JP3967540B2 - Chlorhydrin production method and apparatus - Google Patents

Description

【００９４】
【表２】

【００９５】
【表３】

【図面の簡単な説明】
【図１】本発明方法に使用する代表的な装置の態様を示す概念図
【図２】本発明方法に使用する他の代表的な装置の態様を示す概念図
【図３】実施例及び比較例における、クロルヒドリン濃度とクロルヒドリン選択率の関係を示すグラフ
【符号の説明】
１ 管型反応器
２ 水供給口
３ 取出口
１２、２２、３２ 塩素供給口
１３、２３、３３ 塩素混合用の静止型混合器
１４、２４、３４ 塩素溶解のための流路
１５、２５、３５ オレフィン供給口
１６、２６、３６ オレフィン混合用の静止型混合器
１７、２７、３７ 反応のための流路
４１ 制御バルブ
４２ アルカリ供給口
４３ アルカリ混合用の静止型混合器
４４ 演算部
４５ ｐＨ検出部[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a novel method and apparatus for producing chlorohydrin. Specifically, the present invention provides a method and an apparatus for producing chlorohydrin with high selectivity using chlorine and olefin as raw materials in an aqueous solvent.
[0002]
[Prior art]
Chlorhydrins such as ethylene chlorohydrin, propylene chlorohydrin and propylene dichlorohydrin are important compounds as raw materials for producing epoxy compounds such as ethylene oxide, propylene oxide and epichlorohydrin.
[0003]
The chlorohydrin is generally produced by reacting an olefin and chlorine in water.
[0004]
However, in the above reaction, the chlorine concentration in the reaction system is lowered to prevent side reactions such as the addition of chlorine to the double bond of olefin to produce olefin dichloride and the formation of ethers by successive reactions. Generally, reaction conditions for carrying out the reaction are employed. (MM P. Ferreo et al., Industry Chemibe Beige 19: 113, 1954).
[0005]
Conventionally, the above reaction conditions have been realized by using a so-called reactor called a chlorohydrin tower. That is, a small amount of chlorine is supplied in the downward flow region while supplying a raw material olefin from the lower part of the U-tube reactor that communicates with the upper part, and circulating a large amount of water with the gas lift caused by the bubbles as the main driving force. A method for producing chlorohydrin while supplying chlorine and chlorohydrin at low levels by supplying them one by one is widely practiced. (Published by Nikkan Kogyo Shimbun; Nikkan Kogyo Kogyo Chosen 14 Propylene-based petrochemicals 106-110 pages, etc.).
[0006]
In addition, the flow path has a chlorine gas supply port and an olefin supply port in order, each comprising a tubular reactor and a gas-liquid separator each provided with a static mixer at a downstream position of the supply port, The rear end opening of the tubular reactor is connected to a gas-liquid separator, and the reaction liquid separated by the gas-liquid separator is circulated by supplying it to the front end opening of the tubular reactor via a circulation pump. There has also been proposed a method of obtaining a chlorohydrin aqueous solution by taking out a part of the liquid phase of the gas-liquid separator while replenishing water using a reactor in which a system is formed. (Publication of the People's Republic of China No. 1232011).
[0007]
Among the methods described above, the method using a chlorohydrin column is a method that has been widely practiced industrially from the advantage of simple structure. However, in order to suppress the production of by-product olefin dichlorides, it is necessary to use a large amount of water and thereby circulate a large amount of the reaction solution. However, the volumetric efficiency of the apparatus is small. In addition, there was still room for improvement in the selectivity of the target product, chlorohydrin.
[0008]
On the other hand, the method of forming a circulation system using a tubular reactor is high in volumetric efficiency of the reactor, but the chlorohydrin selectivity of the target product is not always satisfactory, as in the method of using the chlorohydrin tower. It was.
[0009]
[Problems to be solved by the invention]
Accordingly, an object of the present invention is to provide a method and apparatus for industrially advantageously producing chlorohydrin by increasing the selectivity of chlorohydrin in a method for producing chlorohydrin by reacting chlorine and olefin in water. is there.
