JPWO2008123530A1 - Method for producing solid acid catalyst comprising sulfonic acid group-containing carbonaceous material and use thereof - Google Patents

Abstract

Provided is a solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material having high reaction activity, which is useful for various acid-catalyzed reactions such as olefin hydration. That is, it uses a two-stage process in which cellulose, phenolic resin, etc., or organic substances such as woods and herbs are carbonized by heat treatment and then sulfonated, and the carbonization conditions are controlled and the sulfone in the sulfonated process. By controlling the conversion time, a solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material having high reaction activity for various acid catalyst reactions such as olefin hydration is provided.

Description

  The present invention relates to a method for producing a solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material obtained by subjecting an organic substance to carbonization treatment by heating and then sulfonation treatment, and use thereof.

Sulfuric acid is an important catalyst widely used in various chemical reactions. However, it generally requires a large amount of sulfuric acid, there is a problem of corrosion of the equipment, separation of sulfuric acid from the product after the reaction, recovery, purification, reuse process, sulfuric acid remaining in the product There are many problems such as the need for neutralization and the removal and disposal of the salt produced thereby, and wastewater treatment, and the fact that these steps require a lot of energy. The solid acid catalyst can be used as a substitute for a mineral acid catalyst such as sulfuric acid, so that there is no corrosion of the apparatus, and various steps after the above reaction are omitted or greatly simplified. Various solid acids have been developed. Typical solid acids include inorganic compounds such as silica / alumina, crystalline aluminosilicate (zeolite), and heteropolyacid.
On the other hand, olefin hydration is an industrially important reaction for the production of alcohols and ketones, and an acid catalyst is used for this reaction. Isopropyl alcohol or 2-butanol is produced by various methods utilizing the hydration of propylene or n-butene (Non-patent Documents 1 and 2). Many processes in the hydration reaction process use sulfuric acid as a catalyst, but there are also problems with many by-products in addition to the above problems, and some solid acid catalysts are also used to solve these problems. Has been. In this case, the inorganic solid acid catalyst described above is generally not used because its activity decreases in the presence of water, and a catalyst having phosphoric acid supported on an inorganic carrier is used. There is a problem of desorption from the carrier. Further, a strong acid ion exchange resin which is a polymer having a sulfonic acid group on a crosslinked polystyrene skeleton is also used, but the range of use is limited due to problems such as low heat resistance and high cost. A super strong solid acid “Nafion” (registered trademark of DuPont) based on a fluorine-substituted olefin polymer having heat resistance has been developed, but is too expensive to be used for industrial applications.
Under such circumstances, sulfonated carbonaceous materials obtained by subjecting organic substances such as aromatic compounds, petroleum heavy oils and sugars to carbonization and sulfonation by heating have been developed (Patent Document 1), and various solid acid catalysts have been developed. Recently, it has attracted attention because of its high activity in chemical reactions, excellent heat resistance, and low cost. Fatty acid esterification, ester hydrolysis, alkylation, olefin hydration Etc. have been tried (Non-patent document 3, Non-patent document 4, Non-patent document 5, Patent document 2). However, for example, for olefin hydration, only 2,3-dimethyl-2-butanol has been reported in a low yield by hydrating 2,3-dimethyl-2-butene. From the viewpoint of practicality, development of a solid acid having higher catalytic activity is desired.
By the way, it is well known that 2-butanol can be obtained by hydrating normal butene, and methyl ethyl ketone can be obtained by dehydrogenating this 2-butanol. Methyl ethyl ketone is an extremely important industrial chemical as a solvent for paints, inks, adhesives and the like, and as a cleaning agent for various uses. Currently, 2-butanol is produced by a method using sulfuric acid as a catalyst or a method using a heteropolyacid catalyst. However, the sulfuric acid method has the problem of waste sulfuric acid and the problem of corrosion of the equipment, while the heteropoly acid method is technically difficult such as using a supercritical state, and an inexpensive and efficient production technique of 2-butanol is not available. It is desired.
