述中和步骤中,在进行中和反应时,将所述中和反应精馏塔的塔顶温度设为30~40℃,塔底温度设为50~60℃。The method according to claim 1, characterized in that, in the neutralization step, when the neutralization reaction is carried out, the temperature at the top of the neutralization reaction distillation tower is set to 30-40° C. The temperature is set at 50-60°C.
- 根据权利要求1所述的方法,其特征在于,在所述水解步骤中,所述水解反应精馏塔的塔高为10~30m;The method according to claim 1, characterized in that, in the hydrolysis step, the tower height of the hydrolysis reaction distillation tower is 10-30m;所述氯化液中和液进料位置处于距离塔顶为塔高的2/5~3/7的位置,所述第二液碱的进料位置处于距离塔顶为塔高的1/2~3/5的位置,所述第二回用水的进料位置处于距离塔顶为塔高的4/5~9/10的位置。The feed position of the chlorinated liquid neutralizing liquid is 2/5 to 3/7 of the tower height from the top of the tower, and the feed position of the second liquid caustic soda is 1/2 of the tower height from the tower top. ~3/5 of the position, the feed position of the second recycled water is at a position of 4/5~9/10 of the tower height from the top of the tower.
- 根据权利要求1所述的方法,其特征在于,在所述水解步骤中,在进行水解反应时,将所述中和反应精馏塔的塔顶温度设为30~40℃,塔底温度设为 50~60℃。The method according to claim 1, characterized in that, in the hydrolysis step, when carrying out the hydrolysis reaction, the temperature at the top of the neutralization reaction distillation tower is set at 30 to 40°C, and the temperature at the bottom of the column is set at It is 50-60°C.
- 根据权利要求1所述的方法,其特征在于,所述中和反应精馏塔和所述水解反应精馏塔均为填料塔或板式塔,优选为填料塔,其中,所述填料塔中的填料为聚四氟波纹板或θ环,填料高度为所述填料塔塔高的1/3~2/3。The method according to claim 1, characterized in that, both the neutralization reaction rectification tower and the hydrolysis reaction rectification tower are packed towers or tray towers, preferably packed towers, wherein, in the packed towers The filler is polytetrafluoro corrugated plate or θ ring, and the height of the filler is 1/3 to 2/3 of the height of the packed tower.
- 根据权利要求1所述的方法,其特征在于,在所述中和步骤中,所述氯化反应液、所述第一液碱和第一回用水的体积比为10~15:1:1;The method according to claim 1, characterized in that, in the neutralization step, the volume ratio of the chlorination reaction solution, the first liquid alkali and the first recycled water is 10-15:1:1 ;在所述水解步骤中,所述氯化反应中和液、所述第二液碱和第二回用水的体积比为40~60:1:10~20。In the hydrolysis step, the volume ratio of the chlorination reaction neutralization liquid, the second liquid caustic soda and the second recycled water is 40-60:1:10-20.
- 根据权利要求1所述的方法,其特征在于,所述第一液碱和所述第二液碱均为氢氧化钠或氢氧化钾的水溶液,优选为氢氧化钠的水溶液。The method according to claim 1, characterized in that, both the first liquid caustic and the second liquid caustic are aqueous solutions of sodium hydroxide or potassium hydroxide, preferably aqueous solutions of sodium hydroxide.
- 根据权利要求1所述的方法,其特征在于,在所述萃取提纯步骤中,所述将三氯蔗糖水溶液调节至中性包括:The method according to claim 1, characterized in that, in the extraction and purification step, adjusting the sucralose aqueous solution to neutrality comprises:采用无机酸将所述三氯蔗糖水溶液的pH值调节至6~8,其中所述无机酸为盐酸、硫酸或磷酸中的一种。The pH value of the sucralose aqueous solution is adjusted to 6-8 by using an inorganic acid, wherein the inorganic acid is one of hydrochloric acid, sulfuric acid or phosphoric acid.
- 根据权利要求1所述的方法,其特征在于,在所述萃取提纯步骤中,进行萃取所用的萃取剂为乙酸乙酯和/或乙酸丁酯;The method according to claim 1, characterized in that, in the extraction and purification step, the extractant used for extraction is ethyl acetate and/or butyl acetate;所述萃取剂的体积用量与所述氯化反应中和液的比为1~5:1。The ratio of the volumetric dosage of the extractant to the chlorination reaction neutralizing liquid is 1-5:1.
- 根据权利要求1所述的方法,其特征在于,在所述萃取提纯步骤中,所述氧化所用的氧化剂为次氯酸钠或臭氧;其中,所述次氯酸钠的质量用量为所述萃取得到的有机相的体积的0.01~0.1%;所述臭氧的体积用量为所述萃取得到的有机相的体积的0.01~0.1%;The method according to claim 1, characterized in that, in the extraction and purification step, the oxidant used in the oxidation is sodium hypochlorite or ozone; wherein, the mass consumption of the sodium hypochlorite is the volume of the organic phase obtained by the extraction 0.01% to 0.1% of the ozone; the volumetric dosage of the ozone is 0.01% to 0.1% of the volume of the organic phase obtained by the extraction;所述氧化的氧化时间为3~12h。The oxidation time of the oxidation is 3-12 hours.
- 根据权利要求1所述的方法,其特征在于,在所述萃取提纯步骤中,所述反萃取的反萃取剂为水,所述反萃取剂的体积用量与所述萃取得到的有机相的体积的比为1~5:1。method according to claim 1, is characterized in that, in described extracting and purifying step, the stripping agent of described stripping is water, and the volume consumption of described stripping agent and the volume of the organic phase that described extraction obtains The ratio is 1 to 5:1.
- 根据权利要求1所述的方法,其特征在于,在所述结晶步骤中,所述浓缩的浓缩温度为40~60℃,浓缩真空度为-0.1~-0.5Mpa,浓缩至所述三氯蔗糖水溶液中三氯蔗糖浓度为80~140g/L。The method according to claim 1, characterized in that, in the crystallization step, the concentration temperature of the concentration is 40-60°C, the concentration vacuum is -0.1--0.5Mpa, and the sucralose is concentrated to The concentration of sucralose in the aqueous solution is 80-140g/L.
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