[0010]
[Means for Solving the Problems]
As a result of repeated research to achieve the above object, the present inventors have made a chlorine-dissolved aqueous solution flow in the flow path of the tubular reactor, and the olefin is introduced into the flow of the chlorine aqueous solution by the static mixer in the flow path. Perform the mixing operation at least once in series, take out the resulting reaction solution without circulating it, and recover the chlorohydrin aqueous solution to obtain a reaction solution with a high chlorohydrin concentration. It has been found that chlorohydrin can be produced with a higher selectivity than the technology to be used, and the present invention has been completed.
[0011]
That is, the present invention performs at least one operation of circulating a chlorine-dissolved aqueous solution in a flow path of a tubular reactor, supplying olefin gas to the chlorine-dissolved aqueous solution and mixing in a static mixer in the flow path. Further, the present invention provides a method for producing chlorohydrin, characterized in that the obtained chlorohydrin aqueous solution is taken out without being circulated.
[0012]
Further, according to the present invention, as a suitable apparatus for carrying out the above method, a water supply port is provided at the front end of the tubular reactor, and the tubular reactor supplies a mixed gas to the flow path. One or more units each having at least two static mixers having gas supply ports for supplying the chlorine gas to the gas supply ports of the static mixer located upstream of the units, The olefin gas is supplied to each gas supply port of the stationary mixer, and there is an outlet for collecting the chlorohydrin aqueous solution at the rear end of the tubular reactor. And does not have a circulation path for the chlorohydrin aqueous solution recovered from the outlet. An apparatus for producing chlorohydrin is provided.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
In the present invention, the reaction between chlorine and olefin in an aqueous medium is performed using a tubular reactor. That is, in the method of the present invention, the olefin gas is sequentially supplied to the flow path of the chlorine-dissolved aqueous solution once or several times, while preventing the phenomenon that the liquid after mixing the olefin gas is mixed with the previous liquid, The concentration of chlorohydrin, which is a product in the flow path, is increased stepwise and the resulting reaction solution is taken out without being circulated, and it is essential to use a tubular reactor.
[0014]
Therefore, the tubular reactor is not particularly limited as long as it constitutes a tubular flow path having no circulation flow path.
[0015]
In the present invention, the mixer provided for mixing the olefin gas or, if necessary, the chlorine gas into the aqueous solution flowing through the flow path in the tubular reactor, uses a static mixer. However, it is important to promote rapid dissolution of these gases in an aqueous solution and to obtain a desired product with high selectivity.
[0016]
As the static mixer, a known commercially available one can be used without any limitation. Specifically, ejector, plate-shaped or cup-shaped collision plate type static mixer, and Kenics type, Sulzer type, Etoflo type, Tray Hi-mixer type, Bran & Lubbe type, N-form type, Komax type , Lightnin type, Ross ISG type, Prematechnik PMR type static mixer, etc., disperse chlorine gas or olefin gas as fine bubbles in aqueous solution to accelerate gas dissolution in downstream piping Therefore, those having good gas-liquid dispersion performance are preferable. Examples of such a mixer include an ejector, a plate-shaped or cup-shaped collision plate-type static mixer, a Kenics type, a Sulzer type, and the like.
[0017]
Further, as the static mixer, it is preferable to select a fluid flow state after mixing that tends to be a bubble flow, such as an ejector, a plate-shaped or cup-shaped collision plate-type static mixer, a Sulzer type, etc. A static mixer is particularly preferred.
[0018]
In order to lower the supply pressure of chlorine and olefin, those having a small differential pressure between the inlet and the outlet are preferable.
[0019]
In the present invention, the preparation method of the aqueous solution of chlorine dissolved in the flow path of the tubular reactor is not particularly limited as long as it is adjusted to a concentration necessary for the reaction with olefin. For example, a dissolution tank may be provided before being supplied to the tubular reactor, and chlorine may be blown into the water in the tank. However, industrially, water is supplied to the tubular reactor. At the same time, a method of supplying chlorine and mixing with a static mixer is preferable.