In addition, a method for producing acetone and phenol by decomposing cumene hydroperoxide is an extremely important chemical process industrially. This reaction proceeds under an acid catalyst, and dilute sulfuric acid is currently used (Non-Patent Document 6). The sulfuric acid aqueous solution is highly corrosive and has a problem of waste sulfuric acid. In addition, there is a problem that a large amount of energy is required to separate the product from the reaction solution, and an alternative solid acid catalyst is also desired.
It has been clarified that the sulfonation method for producing the sulfonated carbonaceous material can be obtained by sulfonating an organic carbonized product or directly sulfating the organic substance in concentrated sulfuric acid or fuming sulfuric acid. . However, the optimum sulfonation conditions for the production of solid acid catalysts are not clarified. Furthermore, it has not been clarified at all whether a one-step method for directly sulfonating an organic substance is good or a two-step method for sulfonation after carbonizing an organic substance. There is known a method for obtaining a solid acid catalyst by heat-treating polycyclic aromatic hydrocarbons in concentrated sulfuric acid or fuming sulfuric acid to sulfonate, but there is no mention of a two-stage system.
As described above, in the production of the sulfonated carbonaceous material, the optimization of the sulfonation process for the purpose of producing a solid acid catalyst has not yet been made.
Catalyst, 18 (6), 180 (1976) Journal of Petroleum Society, 34 (3), 201 (1991) Domen et al., “Synthesis Conditions and Catalysis of Carbon-Based Solid Strong Acids”, The 85th Annual Meeting of the Chemical Society of Japan (2005), 2B5-43 Hara, M .; et al. Nature, 438 (10), 178, November (2005). Hara et al., PETROTECH, 29 (6), 411 (2006) New Petrochemical Process, p239 (1986), Sachishobo Japanese Patent Laid-Open No. 2004-238111 International Publication WO 2005/029508 A1

An object of the present invention is to provide a method for producing a solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material having high reaction activity, which is useful for various acid catalyst reactions such as olefin hydration. Moreover, it is providing the efficient manufacturing method of the compound obtained by the hydration reaction of the olefin using the solid acid catalyst, and the esterification reaction by a fatty acid. It is also intended to provide an inexpensive and efficient method for producing ketones, and further to provide an inexpensive and efficient method for producing phenols.
In view of the problems of the prior art, the present inventors have conducted extensive research, and as a result, in the production process of the solid acid catalyst comprising the sulfonic acid group-containing carbonaceous material, the organic substance is heat treated and carbonized and then sulfonated. The present invention has been found to dramatically improve the reaction activity as a solid acid catalyst by using a two-step process and controlling the carbonization conditions, and further controlling the sulfonation time in the sulfonation process. It came to complete.
That is, the first of the present invention is a method for producing a solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material obtained by carbonizing and sulfonating an organic substance by heating in an inert gas atmosphere. A solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material, wherein the carbonization treatment is performed at a temperature of 300 to 600 ° C. and the sulfonation time is 5 to 150 minutes. It relates to a manufacturing method.
2nd of this invention is related with the manufacturing method of the solid acid catalyst which consists of a sulfonic acid group containing carbonaceous material characterized by the sulfonation temperature being 20-250 degreeC in 1st of this invention.
Furthermore, a third aspect of the present invention relates to a method for producing a solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material according to the first to second aspects of the present invention, wherein concentrated sulfuric acid is used as a sulfonating agent.
Further, a fourth aspect of the present invention relates to a method for producing a sulfonic acid group-containing carbonaceous material according to any one of the first to third aspects of the present invention, wherein cellulose is used as the organic substance.
Furthermore, a fifth aspect of the present invention relates to a method for producing a solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material according to the first to third aspects of the present invention, wherein a phenol resin is used as the organic substance.
Further, a sixth aspect of the present invention is a method for producing a solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material, wherein woods and / or herbs are used as organic substances in the first to third aspects of the present invention. .
Further, a seventh aspect of the present invention is the first to sixth aspects of the present invention, wherein the integrated intensity of the D peak / the integrated intensity of the G peak of the Raman analysis value of the sulfonic acid group-containing carbonaceous material is 0.0 to 0.7 or The present invention relates to a method for producing a solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material, wherein the Raman spectrum peak is not observed.
Further, according to an eighth aspect of the present invention, there is provided production of an olefin hydrated product characterized in that the hydration reaction of olefin is performed using the solid acid catalyst obtained by the method according to any one of the first to seventh aspects of the present invention. Regarding the method.
