CN1176062C - Preparation method of glycine - Google Patents
Preparation method of glycine Download PDFInfo
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- CN1176062C CN1176062C CNB02125236XA CN02125236A CN1176062C CN 1176062 C CN1176062 C CN 1176062C CN B02125236X A CNB02125236X A CN B02125236XA CN 02125236 A CN02125236 A CN 02125236A CN 1176062 C CN1176062 C CN 1176062C
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Abstract
The present invention relates to a method for preparing glycine, particularly to a method for preparing glycine in an alcohol phase by using two ammonia gas introducing steps. The method comprises the following two steps: (1) introducing ammonia gas to a mixture of chloroacetic acid and alcohol to obtain a product of ammonium chloroacetate; (2) introducing ammonia gas to a mixture of the ammonium chloroacetate, alcohol and urotropine to obtain glycine.
Description
Technical Field
The invention relates to a method for preparing glycine in an alcohol phase, in particular to a method for preparing glycine in the alcohol phase by adopting two steps of introducing ammonia, which comprises the following two steps: (1) introducing ammonia gas into the mixture of chloroacetic acid and alcohol to obtain a product ammonium chloroacetate; (2) and (3) introducing ammonia gas into the mixture of ammonium chloroacetate, alcohol and urotropine to obtain the glycine.
Background
At present, glycine is produced by a plurality of methods, wherein, α -halogenated acid method is a domestic main industrial production method, and chloroacetic acid and ammonia gas are used as raw materials and react in a solvent phase in the presence of a catalyst urotropine (hexamethylenetetramine).
The solvent phase can be an aqueous phase using the α -haloacid method, see for example US3215736, US3510515, or a multi-component solvent phase, such as an alcohol-water phase, chloroform-alcohol-water phase, etc., see for example RU2009123, RU2009122, amino acids and biological resources 18 (1996) 1 st, 9-10 pages, Anhui university newspaper (Nature science edition) 20 th (1997) 4 th, 352 nd 354 pages, chemical world 28 (1993) 4 th, 185 nd 189 nd page 189.
However, the method for producing glycine containing aqueous phase has the defects that the catalyst cannot be recovered, the consumption is high, the catalytic efficiency is low, unreacted raw materials cannot be recycled, and hydrolysate hydroxyacetic acid is easy to generate due to strong alkalinity, water content and the like of a system, so that waste is caused, and the environment is polluted; inorganic salts such as ammonium chloride and the like generated in the reaction are difficult to separate, and the post-treatment capacity is large; difficult judgment of the synthesis reaction end point and the like.
In addition, processes for the preparation of glycine in which the solvent is an alcohol phase, such as ethanol or methanol, are also reported in the literature, see, for example, Shenyang chemical institute, proceedings, volume 11 (1997), 3, p 192-195; the chemical world 1990, 9 th stage, p.419-420. According to the method, glycine is prepared by one-step ammonia introduction reaction (alcohol phase one-step method) in an alcohol phase, but the method still has the defects of long reaction time, difficult control of the reaction and low catalyst efficiency, and 5-7% of two byproducts (B, C, see a side reaction formula below and the same below) are generated through HMR detection, so that the yield is still low. In addition, although the yield of the production method is slightly improved compared with the one-step method of the alcohol phase, the production method of the mixed solvent is provided, 4-5% of two byproducts are generated (B, C) in HMR detection, the solvent is difficult to recover, the solvent consumption is large, the solvent consumption cost is much higher than that of the one-step method of the alcohol phase, and the production method is not suitable for industrial large-scale production.
Therefore, there is still a need for a better industrial production method.
As a result of intensive studies in view of the drawbacks of the prior art, the present inventors have found that the production of both by-products (B, C) can be controlled to 0.5% or less by HMR detection using the alcohol phase two-step method of the present invention described below, that glycine can be produced in high yield and high quality, and that glycine is more suitable for industrial production, and thus have completed the present invention.
Disclosure of Invention
The invention aims to provide a method for preparing glycine by adopting two steps of introducing ammonia into an alcohol phase, which comprises the following two steps:
(1) introducing ammonia gas into the mixture of chloroacetic acid and alcohol to obtain a product ammonium chloroacetate;
(2) and (3) introducing ammonia gas into the mixture of ammonium chloroacetate, alcohol and urotropine to obtain the glycine.