[0020]
In addition, while the prepared chlorine-dissolved aqueous solution is circulated in the tubular reactor, the chlorine concentration decreases due to the reaction with the supplied olefin, but such chlorine is in the middle of the flow path of the tubular reactor. It is possible to replenish and adjust the chlorine concentration in the chlorine-dissolved aqueous solution. Also in this case, it is preferable to supply a chlorine gas and then mix by providing a static mixer because chlorine can be efficiently dissolved in the chlorine-dissolved aqueous solution.
[0021]
In the present invention, the chlorine gas may be gaseous purified chlorine once liquefied and vaporized, but it is economical to use unpurified gaseous chlorine having a purity of about 99% containing oxygen and moisture generated by electrolysis. It is preferable.
[0022]
It is sufficient that the supply pressure of the chlorine gas overcomes the pressure of the liquid flowing in the flow path and has a pressure sufficient to supply the chlorine gas. Usually, it is in the range of 1K Pascal gauge to 700K Pascal gauge.
[0023]
The supply amount of chlorine gas is not particularly limited as long as it is less than the solubility of chlorine determined by pressure and temperature. However, if it is too much, there is a tendency for by-products to increase. However, it tends to induce side reactions as well as an increase in the size of the reactor.
[0024]
Accordingly, it is usually preferable to supply chlorine gas so that the chlorine concentration after dissolution is in the range of 500 to 20000 ppmw, particularly in the range of 4000 to 15000 ppmw.
[0025]
Chlorine gas is supplied upstream of the static mixer except when the static mixer is an ejector. However, when the static mixer is an ejector, the negative gas generated when water passes through the ejector. In order to supply chlorine gas under pressure, it is necessary to provide a supply port inside the ejector. The same applies to the case where an olefin gas described later is supplied to the gas supply port of the static mixer.
[0026]
In the present invention, the most important requirement is that the chlorhydrin aqueous solution obtained by performing at least one operation of supplying an olefin gas to the chlorine-dissolved aqueous solution and mixing with a static mixer in the flow path of the hydrochloric acid-dissolved aqueous solution. It is to take out without circulating.
[0027]
That is, in the conventional method for producing chlorohydrin, when a chlorohydrin aqueous solution having a certain concentration is to be obtained, the olefin is supplied while circulating the chlorine-dissolved aqueous solution between the reactor and the circulation tank, and the desired concentration is obtained. The method of taking out the reaction liquid which became became from the circulation tank was adopted.
[0028]
That is, in order to reduce the chlorine concentration after dissolution for the purpose of preventing the formation of by-products caused by the addition of chlorine to the double bond, the reaction solution is circulated and used to dissolve chlorine before reacting with olefins. A method of keeping the amount low was adopted. For example, even in the case of the latter technique having a relatively high chlorine concentration, only a maximum of 4000 ppm of chlorine is dissolved.
[0029]
Therefore, a chlorine-dissolved aqueous solution containing chlorohydrin at a concentration close to the extraction concentration is always present in the reaction system, increasing the probability of side reactions between chlorohydrin and chlorine, and further generating intermediates and chlorohydrin. The selectivity of chlorohydrin was reduced by increasing the probability of formation of ethers by reaction with chlorohydrin.
[0030]
On the other hand, the method of the present invention continuously increases the concentration of chlorohydrin, which is a product in the flow path, while preventing the phenomenon that the liquid after mixing the olefin gas is mixed with the previous liquid. It is possible to significantly reduce the probability of side reaction between chlorohydrin and chlorine by taking out the reaction solution that is not circulated, and further, the reaction between the intermediate in the production of chlorohydrin and the produced chlorohydrin occurs. Since the probability can be reduced, chlorohydrin can be obtained with high selectivity.
[0031]
Incidentally, according to the method of the present invention, when obtaining an aqueous chlorohydrin solution having a concentration of 1% by weight, the selectivity can be increased by 1% or more as compared with the conventional method by circulation. It can be said that it is a very advantageous method in the industrial production of.
[0032]
In the method of the present invention, the effect of the present invention is particularly remarkable as the concentration of the target chlorohydrin is higher than that of the conventional technique using the circulation system. Usually, when a chlorohydrin aqueous solution having a target chlorohydrin concentration in the range of 0.4 to 7% by weight, particularly 0.6 to 5% by weight is obtained, the effect is remarkable.