Furthermore, a ninth aspect of the present invention relates to a method for producing ethers, wherein an olefin etherification reaction is carried out using the solid acid catalyst obtained by the method according to the first to seventh aspects of the present invention.
Further, according to a tenth aspect of the present invention, from the aralkyl hydroperoxide to the phenol, an acid decomposition reaction of aralkyl hydroperoxide is carried out using the solid acid catalyst obtained by the method according to any one of the first to seventh aspects of the present invention. The present invention relates to a method of producing
Furthermore, an eleventh aspect of the present invention relates to a method for producing a phenol according to the tenth aspect of the present invention, wherein the aralkyl hydroperoxide is cumene hydroperoxide and the phenol is phenol.
Furthermore, a twelfth aspect of the present invention is a method for producing an ester, characterized in that an alcohol and a carboxylic acid are esterified using the solid acid catalyst obtained by the method according to any one of the first to seventh aspects of the present invention. About.
Furthermore, the thirteenth aspect of the present invention relates to a method for producing a ketone characterized by carrying out a dehydrogenation reaction of the olefin hydrate product obtained according to the eighth aspect of the present invention.
Furthermore, the fourteenth aspect of the present invention relates to a method for producing a ketone according to the thirteenth aspect of the present invention, wherein the olefin hydration product is 2-butanol and the ketone obtained by the dehydrogenation reaction is methyl ethyl ketone.
Effects of the Invention The solid acid catalyst comprising the sulfonic acid group-containing carbonaceous material of the present invention is a solid acid catalyst for various chemical reactions, especially olefin hydration reaction, etherification reaction, aralkyl hydroperoxide acid decomposition reaction, etc. Since it has a high activity and can be produced easily and inexpensively, it can be supplied in large quantities for industrial use. In addition, when the solid acid catalyst comprising the sulfonic acid group-containing carbonaceous material of the present invention is used to produce olefin hydrates, ethers, etc., or to produce phenols by acid decomposition reaction of aralkyl hydroperoxide. Has high catalyst activity, does not require neutralization and purification of the catalyst after the reaction, can be easily separated and reused, has no problem of equipment corrosion, and is low cost and efficient. The desired product can be manufactured. Moreover, the solid acid catalyst which consists of a sulfonic acid group containing carbonaceous material of this invention can be used also for esterification reaction, hydrolysis reaction of ester, and ethers. Further, when the solid acid catalyst of the present invention is used, the olefin hydrate can be produced at low cost and efficiently as described above. Therefore, by dehydrogenating the obtained olefin hydrate, the ketone can be efficiently and inexpensively produced. Can be manufactured.

ここで式１において、Ｒ_１とＲ_２はアルキル基あるいは水素原子を表し、Ｒ_１とＲ_２の炭素原子数の合計は１以上である。

アラルキルヒドロペルオキシドの酸分解反応を行う方法に関して、クメンヒドロペルオキシドを例に触れる。反応は液相状態で行われる。反応器の形態は固体酸触媒を充填した固定相流通式、あるいは触媒を反応液中に懸濁させた回分式攪拌層型反応器、何れも用いることが出来る。反応温度は５０℃から９０℃、望ましくは６０℃から８０℃である。クメンヒドロペルオキシドの酸分解反応は発熱反応であるので、必要であれば反応熱による温度上昇を緩和するために不活性希釈剤で反応液を希釈することが望ましい。回分式反応器を用いた場合、適切な沸点を有する希釈剤を使用し、その希釈剤を沸騰させ還流させることにより、反応温度を維持し且つ反応熱を除去することが可能である。回分式反応の場合、固体酸触媒として用いる本発明のスルホン酸基含有炭素質材料の使用割合は、仕込んだヒドロペルオキシドの１／１００から１（重量比）である。反応時間は１５分から８時間が望ましい。固定相流通式の場合、反応原料混合液のＬＨＳＶは０．１から１．０（Ｌ−ｆｅｅｄ／Ｌ−触媒／Ｈｒ）が望ましい。
ここでケトンの製造について触れる。本発明のスルホン酸基含有炭素質材料からなる固体酸触媒を用い、前記記載のオレフィンの水和反応（オレフィンと水の反応）により第二アルコールを製造することが出来る。この第二アルコールを脱水素反応することにより対応するケトンを製造することが出来る。例えば、プロピレンの水和反応で得られた２−プロパノールを脱水素することによりアセトンが得られる。また、ノルマルブテンの水和反応で得られた２−ブタノールを脱水素することによりメチルエチルケトンを製造することが出来る。脱水素反応は一般的に知られている方法で行うことが出来る。例えば銅‐亜鉛系触媒を用い、反応温度３００−５００℃、圧力０−１ＭＰａで行うことが出来る。この脱水素反応は吸熱反応であるため化学平衡の面からは高温ほど有利であるが、過度な高温は分解反応を併起したり、触媒の焼結が起こったりして好ましくなく、上記した温度範囲が好ましい。また、脱水素反応であるので低圧ほど反応は有利に進む。
