RU2722835C1 - Method of purifying propylene oxide from impurities of carbonyl and carboxyl compounds - Google Patents

Abstract

FIELD: technological processes.SUBSTANCE: invention relates to a method of purifying propylene oxide, obtained using the technology of epoxidation of propylene with hydrogen peroxide on a titanium silicalite catalyst (HPPO technology), from impurities of carbonyl compounds (aldehydes and ketones) of general formula RCORand carboxyl compounds (carboxylic acids and esters thereof) of general formula RCOOR, where R– hydrocarbon radical C, and R– hydrogen atom or methyl radical. Substance of the method consists in reaction of carbonyl and carboxyl compounds with formaldehyde and alkali, further dissolution of products of their interaction with water and distillation of purified propylene oxide from the obtained mixture.EFFECT: products formed during chemical purification can be recycled without application of additional special processing technologies.1 cl, 2 dwg, 1 ex

Description

Propylene oxide is a large-capacity product. Its world production is about 9 million tons annually. There are three main industrial methods for the production of propylene oxide: chlorohydrin, hydroperoxide, and epoxidation of propylene with hydrogen peroxide under the action of the TS-1 zeolite catalyst of titanium silicalite. The latter method is the most modern and environmentally friendly, this technology is called the HPPO process (Hydrogen Peroxide to Propylene Oxide).

The most preferred solvent in this process is methanol, due to the high catalytic activity of the TS-1 catalyst in its presence. The resulting propylene oxide contains, as a rule, an admixture of solvent, and also, due to side reactions, impurities of organic compounds with a carbonyl or carboxyl group, in the molecule of which there are from one to four carbon atoms.

In the patent RU 2472786, as well as the inventions described in EP-A 100119, WO 2007074101 A1 and US 7378536 B2, methods were proposed for the synthesis of propylene oxide by epoxidation of propylene with hydrogen peroxide. At the stage of separation of propylene oxide from the reaction mixture, a material stream is obtained, which is a crude concentrate of propylene oxide, which, depending on the synthesis conditions, contains more or less admixture of formaldehyde, acetaldehyde, propanal, acetone, methyl formate, methyl acetate, formic and acetic acid. Other aldehydes, ketones, esters and carboxylic acids are also possible.

The formation of carbonyl compounds, carboxylic acids and their esters occurs regardless of the design of the reactor unit and is caused by the reactivity of the starting and intermediate substances involved in the production of propylene oxide by the HPPO method.

Modern requirements for the quality of commercial propylene oxide strictly standardize the content of the basic substance at a level of at least 99.96% by weight, which is due to the main scope of the product - the production of polyurethanes. In a commercial product, the total content of organic impurities, including methanol, carbonyl compounds, carboxylic acids and esters, should not exceed 280 ppm (according to GOST 23001-88 "Technical propylene oxide. Technical conditions"). The content of each impurity should not exceed 100 ppm. This fact requires the purification of propylene oxide obtained by HPPO technology, especially efficiently.

All of the above impurities can hardly be removed using simple rectification. In mixtures containing more than 98 mol%. propylene oxide, these compounds have relative volatility comparable to propylene oxide, which leads to the necessity of using distillation columns with a large number of plates and the operation of columns with large reflux numbers. Therefore, the purification of propylene oxide by simple distillation becomes economically unprofitable due to high investment and energy costs.

In the literature, you can find many ways to remove aldehydes and ketones, as well as methanol from propylene oxide. Extensive distillation is a widely used method for separating difficultly separated mixtures. EP-A 1009746 describes the purification of propylene oxide by extractive distillation from methanol and acetaldehyde. It is proposed to use polar solvents with one or more hydroxyl groups as an extracting agent. This method removes not only methanol from propylene oxide, but also part of the acetaldehyde. The disadvantage of the proposed method is visible from the above examples - the content of methanol and acetaldehyde in the purified propylene oxide exceeds 100 ppm. Thus, the obtained propylene oxide requires additional purification steps.

A similar method for purification of propylene oxide from methanol, acetone and water using extractive distillation using dipropylene glycol as an extracting agent is described in US Pat. No. 5,610,587. The above examples show effective removal of acetone and water and less effective removal of methanol. However, the patent does not say anything about the possibility of removing other impurities, such as acetaldehyde. It is also worth noting that satisfactory results for this method were obtained on a distillation column having 120 plates.