[0033]
As described above, when the concentration of the target chlorohydrin is high, a method of supplying the olefin gas a plurality of times and supplying the chlorine gas as necessary in the flow path of the chlorine-dissolved aqueous solution is preferable. Then, a chlorohydrin can be produced with high selectivity by taking out a chlorohydrin aqueous solution having a target concentration from the rear end of the tubular reactor without circulating it.
[0034]
In the present invention, the olefin used is not particularly limited, but C ₂ ~ C _Four Of these olefins are generally used. Of these, ethylene, propylene, and allyl chloride are particularly preferable.
[0035]
Moreover, the purity may be easily available industrially, and generally a purity of about 95% to 96% is used.
[0036]
As the supply pressure of the olefin gas, it is sufficient if the pressure is sufficient to overcome the pressure of the fluid flowing through the tubular reactor and supply the olefin gas. Usually, it is in the range of 1K Pascal gauge to 700K Pascal gauge.
[0037]
Further, if the amount of olefin gas supplied is too large, the amount of unreacted substances tends to increase, and if it is too small, the amount of by-products tends to increase. A range of 9 to 1.2, in particular a range of 1 to 1.1, is recommended.
[0038]
The supply position of the olefin gas is preferably a position where the supplied chlorine gas is sufficiently dissolved when supplying chlorine gas in the flow path. Such a position may be determined in advance by experiments, but it is usually preferable to ensure a residence time of 4 seconds or more after mixing chlorine in order to ensure complete dissolution of chlorine.
[0039]
Moreover, when supplying chlorine gas after mixing olefin gas, or when taking out chlorohydrin aqueous solution, in order to make the reaction rate of the dissolved chlorine and olefin perfect, it is preferable to ensure the residence time of 10 seconds or more. .
[0040]
Thus, the olefin gas is mixed with the chlorine-dissolved aqueous solution by the static mixer, and is taken out as a chlorohydrin aqueous solution with high selectivity from the rear end portion of the tubular reactor through a residence time required for the reaction.
[0041]
The olefin gas and chlorine gas are preferably supplied without diluting them, but if necessary, they may be diluted with an inert gas such as propane, ethane, nitrogen or argon. Is possible.
[0042]
In the present invention, the most preferable embodiment is that water is supplied to a tubular reactor, and chlorine gas is supplied to prepare a chlorine-dissolved aqueous solution in the flow path, and then olefin gas is supplied and mixed to produce chlorohydrin. By repeating the operation and the operation of supplying and mixing chlorine gas and capturing the chlorine decreased by the reaction, the concentration of chlorohydrin is sequentially increased in the flow path, from the rear end opening of the tubular reactor. , An embodiment comprising taking out a high concentration of chlorohydrin.
[0043]
In the present invention, the tubular reactor may be configured by providing a plurality of sets of the above-described chlorine gas and olefin gas supply and mixing points in one tube reactor, or supplying chlorine gas and olefin gas. A plurality of tubular reactors having a single mixing point may be connected in series.
[0044]
In the case where a plurality of tubular reactors are connected in series, there is no problem even if a pump is provided at the connecting portion to restore the liquid supply pressure.
[0045]
In addition, the horizontal, inclined, and vertical directions can be adopted for installing the tubular reactor, but if installed horizontally or inclined, laminar flow or wave flow tends to occur, resulting in poor gas absorption efficiency and static mixing. Since the length of the gas absorption pipe installed downstream of the vessel tends to be long, the flow state of the fluid consisting of bubbles of chlorine or olefin finely dispersed in water in the static mixer is bubbly flow, plug flow, or Any slag flow, particularly bubbly flow, is preferred, and it is possible to install the baffle flow in the vertical direction as much as possible, so that the range of bubbling flow is wide, the overall length of the device can be shortened, and the scale It is particularly preferable because it is easy to increase.
[0046]
In the present invention, if the reaction temperature is too high, the selectivity of the target chlorohydrin tends to be low. Therefore, the temperature of the chlorohydrin aqueous solution is preferably adjusted to 80 ° C. or lower. Such an adjustment method is not particularly limited, but a method of adjusting the temperature of water or a chlorine-dissolved aqueous solution supplied to the tubular reactor is preferable. That is, the temperature of the water or the chlorine-dissolved aqueous solution supplied to the tubular reactor is preferably 70 ° C. or less, particularly preferably in the range of 0 to 60 ° C. in consideration of the heat of reaction for chlorohydrin formation.