Specifically, the method adopts an alcohol phase two-step method to synthesize the glycine, which can be expressed by the following reaction formula:
in a specific embodiment, the present invention provides an alcohol phase two-step process for the preparation of glycine comprising the following two steps:
(1) introducing ammonia gas into a mixture of chloroacetic acid and alcohol such as ethanol and/or methanol at 0-40 ℃, controlling the temperature to be not higher than 60 ℃, preferably not higher than 50 ℃ for 0.5-1 hour till the pH value of a reaction system is 6.5-7.5, separating, such as centrifuging or pressure filtering, to obtain a product ammonium chloroacetate, and feeding the mother liquor into the next first step for reaction for reuse, wherein the molar ratio is as follows: chloroacetic acid, alcohol and ammonia are 1 to (4.4-6.0) to (1.05-1.2),
(2) controlling the temperature at 50-65 ℃, keeping the pH value at 6.5-7.5, introducing ammonia gas into a mixture of ammonium chloroacetate, alcohol such as ethanol and/or methanol and urotropine, reacting for 1-2 hours until the pHvalue of a reaction system reaches 7.5-8.0, preserving the temperature for 0.5 hour, separating, such as centrifuging or pressure filtering, obtaining a crude glycine batch, and performing a second step reaction for reuse, wherein the molar ratio is as follows: ammonium chloroacetate, alcohol, urotropin and ammonia are 1 to (6.0-7.5) to (0.07-1.05) to (1.05-1.2).
The crude glycine, the reaction product, may be purified by methods known in the art, for example, by recrystallization from an alcohol phase such as methanol and/or ethanol, or by ion exchange, as described, for example, in CN 1052479A; "amino acids and biological resources" Vol.18, No. 1, pages 9-10.
The two-step reaction method can avoid the following two side reactions:
i)
(B)
ii)
(C)
the whole reaction system is controlled to be carried out in an alcohol phase system, and compared with a water phase system, the method has the following advantages: firstly, the catalyst can be continuously used, and by adopting the alcohol phase two-step method, the catalyst can be continuously used for ten times or even twenty times, so that the defects that the catalyst cannot be recovered, the consumption is high and the catalytic efficiency is low when a water phase reaction is adopted are completely overcome; secondly, the product glycine is crystallized and precipitated once being generated, so that the generation of a byproduct B, C can be avoided; thirdly, as no water exists in the system, the generation of a byproduct, namely glycolic acid can be avoided; fourthly, the method has small solvent loss.
Compared with the alcohol phase one-step method in the prior art, the method has the following advantages: firstly, the catalytic efficiency is higher, the catalyst is easy to decompose in an alcohol phase one-step method, and can be used repeatedly for about three times, the method can avoid the decomposition of the catalyst, and the content of the catalyst is kept stable after the catalyst is continuously used for more than twenty times; secondly, the reaction temperature is stable and easy to control, and the occurrence of two side reactions is greatly reduced; thirdly, the reaction time is shortened; fourthly, the amount of B, C side reactions can be reduced to the minimum, thereby improving the reaction yield and the quality of glycine; fifthly, the reaction end point can be accurately judged, and the whole reaction condition is easy to control, so that the method is more suitable for industrial production.
Examples
The invention is further illustrated by the following non-limiting examples.
EXAMPLE 1 Synthesis of Glycine by alcohol phase two-step Process
Step (1): 50g (0.508mol) chloroacetic acid and 75g (2.320mol) methanol are added into a four-neck flask provided with a stirrer, a thermometer, a reflux condenser and a gas guide tube, ammonia gas is slowly introduced at 0-40 ℃ after stirring and dissolving, the temperature is controlled to be not more than 60 ℃ within 0.5-1 hour until the pH value of the system is reduced to 6.5-7.5, then the temperature is reduced to 20 ℃, and pressure filtration or centrifugation is carried out to obtain ammonium chloroacetate crystals, and mother liquor enters the next batch for reaction for reuse. Step (2): adding 56.528g (about 0.507mol) of ammonium chloroacetate, 120g (3.75mol) of methanol and 8g (0.056mol) of urotropine which are products of the reaction in the step (1) into a four-neck flask provided with a stirrer, a thermometer, a reflux condenser and a gas guide tube, stirring for dissolution, heating to 50 ℃, starting introducing ammonia, maintaining the temperature at 50-65 ℃, reacting for 1-2 hours when the pH value of a reaction system is 6.5-7.0 until the pH value of the system is 7.5-8.0, preserving heat for 0.5 hour, cooling to 20-30 ℃, performing pressure filtration or centrifugation to obtain a glycine crude product, and recycling mother liquor in the next batch of reaction. The crystal is dried to obtain 64.94g of crude glycine with the content of 58.52 percent and the in-situ yield is 99.7 percent. The crude product is electrodialyzed by adopting an alcohol-water system to obtain wet refined product, and is dried at 80 ℃ to obtain 35.221g of glycine with the content of 99 percent, the total yield is 92.4 percent, and the catalyst and the solvent can be continuously used. The first step reaction solvent can be used for more than forty times, and the second step reaction catalyst and solvent can be used for more than twenty times.