For the removal of methyl formate from propylene oxide, extractive distillation methods with hydrocarbons as extracting agents are proposed. From US Pat. No. 3,337,425, a method is known using olefins, aromatic compounds and mixtures thereof to remove impurities with a carbonyl and carboxyl group with boiling points plus / minus 5 ° C from the boiling point of propylene oxide. As impurities removed by the proposed method, the authors of the patent call acetaldehyde and methyl formate. A similar approach is proposed in US Pat. No. 3,391,063, where methyl formate is removed from propylene oxide during extractive distillation with benzene. In addition to extractive distillation, azeotropic distillation to remove methyl formate is also proposed. US Pat. No. 4,014,753 describes an azeotropic rectification of propylene oxide with 2-methylpentane, and US Pat. No. 3,071,601 uses n-pentane for the same purpose.

In addition to the above, more complex options for the execution of extractive rectification are proposed. EP 0 645 381 describes a multi-stage purification of propylene oxide from impurities by extractive distillation with several extracting agents. In the proposed purification process, C _2-6 alkylene glycol is used as an extracting agent in the first and last stages, and in the intermediate stages, extractive rectification is carried out with C _7-10 alkanes. Using this method, both polar, including water, and non-polar compounds can be removed from propylene oxide. However, it is worth noting the significant complexity of the allocation scheme, which casts doubt on the possibility of its implementation in practice.

A different approach to the removal of methylformite by extractive distillation is described in US Pat. No. 2,622,060, in which the authors propose using an aqueous alkali solution, for example, sodium hydroxide, as the extracting agent.

Despite the high efficiency of this method for the removal of methyl formate, it also has significant disadvantages. The batch embodiment effectively removes methyl formate and acetaldehyde, but leads to significant losses of propylene oxide due to the opening of the oxirane ring to form propylene glycol derivatives. When the cleaning process is carried out continuously, the cleaning is less effective, since the purified propylene oxide contains, judging by the above examples, significantly more than 100 ppm of acetaldehyde. Therefore, in this case, additional purification steps are required in order to obtain propylene oxide of the desired purity.

A similar option for the removal of methyl formate from propylene oxide is also proposed in US Pat. No. 3,477,919, but with the only fundamental difference that the methyl saponification reagent is fed to the column as an aqueous suspension of calcium hydroxide. Accordingly, to all the drawbacks of the method from US 2622060, another significant drawback is added - the complexity of controlling the operation of the column, in which a three-phase system is formed.

Another method for removing methyl formate using a saponification reaction is given in US Pat. No. 5,107,002. This method proposes to pass propylene oxide containing methyl formate through a fixed layer of an ion-exchange resin, for example Amberlist A-21 weakly basic resin, and regenerate the resin with aqueous alkali solutions as soon as the concentration methyl formate at the exit of the apparatus will reach unsatisfactory values. Unfortunately, the description of the method does not say anything about the removal of acetaldehyde. Considering the similarity of approaches to the removal of methyl formate from the point of view of the chemistry of the process in the methods of US 2622060, US 3477919, US 5107002, it can be assumed that in the latter case, it will be impossible to achieve the desired indicators for the residual acetaldehyde content in propylene oxide.

To remove acetaldehyde from propylene oxide, the use of adsorption purification is proposed. In an article by Li et al. (ACS Omega 2018, 3, 11, 15272-15280) presents the results of a study on the purification of propylene oxide produced by HPPO technology from acetaldehyde by adsorption. Adsorption was studied on molecular sieves with pore sizes from 2.1 to 10 Å and also on activated carbon. The results show the effectiveness of a molecular sieve with a pore size of 4.9 - 5.6 Å for the purification of propylene oxide from acetaldehyde.

A chemical method for removing aldehydes is described in US Pat. No. 3,816,478, which proposes to remove formaldehyde, acetaldehyde and propanal by passing the crude propylene oxide through a layer of solid sodium bisulfite. Significant disadvantages of the method include the need for periodic regeneration of the surface of sodium bisulfite, since the reaction products of aldehydes and sodium bisulfite are sparingly soluble compounds deposited on its surface. For this purpose, it is recommended that the sodium bisulfite layer be washed with an inert solvent, for example n-pentane, isooctane, isobutane, etc., followed by drying with an inert gas at a temperature of 75-150 ° C. It is also noted in the patent that propylene oxide must necessarily contain water, preferably in an amount of about 2 wt. % This, in turn, can lead to pollution of sulfur dioxide purified from aldehydes by sulfur dioxide due to hydrolysis of sodium bisulfite. From the examples shown, the effectiveness of the method with respect to the removal of acetaldehyde is visible, but its low efficiency with the removal of acetone.