[0047]
In the present invention, the supply pressure of water or a chlorine-dissolved aqueous solution supplied to the tubular reactor is not particularly limited, but in order to guarantee the liquid flow, the pressure recovery due to the difference in height and the static mixing described later. It is sufficient that the total pressure loss of the vessel is equal to or higher than the atmospheric pressure, and it is usually preferably in the range of 1 K Pascal gauge to 500 K Pascal gauge.
[0048]
Further, when the static mixer is an ejector, the supply water pressure is used as the drive force of the ejector, and the pressure is preferably equal to or higher than the pressure necessary for driving the ejector to guarantee complete gas absorption.
[0049]
In the present invention, the flow rate of the water or chlorine-dissolved aqueous solution supplied to the tubular reactor sufficiently draws out the gas mixing performance by the static mixer, and the flow state of the fluid after gas mixing is a bubble flow, a plug flow, Or it is preferable to adjust so that it may become either a slag flow, especially a bubble flow.
[0050]
The preferred flow rate is not limited in general, but usually the flow rate of the liquid introduced into the static mixer is in the range of 0.3 to 4 m / sec, preferably 0.7 to 3 m / sec.
[0051]
Such flow rate adjustment can be generally performed by the flow rate of water or a chlorine-dissolved aqueous solution supplied to the tubular reactor and the diameter of the pipe (Chemical Engineering Handbook, 5th edition, pages 272 to 276).
[0052]
In the present invention, an embodiment in which an alkali is added to the chlorine-dissolved aqueous solution flowing through the flow path of the tubular reactor in a range where the pH does not become 7 or more is a preferable embodiment in order to achieve higher selectivity of the resulting chlorohydrin.
[0053]
The reason why the selectivity of chlorohydrin is further improved by the addition of the alkali is estimated as follows.
[0054]
That is, when chlorine is dissolved in water, a reversible reaction occurs in which chlorine reacts with water to generate hypochlorous acid and hydrochloric acid. In the method of the present invention, since alkali is supplied to chlorine dissolved in water, the generated hydrochloric acid has a magnitude of its dissociation multiplier (hypochlorous acid 4 × 10 4 ^-8 , Hydrochloric acid 1 × 10 ^-1 ) Is selectively neutralized to form a salt. As a result, the reversible reaction promotes the reaction of generating hypochlorous acid, and an aqueous solution having a very low chlorine concentration and a high hypochlorous acid concentration can be obtained. In the present invention, since the olefin is supplied to such a solution stream, it is possible to suppress the production of by-products caused by the addition of chlorine to the double bond, and the chlorohydrin selectivity, which is the target product, can be reduced. It seems to be even higher.
[0055]
The type of alkali supplied for pH adjustment is not particularly limited, but alkali metal hydroxides such as lithium hydroxide, sodium hydroxide, and potassium hydroxide, magnesium hydroxide, calcium hydroxide, barium hydroxide, etc. Alkaline earth metal hydroxides, alkali metal carbonates such as sodium carbonate, sodium hydrogen carbonate, and potassium carbonate, and alkaline earth metal carbonates such as magnesium carbonate and calcium carbonate are preferred. Calcium oxide is particularly preferred.
[0056]
In addition, the amount of alkali added is preferably within the range where the pH of the chlorine-dissolved aqueous solution does not exceed 7, as described above, and in particular, the amount of alkali supplied can be controlled to be in the range of pH 3-6. This is suitable because a solution having a low chlorine concentration and a high hypochlorous acid concentration can be obtained.
[0057]
That is, when the pH is 7 or more, hypochlorous acid may be neutralized, or the supplied alkali may remain and come into contact with the olefin to cause a side reaction that generates olefin oxide, olefin diol, ether compound, or the like. This is not preferable.