本発明のスルホン酸基含有炭素質材料からなる固体酸触媒を用いて製造されたアルコールは従来の硫酸を用いる方法や，超臨界条件を用いるヘテロポリ酸を用いる方法で製造されたアルコールに比べ、その製造方法が簡便で装置の腐食も無くまた廃棄物の少ない方法であるため安価であり、それを脱水素して製造されるケトンも安価に製造することが出来る。すなわち、安価で環境負荷の少ない経済的に有利な、ノルマルブテンからメチルエチルケトンを製造する方法を提供できるものである。
以下、実施例により本発明を具体的に説明するが、本発明はこれに限定されるものではない。The present invention is described in further detail below.
The solid acid catalyst comprising the sulfonic acid group-containing carbonaceous material of the present invention is obtained by carbonizing and then sulfonating an organic synthetic compound or organic natural compound or a composition thereof as a starting material.
(About raw materials)
Any raw material for producing a solid acid catalyst made of a sulfonic acid group-containing carbonaceous material can be used as long as it is an organic substance that can be carbonized. For example, organic low molecular weight compounds such as aromatic hydrocarbons, heavy oils, petroleum heavy hydrocarbon mixtures such as petroleum pitch and tar, natural organics such as sugars, starch, cellulose, amylose, phenol resins, furan resins, urea Examples thereof include organic polymer compounds such as resins, melamine resins, unsaturated polyester resins, and thermosetting resins such as epoxy resins. Among these organic materials, when cellulose or an organic material containing cellulose is used as a raw material, the heat resistance of a solid acid made of the obtained sulfonic acid group-containing carbonaceous material is excellent, which is particularly preferable. In particular, when woods and / or herbs are used as organic substances containing cellulose, they are extremely inexpensive unlike purified cellulose, and therefore solid acid catalysts made of sulfonic acid group-containing carbonaceous materials are also extremely inexpensive. Can be manufactured. Moreover, when a phenol resin is used as a raw material, the activity of the solid acid catalyst which consists of a sulfonic acid group containing carbonaceous material obtained is excellent, and it is especially preferable.
(Conditions for producing a solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material)
In the production of the solid acid catalyst comprising the sulfonic acid group-containing carbonaceous material of the present invention, the sulfonation treatment is performed after the carbonization treatment. In a method in which carbonization treatment and sulfonation are performed simultaneously, a highly active solid acid catalyst cannot be obtained. In the following, preferred embodiments in the case of carrying out the sulfonation treatment after the carbonization treatment are described.
(Carbonization)
Carbonization is performed by heating in an inert gas atmosphere such as nitrogen or argon. The conditions for the carbonization treatment are appropriately selected depending on the type of raw materials used and the properties of the solid acid catalyst made of the target sulfonic acid group-containing carbonaceous material, whereby an amorphous black solid (carbide) is obtained. The temperature is 300 to 600 ° C, preferably 350 to 550 ° C. When the temperature of the carbonization treatment is less than the lower limit of this range, the activity of the solid acid catalyst comprising the sulfonic acid group-containing carbonaceous material obtained by sulfonation treatment is inferior, or the amount dissolved in water or organic matter Tend to cause problems such as On the other hand, in the case of a temperature exceeding the upper limit of this range, a sufficient amount of sulfonic acid groups cannot be imparted when sulfonating the solid acid, and the resulting solid acid comprising a sulfonic acid group-containing carbonaceous material is obtained. The catalyst activity for various chemical reactions of the catalyst tends to be insufficient.