Another method for the chemical removal of aldehydes, as well as ketones and esters from propylene oxide is known from patent CH 436240. The proposed method is based on the selective reaction of these compounds with sodium borohydride. High selectivity of the method is its significant advantage, but it also has no less significant drawbacks. These include the technological complexity of working with sodium borohydride, as well as the formation of poorly soluble organic boron compounds during the reaction. The effectiveness of the method with respect to the removal of aldehydes is confirmed by the examples given in the patent.

Patent EP 0004019 proposes a method for the distillation of oxiranes from aldehydes and ketones, which consists in feeding a compound with a primary amino group —NH ₂ to the distillation column at a level above the entry point of the crude propylene oxide. As such, either pure liquid compounds or solutions of liquid or solid compounds in inert solvents can be used. The authors of the patent, referring to the literature data, separately note that in the case of using hydrazine and its solutions, the method has some disadvantages. The reaction of hydrazine with propanal proceeds at room temperature very slowly, and the reaction products of hydrazine with acetaldehyde are poorly soluble compounds, which can lead to the formation of unwanted deposits on the inside of the distillation column. The above examples confirm the effectiveness of various compounds with an amino group for the purification of oxiranes from aldehydes and ketones.

The main disadvantages that to one degree or another are inherent in all of the above methods are limited efficiency, technological complexity of execution, or strict focus of the method on extracting only one compound or one class of compounds from propylene oxide, while propylene oxide obtained by the HPPO technology contains a number of impurities belonging to different classes of organic compounds.

The only universal method for purification of propylene oxide from aldehydes, ketones and esters is described in patent EP 1424332, which is in essence a further development of patent EP 0004019. The inventors of EP 1424332 propose purifying propylene oxide from aldehydes and ketones by extractive distillation when used as an extracting agent an aqueous solution of hydrazine fed to the column above the feed point of the crude propylene oxide. In contrast to the claims in EP 0004019 regarding the disadvantages of using hydrazine and its solutions, the authors of this patent claim that the reaction of carbonyl compounds with hydrazine proceeds quickly and does not lead to the formation of undesirable deposits in the column. In order to remove methyl formate, in the proposed method, the propylene oxide stream is mixed with an aqueous sodium hydroxide solution before being fed to the extractive distillation column and sent to a reactor where the reaction of saponification of methyl formate to methanol and sodium formate takes place. The application examples shown in the patent prove the high efficiency of the method for removing methyl formate and acetaldehyde from propylene oxide. In addition, in parallel with carbonyl compounds, methanol is also removed from propylene oxide in the process of extractive rectification, since the aqueous hydrazine solution supplied to the column contains a large amount of water, which is known to be a good extracting agent with respect to methanol in this system. The only, but quite significant, drawback of this method is the formation of hydrazones - the reaction products of hydrazine with carbonyl compounds. These nitrogen-containing compounds make it impossible to directly discharge wastewater from the process into bio-treatment. Therefore, in the proposed embodiment of the propylene oxide purification technology, an additional stage of catalytic hydrogenation of the formed hydrazones into the corresponding amines is introduced.

The aim of the present invention is to develop a method for purification of propylene oxide from aldehydes, ketones, esters and carboxylic acids with the number of carbon atoms in each molecule of a substance from one to four, which can significantly reduce the content of these impurities without the use of a catalytic hydrogenation step.

The essence of the invention

The stated goal is achieved by the following sequence of technological operations:

I. Propylene oxide containing impurities and a solvent, for example methanol, is fed into the first reaction apparatus, pos. 1 in FIG. 1 (hereinafter referred to as the reactor), to which alkali and formaldehyde are also fed. Under given conditions and concentrations of reagents, several types of reactions will proceed in the reactor:

- saponification of esters in an alkaline environment;

- condensation between the removed aldehydes and ketones and the added formaldehyde, followed by the cross-reaction of Cannizzaro in the case of aldehydes;

- neutralization of carboxylic acids with alkali.

II. The reaction from paragraph I. leads to the formation of products insoluble in the reaction medium and, as a result, precipitated. Therefore, the reaction stream from the reactor is supplied to the second reaction apparatus, pos. 2 in FIG. 1 (hereinafter the homogenizer), where the heterogeneous reaction mixture is mixed with water, and the precipitate is completely dissolved and a homogeneous system is obtained, since all the reaction products from paragraph I. are readily soluble in water. It is also possible to use a single reaction apparatus with a special section for supplying water, thereby combining the functions of a reactor and a homogenizer.

III. After the homogenization step is completed, the mixture is fed to the stripping column, pos. 3 in FIG. 1, where its separation occurs. The reaction products from paragraph I., water, and unreacted residues of alkali and formaldehyde leave the column as a bottoms product, which after neutralization with acid can be sent for bio-treatment. The distillate selected from the head of the column is purified propylene oxide mixed with a solvent. In the case of the NRPO process, this solvent is methanol, which can be removed from propylene oxide by one of the known methods, for example, extractive distillation. A block diagram of the proposed process is shown in FIG. 1.