[0058]
The method for supplying the alkali is not particularly limited, but it is usually preferable to supply it continuously as a 1 to 40% by weight aqueous solution or slurry. At that time, it is preferable to control the pH by using a pH control device comprising a pH detection part of the fluid in the tubular reactor and a valve for adjusting the alkali flow rate based on the signal.
[0059]
Moreover, it is preferable to add the alkali using a static mixer similar to the gas.
[0060]
The solution having a low chlorine concentration and a high hypochlorous acid concentration thus obtained is mixed with olefin gas in a static mixer for mixing olefin gas, and chlorohydrin can be efficiently produced.
[0061]
Further, since chlorine is dissolved in water in a very short time by adding alkali, it is possible to shorten a suitable residence time after mixing the chlorine gas. Usually, such a residence time of 2 seconds or more is sufficient. It becomes.
[0062]
The method of the present invention is advantageous particularly when producing a chlorohydrin aqueous solution having a relatively high concentration from a chlorine-dissolved aqueous solution having a chlorohydrin concentration of zero or extremely low, but the concentration of the chlorohydrin aqueous solution obtained by the method of the present invention is further increased. In order to raise it, supplying the chlorohydrin aqueous solution obtained by the method of the present invention to a chlorohydrin tower conventionally used industrially can be carried out without any limitation.
[0063]
The aqueous chlorohydrin solution obtained by the method of the present invention can be used as it is as a raw material for producing propylene oxide.
[0064]
The apparatus for carrying out the method of the present invention is not particularly limited as long as it satisfies the above-described manufacturing requirements, but examples of suitable apparatuses include the following apparatuses.
[0065]
That is, according to the present invention, a static mixer having a water supply port at the front end of the tubular reactor, the gas tube having a gas supply port for supplying a mixed gas to the flow path. At least two units, chlorine gas is supplied to the gas supply port of the static mixer located upstream of the unit, and olefin is supplied to the gas supply port of the static mixer located downstream. There is provided an apparatus for producing chlorohydrin, which is configured to supply gas, and has an outlet for collecting an aqueous chlorohydrin solution at the rear end of the tubular reactor.
[0066]
Below, the typical aspect of the said apparatus is demonstrated according to FIGS.
[0067]
The apparatus shown in FIG. 1 shows an embodiment having three units each including at least two static mixers. That is, the embodiment of the apparatus shown in FIG. 1 has a supply port 2 of water C at the front end of the tubular reactor 1, and includes static mixers 13, 23, 33 located upstream of the units 1-3. Chlorine gas A is supplied to the gas supply ports 12, 22, 32, and olefin gas B is supplied to the gas supply ports 15, 25, 35 of the stationary mixers 16, 26, 36 located on the downstream side, An outlet 3 for recovering the aqueous chlorohydrin solution is provided at the rear end of the tubular reactor.
[0068]
In FIG. 1, water C is supplied into the apparatus from a supply port 2, mixed with chlorine gas supplied from a gas supply port 12 in a static mixer 13, and chlorine is dispersed in water as fine bubbles.
[0069]
Next, the water mixed with the chlorine gas A dissolves in the chlorine gas in the flow path 14 of the tubular reactor, and is completely dissolved before reaching the olefin supply port 15 to prepare a chlorine-dissolved aqueous solution. .
[0070]
Thereafter, the olefin gas B is supplied to the flow path from the olefin supply port 15 and supplied to the chlorine-dissolved aqueous solution passing through the flow path.
[0071]
The supplied olefin gas is mixed with the chlorine-dissolved aqueous solution in the static mixer 16, and the olefin gas is dispersed in the chlorine-dissolved aqueous solution as fine bubbles.
[0072]
In the flow path 17 following the static reactor, the reaction of olefin, chlorine and water proceeds, and the production of chlorohydrin and hydrogen chloride proceeds.
[0073]
The generated chlorine-dissolved aqueous solution containing chlorohydrin can be taken out as it is. However, in the embodiment shown in FIG. 1, there are further two units for performing the above-described operation, whereby a high-concentration chlorohydrin aqueous solution is obtained. It can be taken out from the outlet 3 of the tubular reactor 1.
[0074]
On the other hand, the apparatus shown in FIG. 2 shows an embodiment for adjusting the pH of the chlorine-dissolved aqueous solution by adding alkali in the apparatus shown in FIG.