The heating time for the carbonization treatment is 1 to 100 hours, preferably 2 to 15 hours. If the carbonization time is less than the lower limit of this range, the activity of the solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material obtained by sulfonation is inferior, or dissolved in water or organic matter. It tends to cause problems such as a lot of minutes. On the other hand, the necessary carbonization proceeds sufficiently in the upper limit of the range, and it is not necessary to spend more time.
In the case of using woody or herbaceous materials as raw materials, it is desirable to obtain a uniform particle size by, for example, pulverizing in advance in order to promote uniform carbonization.
(Sulfonation)
The conditions for the sulfonation treatment are appropriately selected depending on the type of raw materials used and the properties of the solid acid catalyst made of the target sulfonic acid group-containing carbonaceous material. The carbide obtained by the carbonization treatment may be nitrogen, argon, etc. By heating in concentrated sulfuric acid or fuming sulfuric acid under an inert gas atmosphere, thereby adding sulfonic acid groups to the carbide skeleton. When fuming sulfuric acid is used, the content of the introduced sulfonic acid group increases, but the activity of the solid acid catalyst comprising the resulting sulfonic acid group-containing carbonaceous material tends to decrease, so concentrated sulfuric acid is used. It is preferable to do. The amount of concentrated sulfuric acid or fuming sulfuric acid to be used is not particularly limited, but is 5 to 100 times (mass ratio), preferably 10 to 80 times the amount of carbide to be sulfonated. If the lower limit of this range is not reached, a sufficient amount of sulfonic acid groups cannot be imparted to the carbide, and the resulting solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material has catalytic activity for various chemical reactions. Tends to be insufficient. On the other hand, if the upper limit of this range is exceeded, excessive concentrated sulfuric acid or fuming sulfuric acid will be used, resulting in an increase in cost including the treatment of used sulfuric acid.
The temperature of the sulfonation treatment is 20 to 250 ° C, preferably 50 to 200 ° C. When the temperature of the sulfonation treatment is less than the lower limit of this range, a sufficient amount of the sulfonic acid group cannot be imparted to the carbide, and various solid acid catalysts comprising the resulting sulfonic acid group-containing carbonaceous material can be obtained. The catalytic activity for the chemical reaction tends to be insufficient. On the other hand, when the temperature exceeds the upper limit of this range, the added sulfonic acid group is decomposed. The time for the sulfonation treatment needs to be 5 minutes to 150 minutes, and more preferably 15 minutes to 90 minutes. When the time for the sulfonation treatment is less than the lower limit of this range, not only cannot a sufficient sulfonic acid group be imparted to the carbide, but control becomes extremely difficult. However, since the catalyst activity per unit sulfonic acid group tends to be higher as the time is shorter, sulfonation for 150 minutes or more is not preferable because sufficient reaction activity cannot be obtained. Further, since the amount of sulfonic acid is almost saturated by 150 minutes, a sulfonation time of 150 minutes or more is not required for the purpose of increasing the sulfonic acid group. It has not been known so far that a solid acid catalyst made of a sulfonic acid group-containing carbonaceous material can be obtained with a short sulfonation treatment of 5 minutes to 150 minutes, and conventionally 5 hours. It has been considered that sulfonation treatment for a long time as described above is desirable (Patent Document 2).
After the carbonization and sulfonation treatment steps, excess sulfuric acid is removed by washing the sulfonated product, preferably with hot water, and further dried to obtain the sulfonic acid group-containing carbonaceous material of the present invention in the form of a black powder. A solid acid catalyst can be obtained. Washing with hot water is conveniently performed under reflux at about 100 ° C., for example, by a Soxhlet extraction method. It is also possible to shorten the washing time by washing at a higher temperature under pressure.