Description of the invention

The proposed method for removing impurities is particularly well suited for the purification of propylene oxide produced by the HPPO technology, since it allows you to remove all impurities of carbonyl compounds, general formula R ₁ COR ₂ , and carboxyl compounds, general formula R ₁ from propylene oxide using an alkaline formaldehyde solution COOR ₂ . The radical R ₁ is a saturated or unsaturated linear or branched hydrocarbon residue containing from 1 to 3 carbon atoms, and the radical R ₂ is CH ₃ or H is a hydrogen atom. Waste water immediately after neutralization can be sent to the biological neutralization unit, which is a significant advantage of this invention and differs from the method of chemical purification of propylene oxide from carbonyl and carboxyl compounds proposed in patent EP 1424332 using alkali and hydrazine.

The proposed method can be implemented in a batch mode, but a continuous process is more preferable. This is because in a continuous process the contact time of propylene oxide with alkali is minimized, which reduces the loss of propylene oxide due to the formation of propylene glycol derivatives.

In the proposed method, propylene oxide containing impurities and a solvent is mixed in the reactor according to claim I. with alkali and formaldehyde. As the reactor according to claim I., any type of reaction apparatus suitable for working with heterogeneous systems can be used. In the most preferred embodiment of the invention, the reactor should be close in its characteristics to the ideal displacement reactor and have a design that allows reliably removing a multiphase stream from the reactor. In addition, the reactor should be equipped with a system for maintaining the set temperature. The temperature in the reactor may range from 20 ° C to 80 ° C, but in a preferred embodiment of the invention should not exceed 35 ° C. The pressure in the reactor should be chosen so as to avoid boiling of the reaction mixture, since the reactions according to claim I. can proceed only in the condensed phase. The residence time of the reaction mixture in the reactor can be from 3 to 180 minutes. As alkali, hydroxides of alkali and alkaline earth metals, as well as their salts with the corresponding weak acids, can be used. In addition to hydroxides and salts, the use of oxides of alkali and alkaline earth metals is also possible. Alkali can be fed into the reactor both in solid form or in the form of an aqueous solution, or a solution in an inert solvent. The most preferred option is a solution of sodium hydroxide or potassium hydroxide in methanol. Formaldehyde can also be fed to the reactor as an aqueous solution, or as a solution in any inert solvent. In addition to the formaldehyde solution, paraform can also be used. The most preferred option is a solution of paraform in methanol. In addition, the option of applying a single stream of a three-component solution consisting of paraformal alkali and an inert solvent, preferably methanol, can be applied.

The reaction scheme of the reactor according to claim I. is shown in FIG. 2. The amount of alkali supplied to the reactor should be such that the concentration of alkali in the reactor after the saponification of esters according to item A), the neutralization of carboxylic acids according to item E) and the Cannizzarro reaction according to item C) and item D ) was established at a level of from 0.1 to 10.0 wt.%, but in the most preferred embodiment was in the range of 0.5-2 wt. %

The amount of formaldehyde supplied to the reactor should be chosen so as to ensure the most complete reaction according to p. B), p. C) and p. D). To remove ketones, the molar ratio [ketone]: [formaldehyde] for each ketone to be removed may be in the range from 1: 0.5 to 1: 2, but the most preferred ratio is 1: 1.2. To remove aldehydes, excluding acetaldehyde, the molar ratio [aldehyde]: [formaldehyde] for each aldehyde removed may lie in the range from 1: 0.5 to 1: 6, but the most preferred ratio is 1: 3.6. To remove acetaldehyde, the molar ratio [aldehyde]: [formaldehyde] may be in the range from 1: 0.5 to 1: 8, but the most preferred ratio is 1: 4.8.

As a homogenizer according to claim II. any type of apparatus can be used whose design allows efficient mixing of the heterogeneous stream leaving the reactor and the stream of water also supplied to the homogenizer. The device must be equipped with a heating system that supports the process temperature from 20 ° C to 80 ° C, but the most preferred temperature for the operation of the homogenizer is 20 ° C. The residence time of the reaction mass in the homogenizer may lie in the range from 0.5 to 180 minutes. An alternative to a separate apparatus can also be a special section in the reactor, where the flow of the reaction mixture will be mixed with the flow of water. Since in the presence of large quantities of water, its reaction with propylene oxide can begin, leading to the undesirable formation of propylene glycol, the feed water stream must be selected as minimally necessary only to obtain a homogeneous mixture in the homogenizer.