[0075]
That is, the apparatus of FIG. 2 includes an alkali supply port 42 having a control valve 41 for adding the alkaline aqueous solution E while controlling the pH to the flow channel immediately after the flow channel 14 for preparing the chlorine-dissolved aqueous solution. On the downstream side, a static mixer 43, a pH detection unit 45, and a calculation unit 44 for converting the signals of the pH detection unit 45 into signals for controlling the control valve 41 are provided.
[0076]
The generated chlorine-dissolved aqueous solution containing chlorohydrin can be taken out as it is. However, in the embodiment shown in FIG. 2, the unit shown in FIG. 1 is further provided with two units, thereby further increasing the selectivity of chlorohydrin. The high-concentration chlorohydrin aqueous solution can be taken out from the outlet 3 of the tubular reactor 1 by securing it.
[0077]
In each of the above devices, the number of static mixers provided after the gas or liquid is supplied to the flow path is not particularly limited, and may be one, or two or more may be arranged in series. good.
[0078]
Also, although not shown in the figure, after the olefin is supplied and reacted, if the dissolved chlorine in the chlorine-dissolved aqueous solution remains sufficiently, the olefin supply port and the static mixer are continuously provided without providing the chlorine supply port. It is also possible to provide the channel in the flow path.
[0079]
The material for forming the apparatus of the present invention is not particularly limited as long as no problem such as corrosion occurs except for the nozzle portion of the chlorine supply port. For example, a lining made of a polymer material such as PTFE, a corrosion resistant metal material such as Ti, and the like can be exemplified. Since the nozzle of the chlorine supply port reacts with chlorine when Ti is used, it is preferably a polymer material such as PTFE.
[0080]
【The invention's effect】
As can be understood from the above description, according to the present invention, it is possible to ensure a high selectivity for chlorohydrin and to produce chlorohydrin advantageously industrially.
[0081]
In particular, when obtaining an object having a relatively high chlorohydrin concentration, the effect of exhibiting a higher selectivity for chlorohydrin than that of the prior art is remarkable.
[0082]
Therefore, the industrial value of the present invention is extremely high.
[0083]
【Example】
EXAMPLES Hereinafter, examples will be shown to describe the present invention more specifically, but the present invention is not limited to the following examples.
[0084]
Example 1
An apparatus having one unit comprising two static mixers, that is, a chlorine supply port and a propylene supply port, a Kenics type static mixer for mixing chlorine and propylene, and a front end and a rear end Using a Teflon pipe with an inner diameter of 9.6 mm, a pipe reactor with a distance from the chlorine mixer to the propylene supply port of 6 m and a distance from the propylene mixer to the rear end of the pipe of 10 m did.
[0085]
21 ° C water 0.12m from the front end of the pipe ^Three / Hr at a rate of 0.12 m for chlorine ^Three / Hr at a rate of 0.18 m of propylene ^Three A chlorohydrination reaction was carried out at a rate of / Hr.
[0086]
When the chlorohydrin aqueous solution was taken out and analyzed from the rear end of the pipe, the propylene chlorohydrin concentration was 0.41%, the chlorine conversion was 100%, and the propylene chlorohydrin selectivity was 97.9%.
[0087]
Further, when the chlorine concentration was measured by sampling at a position immediately before the propylene supply port, it was 3145 ppmw, and the supplied chlorine was completely dissolved. (See Tables 1 to 3 and FIG. 3).
[0088]
Examples 2-4
A chlorohydrination reaction was carried out using the apparatus shown in Table 1 and the reaction conditions shown in Table 2. The results are shown in Table 3 and FIG.
[0089]
Example 5
An apparatus having three units each having two static mixers shown in Table 1, that is, the apparatus shown in FIG. 1, is used and 1.00 m from each chlorine supply port. ^Three Chlorine is supplied at a speed of / Hr, and 1.10 m from each propylene supply port ^Three Propylene was supplied at a rate of / Hr, and a chlorohydrination reaction was performed using the reaction conditions shown in Table 2. The results are shown in Table 3 and FIG.