(About acid group content)
The acid group content of the sulfonic acid group-containing carbonaceous material of the present invention is 1 mmol / g or more, preferably 1.5 mmol / g or more. When the acid group content is less than 1 mmol / g, the activity of the resulting solid acid catalyst comprising the sulfonic acid group-containing carbonaceous material as a solid acid catalyst for various chemical reactions tends to be insufficient. In addition, acid group content here is what measures the solid acid which consists of a sulfonic acid group containing carbonaceous material with a back titration method, and is the carboxylic acid produced | generated at the time of carbonization process with the sulfonic acid group produced | generated by sulfonation process. It refers to the content of the group.
(Graphitization degree = Raman spectroscopic analysis)
In general, the degree of carbonization when an organic substance is carbonized by heating is often expressed by the degree of graphitization. As one index indicating the degree of graphitization, the intensity ratio of the D peak to the G peak in Raman spectroscopy is used. Used. That is, it is shown that the graphitization degree progresses as the value of the integrated intensity ratio of D peak / integrated intensity ratio of G peak increases. For example, in a conventional sulfonated carbonaceous material disclosed in Non-Patent Document 5 using aromatic hydrocarbon, heavy oil, glucose or the like as a starting material, measurement of graphitization degree by this Raman spectroscopy or The size of the carbon sheet has been estimated. Even in the solid acid catalyst made of the sulfonic acid group-containing carbonaceous material of the present invention, as the sulfonation time increases, the integrated intensity ratio of D peak / integrated intensity of G peak increases, and this ratio becomes too large. It has been observed that catalytic activity is reduced. A preferable integrated intensity ratio of the D peak / G peak is 0.0 to 0.7. Some raw materials for producing a solid acid catalyst comprising the sulfonic acid group-containing carbonaceous material of the present invention do not provide the Raman spectrum peak. Such a material is also preferably used.
(About X-ray diffraction analysis)
The solid acid catalyst comprising the sulfonic acid group-containing carbonaceous material of the present invention cannot be confirmed from any structure from the X-ray diffraction pattern, and is substantially amorphous. Patent Document 1 describes that a carbonaceous mesophase is formed when carbonizing a pitch or the like of a raw material, which suggests that the obtained sulfonated carbonaceous material has a crystalline structure. Yes. Further, in Patent Document 3, there is a description that it is preferable to detect a peak of the [002] plane in the obtained carbonaceous material into which a sulfonic acid group has been introduced, while saying “amorphous carbon”. , Suggesting that it has a partially crystalline structure. Also in this respect, the sulfonic acid group-containing carbonaceous material of the present invention is different from the sulfonated carbonaceous materials disclosed in these prior arts.
The solid acid catalyst of the present invention may be in the form of powder, or may be molded into a granular shape, a spherical shape, a plate shape, a pellet shape, or the like. When molding into these shapes, molding may be performed by blending an inorganic substance called a binder. This binder is blended for the purpose of improving the moldability, the strength of the molded catalyst, the mechanical properties such as the friction resistance, etc., and alumina, alumina / boria, silica / alumina, etc. are preferably used. .
The solid acid catalyst comprising the sulfonic acid group-containing carbonaceous material of the present invention obtained as described above has an acid strength and an acid amount sufficient for various chemical reactions as a solid acid catalyst. The solid acid catalyst comprising the sulfonic acid group-containing carbonaceous material of the present invention is a catalyst for reactions under various polar conditions such as hydration reaction of olefins, etherification reaction, esterification reaction of alcohol and acid, and hydrolysis of ether. It is particularly useful. That is, since it exhibits excellent activity and resistance in reactions using polar substances such as alcohol and water as reaction substrates, it exhibits excellent characteristics as a solid acid catalyst for these polar reactions. In addition, it exhibits excellent properties as an acid decomposition reaction catalyst for aralkyl hydroperoxide.
Hereinafter, olefin hydration reaction (olefin-water reaction), etherification reaction (olefin-alcohol reaction) and esterification reaction (carboxylic acid) using the solid acid catalyst comprising the sulfonic acid group-containing carbonaceous material of the present invention. And the reaction of alcohol).
(Reaction raw materials)
The olefin used in the present invention is not particularly limited and may be linear, branched, or cyclic. However, the olefin having 2 to 5 carbon atoms, specifically, propylene, 1-butene, 2-butene, and isobutene. Butenes such as The water used for the hydration reaction is not particularly limited, but it is preferable to use ion exchange water or distilled water (including steam condensed water).