The results of ten times before application are shown in the table:
number of times | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 |
Glycine crude product (g) | 64.94 | 64.96 | 64.98 | 64.84 | 64.88 | 64.69 | 65.02 | 64.95 | 64.73 | 65.12 |
Glycine content (%) | 58.52 | 58.38 | 58.52 | 58.52 | 58.54 | 58.60 | 58.48 | 58.42 | 58.62 | 58.36 |
Catalyst content (g/L) | 42.05 | 42.04 | 42.04 | 42.05 | 42.05 | 42.04 | 42.05 | 42.04 | 42.03 | 42.02 |
In situ yield (%) | 99.70 | 99.50 | 99.30 | 99.50 | 99.60 | 99.40 | 99.70 | 99.50 | 99.50 | 99.70 |
Comparative example 1 Synthesis of Glycine by alcohol phase one-step Process
50g (0.508mol) of chloroacetic acid, 8g (0.056mol) of urotropine and 100g (3.125mol) of methanol are added into a four-neck flask provided with a stirrer, a thermometer and a reflux condenser, after stirring and mixing, the temperature is raised to 65 ℃, ammonia gas is slowly introduced within 2 hours, the pH value is maintained at 7-8, the temperature is kept for 2-3 hours, cooling crystallization is carried out, and 58.61g of 58.5 percent glycine crude product is obtained after suction filtration and drying, and the in-situ yield is 89.9 percent. Adding 1.8 times of water into the crude product, heating to dissolve, adding 2.5 times of ethanol into the solution, cooling to crystallize, filtering, washing with ethanol for three times, and drying at 80 ℃ to obtain 31.54g of glycine with the content of 99%, wherein the total yield is 81.88%. The catalyst and the solvent can be used for only five times at most.
Claims (4)
1. A process for the preparation of glycine in the alcohol phase comprising the steps of:
(1) introducing ammonia gas into the mixture of chloroacetic acid and alcohol to obtain a product ammonium chloroacetate;
(2) and (3) introducing ammonia gas into the mixture of ammonium chloroacetate, alcohol and urotropine to obtain the glycine.
2. The method according to claim 1, wherein
(1) Introducing ammonia gas into the mixture of chloroacetic acid and alcohol at 0-40 ℃, controlling the temperature to be not higher than 60 ℃ within 0.5-1 h until the pH value of the reaction system is 6.5-7.5, and separating to obtain a product ammonium chloroacetate;
(2) controlling the temperature at 50-65℃, keeping the pH value at 6.5-7.5, introducing ammonia gas into the mixture of ammonium chloroacetate, alcohol and urotropine, reacting for 1-2 hours until the pH value of the reaction system is 7.5-8.0, preserving the temperature for 0.5 hour, and separating to obtain the glycine.
3. A process according to claim 1 or 2, wherein
In the step (1), the mol ratio of chloroacetic acid, alcohol and ammonia is 1: 4.4-6.0: 1.05-1.2;
in the step (2), the mol ratio of ammonium chloroacetate, alcohol, urotropine and ammonia is 1: 6.0-7.5: 0.07-0.15: 1.05-1.2.
4. A process according to any one of claims 1 to 2 wherein the alcohol is methanol or ethanol.
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CN1305836C (en) * | 2003-10-14 | 2007-03-21 | 重庆三峡英力化工有限公司 | Method for preparing glycine |
CN103086900B (en) * | 2011-11-04 | 2015-02-25 | 海南正业中农高科股份有限公司 | Method of production of glycine by circulation environmental-friendly method in alcohol phase |
CN107253916B (en) * | 2017-05-12 | 2019-02-22 | 仇荣庆 | A kind of environmentally protective new method for preparing amion acetic acid |
CN109180508A (en) * | 2018-10-22 | 2019-01-11 | 刘长飞 | A kind of method of electrodialytic membranes separation production glycine |
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