The specific value of the water flow depends directly on the form of supply of the reagents to the reactor and the amount of poorly soluble reaction products formed, that is, on the amount of impurities in the propylene oxide.

The distillation column according to claim III. It is a distillation column equipped with a still bottom evaporator and condenser. The column may consist only of a reinforcing part, but in a preferred embodiment it has a distant and reinforcing part. Irregular or regular nozzles, plates of various designs, as well as any combination of the listed mass transfer devices can act as mass transfer devices. Mass transfer devices should provide the number of theoretical plates in the distant part of the column from 5 to 25, and in the reinforcing part from 5 to 50. The reflux ratio can be in the range from 0.1 to 10.0, and the absolute pressure in the column in the range from 0.2 to 5 bar, although the most preferred pressure range is 1-2.5 bar.

The invention is illustrated by the following example of its application.

Examples

Propylene oxide containing 0.54% wt. methyl formate, 0.06% wt. methyl acetate, 1.12% wt. acetaldehyde, 0.05% wt. propanal, 0.10% wt. acetone and 1.30% wt. methanol, pumped in an amount of 59 g / h was fed into the reactor according to claim I., which is a tubular reactor operating at atmospheric pressure, with a heating jacket, in which the thermostat was maintained at a temperature of 30 ° C. There, in a quantity of 6 g / h, a solution of paraform and sodium hydroxide in methanol was fed with a concentration of 18% wt. sodium hydroxide and 22% wt. formaldehyde. To reliably mix the streams, the inlet reactor was equipped with a static mixer. The estimated residence time of the reaction mixture was 40 minutes. After the reactor, the reaction mixture by gravity fell into the homogenizer according to claim II., Where it was mixed with a stream of water supplied to the apparatus by a pump in an amount of 6 g / h. The homogenizer was a simple apparatus with a stirrer operating at room temperature, and the residence time of the mixture in the apparatus was 10 minutes. After the homogenizer, the resulting solution was pumped into the distillation column according to claim III. An irregular packing was used as the mass transfer device of the column, which yielded 7 and 13 theoretical plates, respectively, in the distant and strengthening parts of the column. The column was operated under atmospheric pressure and with a reflux number of 1. The distillate taken from the column was purified propylene oxide containing 33 ppm acetaldehyde, 35 ppm propanal, 80 ppm acetone, 40 ppm methyl acetate, and 2.50% wt. methanol. The methyl formate content was beyond the definition.

Now, from a mixture with the obtained qualitative and quantitative composition of impurities, propylene oxide of the required quality can be isolated by extractive distillation with water.

All analyzes were performed by gas chromatography. Since formaldehyde cannot be detected on a flame ionization detector, its content in propylene oxide was monitored spectrophotometrically using chromotropic acid. The analysis showed the absence of formaldehyde in the obtained propylene oxide. In addition, as part of the experiment, samples were taken from a homogenizer to control the content of propylene glycol derivatives. The concentration of 1-methoxy-2-propanol in the solution did not exceed 0.4 wt.%, And its isomer 2-methoxy-1-propanol and propylene glycol were not observed in the samples, which indicates the absence of significant losses of propylene oxide due to the reactions taking place with the disclosure oxirane ring.

Claims (11)

1. The method of purification of propylene oxide obtained by the technology of propylene epoxidation with hydrogen peroxide under the action of a titanium silicate catalyst using methanol as a solvent (HPPO technology) from carbonyl impurities (aldehydes and ketones) of compounds of the general formula R ₁ COR ₂ , where R ₁ is a C _1-3 hydrocarbon radical, and R ₂ is a hydrogen atom or a methyl radical; and carboxylic (carboxylic acids and their esters) compounds of the general formula R ₁ COOR ₂ , where R ₁ is a C _1-3 hydrocarbon radical, and R ₂ is a hydrogen atom or a methyl radical, consisting of the reaction of carbonyl and carboxyl compounds with formaldehyde and alkali, subsequent dissolution of the products of their interaction with water and distillation of the purified propylene oxide from the resulting mixture, and characterized in that the products formed during chemical cleaning can be disposed of without the use of additional special processing technologies. 2. The method of purification of propylene oxide according to claim 1, characterized in that the chemical cleaning process is carried out in a cascade of three devices of the following functional purpose: - a reactor where crude propylene oxide, formaldehyde and alkali are mixed at the same time and reactions proceed along carbonyl and carboxyl groups; - a homogenizer, where the reaction mixture is mixed with water and homogenized due to the dissolution of the formed solid reaction products; - distillation columns in which propylene oxide purified from carbonyl and carboxyl compounds is isolated.

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