The alcohol used in the etherification reaction is not particularly limited, but alcohols having 1 to 4 carbon atoms, specifically methanol, ethanol, and isopropyl alcohol are preferable.
The molar ratio of water or alcohol to olefin is not particularly limited, but if the amount of water or alcohol is too small, side reactions such as dimerization of olefin occur, and if too large, productivity is unfavorable. .
The alcohols used in the esterification reaction according to the present invention can be the same as the above alcohols. Examples of the carboxylic acid include saturated or unsaturated carboxylic acids having 1 to 4 carbon atoms, such as acetic acid, acrylic acid, and methacrylic acid. The molar ratio of the alcohol to the acid is not particularly limited, but is usually 0.1 to 100. An anhydride may be used for the carboxylic acid.
(Reaction conditions)
The reaction conditions of the olefin hydration reaction and etherification reaction using the solid acid catalyst comprising the sulfonic acid group-containing carbonaceous material of the present invention can be appropriately selected. However, if the reaction temperature exceeds 250 ° C., the sulfonic acid group-containing carbonaceous material may be decomposed during the reaction, and therefore, the reaction temperature is preferably 250 ° C. or less. Also, the reaction conditions can be appropriately selected when the esterification reaction of carboxylic acid with alcohols is performed. Further, in each of the above reactions using the solid acid catalyst containing the sulfonic acid group-containing carbonaceous material of the present invention, it is possible to use means for reactive distillation.
The reaction pressure is not particularly limited and can be appropriately selected. However, when the reaction pressure exceeds 20 MPa, problems such as an increase in equipment cost arise.
As the reaction phase, any of a gas phase, a liquid phase, and a gas-liquid mixed phase can be adopted. In the case of an esterification reaction, the reaction is likely to proceed if water generated as the reaction proceeds is appropriately removed from the reaction system.
A solvent can also be used when performing a hydration reaction. The solvent is preferably amphiphilic in order to prevent the reaction solution from separating into an aqueous phase and an oil phase, and for example, ethers, glycol ethers, alcohols, ketones and the like can be used. In the case of the etherification reaction, a solvent can be used in the same manner, but the solvent is unnecessary if phase separation does not occur.
(Reaction process using the solid acid catalyst of the present invention)
Since the hydration reaction of an olefin using a solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material of the present invention is a direct hydration method (one-stage reaction), an indirect hydration method using a sulfuric acid catalyst (sulfate ester) Compared with the two-stage reaction of crystallization and hydrolysis, the process is simple. In addition, the indirect hydration method requires a neutralization purification step for sulfuric acid removal and a concentration step for sulfuric acid reuse, and the process is complicated, but in the method of the present invention, the catalyst is a solid, The catalyst can be easily separated and reused by filtration, centrifugation, etc., and the reaction solution after removing the catalyst contains no acid catalyst component. A purification step is not necessary. After removing the catalyst, it can be appropriately purified by distillation or the like. Reactive distillation is also possible. The olefin etherification reaction of the present invention is generally performed by reactive distillation or a fixed bed method.
The form of the reactor in the case of performing the olefin hydration reaction, etherification reaction or esterification reaction of the present invention is not particularly limited, but may be any of batch type, continuous type and semi-continuous type. Moreover, any shape, such as a tank reactor, a column reactor, and a loop reactor, may be used. The type of contact between the catalyst and the reactant may be any of a suspended phase, a fixed bed, and the like. In particular, a form in which the catalyst is suspended in a tank reactor equipped with stirring equipment or a form in which the catalyst is used as a fixed bed and the reactants are continuously circulated is preferably employed.
In any case of the hydration reaction and the etherification reaction or the esterification reaction, the use of the solid acid catalyst comprising the sulfonic acid group-containing carbonaceous material of the present invention makes it possible to operate at a high temperature due to its high heat resistance. As a result, the reaction rate is improved, and the reactor can be downsized. Moreover, the catalyst replacement frequency is also reduced due to the heat resistance of the catalyst.