[0090]
Examples 6-8
17% lime milk is used as the alkali in the apparatus with one unit comprising two static mixers in Table 1 and the apparatus for adjusting the pH of the chlorine-dissolved aqueous solution by adding alkali. Then, the pH was controlled by supplying from an alkali supply port, and a chlorohydrin reaction was performed using the reaction conditions shown in Table 2. The results are shown in Table 3 and FIG.
[0091]
Examples 9-10
An apparatus that adjusts pH to one unit with an apparatus that adjusts the pH of a chlorine-dissolved aqueous solution by adding an alkali to an apparatus that has one unit comprising two static mixers shown in Table 1. What is not provided A device in which two units are arranged in series, that is, the device shown in FIG. ^Three / Hr is supplied at a rate of chlorine, pH is controlled by supplying 17% lime milk as an alkali from an alkali supply port, and 1.10 m from each propylene supply port. ^Three Propylene was supplied at a rate of / Hr, and a chlorohydrination reaction was performed using the reaction conditions shown in Table 2. The results are shown in Table 3 and FIG.
[0092]
Comparative Examples 1-2
A gas-liquid separator is connected to the rear end of the device, and the liquid phase is circulated to the front end of the device using a pump, with some being able to withdraw the chlorohydrin aqueous solution and the rest being combined with the feed water. This was performed under the conditions shown in Tables 1 and 2 except that the chlorohydrin aqueous solution was withdrawn as much as the feed water flow rate. The results are shown in Table 3 and FIG.
[0093]
[Table 1]

[0094]
[Table 2]

[0095]
[Table 3]

[Brief description of the drawings]
FIG. 1 is a conceptual diagram showing an embodiment of a typical apparatus used in the method of the present invention.
FIG. 2 is a conceptual diagram showing an embodiment of another typical apparatus used in the method of the present invention.
FIG. 3 is a graph showing the relationship between chlorohydrin concentration and chlorohydrin selectivity in Examples and Comparative Examples.
[Explanation of symbols]
1 Tube reactor
2 Water supply port
3 Exit
12, 22, 32 Chlorine supply port
13, 23, 33 Static mixer for chlorine mixing
14, 24, 34 Channels for dissolving chlorine
15, 25, 35 Olefin supply port
16, 26, 36 Static mixer for mixing olefins
17, 27, 37 Flow path for reaction
41 Control valve
42 Alkali supply port
43 Static mixer for alkali mixing
44 Calculation unit
45 pH detector

Claims (7)

  An aqueous solution of chlorohydrin obtained by circulating an aqueous solution of chlorine in a flow path of a tubular reactor, supplying an olefin gas to the aqueous solution of chlorine dissolved in the flow path, and mixing in a static mixer at least once. A process for producing chlorohydrin, characterized in that the chlorohydrin is taken out without circulating.   The method for producing chlorohydrin according to claim 1, wherein the chlorine concentration in the chlorine-dissolved aqueous solution is adjusted by an operation of supplying chlorine gas to the flow path and mixing with a static mixer.   The method for producing chlorohydrin according to claim 1, wherein an alkali is added within a range in which the pH of the aqueous solution of chlorine dissolved in the flow path does not become 7 or more.   The method for producing chlorohydrin according to any one of claims 1 to 3, wherein the liquid in the flow channel after mixing the gas forms a bubble flow, a plug flow or a slag flow. A unit having a water supply port at the front end of a tubular reactor, and the tubular reactor is provided with at least two stationary mixers having gas supply ports for supplying a gas mixture to the flow path The chlorine gas is supplied to the gas supply port of the static mixer located upstream of the unit, and the olefin gas is supplied to the gas supply port of the static mixer located downstream. and, it has a outlet for recovering chlorohydrin aqueous solution at the rear end of the tubular reactor, and apparatus for manufacturing a chlorohydrin, characterized in that no circulation path of the chlorohydrin aqueous solution recovered from the removal port.   6. The apparatus for producing chlorohydrin according to claim 5, wherein an alkali supply port is provided in front of the mixed gas supply port for supplying the olefin gas.   The apparatus for producing chlorohydrin according to claim 5 or 6, comprising two or more units.

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