Next, the acid decomposition reaction of aralkyl hydroperoxide using the solid acid catalyst comprising the sulfonic acid group-containing carbonaceous material of the present invention will be described. The aralkyl hydroperoxide used here is one in which a secondary or tertiary carbon atom in the side chain of an alkyl-substituted aromatic hydrocarbon compound is substituted with a hydroperoxy group, and has a structure represented by the following formula 1. . When this is decomposed in the presence of an acid catalyst, the corresponding phenols and ketones or aldehydes are produced. From cumene hydroperoxide, phenol and acetone are produced as represented by the following formula 2.

Here, in Formula 1, R ₁ and R ₂ represent an alkyl group or a hydrogen atom, and the total number of carbon atoms of R ₁ and R ₂ is 1 or more.

Cumene hydroperoxide is mentioned as an example for a method for carrying out an acid decomposition reaction of aralkyl hydroperoxide. The reaction is carried out in a liquid phase state. As the form of the reactor, either a stationary phase flow type filled with a solid acid catalyst or a batch type stirred layer type reactor in which a catalyst is suspended in a reaction solution can be used. The reaction temperature is 50 ° C to 90 ° C, preferably 60 ° C to 80 ° C. Since the acid decomposition reaction of cumene hydroperoxide is an exothermic reaction, it is desirable to dilute the reaction liquid with an inert diluent to reduce the temperature rise due to reaction heat if necessary. When a batch reactor is used, it is possible to maintain the reaction temperature and remove the heat of reaction by using a diluent having an appropriate boiling point and boiling and diluting the diluent. In the case of a batch reaction, the proportion of the sulfonic acid group-containing carbonaceous material of the present invention used as a solid acid catalyst is 1/100 to 1 (weight ratio) of the charged hydroperoxide. The reaction time is preferably 15 minutes to 8 hours. In the case of the stationary phase flow type, the LHSV of the reaction raw material mixture is preferably 0.1 to 1.0 (L-feed / L-catalyst / Hr).
Here we touch on the production of ketones. Using the solid acid catalyst comprising the sulfonic acid group-containing carbonaceous material of the present invention, the second alcohol can be produced by the olefin hydration reaction described above (reaction of olefin and water). The corresponding ketone can be produced by dehydrogenating the secondary alcohol. For example, acetone is obtained by dehydrogenating 2-propanol obtained by the hydration reaction of propylene. Moreover, methyl ethyl ketone can be produced by dehydrogenating 2-butanol obtained by the hydration reaction of normal butene. The dehydrogenation reaction can be performed by a generally known method. For example, a copper-zinc catalyst can be used at a reaction temperature of 300 to 500 ° C. and a pressure of 0 to 1 MPa. Since this dehydrogenation reaction is endothermic, a higher temperature is advantageous from the viewpoint of chemical equilibrium. However, an excessively high temperature is not preferable because it causes a decomposition reaction or sintering of the catalyst. A range is preferred. Moreover, since it is a dehydrogenation reaction, the reaction proceeds more advantageously at a lower pressure.
The alcohol produced using the solid acid catalyst comprising the sulfonic acid group-containing carbonaceous material of the present invention is more in comparison with the alcohol produced by the conventional method using sulfuric acid or the method using heteropoly acid using supercritical conditions. Since the production method is simple, there is no corrosion of the apparatus, and there is little waste, it is inexpensive, and a ketone produced by dehydrogenating it can also be produced at low cost. That is, an inexpensive and economically advantageous method for producing methyl ethyl ketone from normal butene can be provided.
EXAMPLES Hereinafter, the present invention will be specifically described with reference to examples, but the present invention is not limited thereto.

[Example 1]
(Preparation of solid acid catalyst comprising sulfonic acid group-containing carbonaceous material)
40.0 g of cellulose was heat-treated at 400 ° C. for 4 hours in a nitrogen atmosphere to obtain 11.2 g of carbide. 150 g of concentrated sulfuric acid was added to 3.0 g of this carbide, followed by heat treatment at 150 ° C. for 15 minutes in a nitrogen atmosphere to perform sulfonation. After sulfonation, the black solid was filtered using a glass filter, washed repeatedly with hot water under reflux (about 100 ° C.), and continued until no sulfuric acid was detected in the washing solution. Next, drying was performed to obtain 3.1 g of a solid acid catalyst A made of an amorphous black powder-containing sulfonic acid group-containing carbonaceous material. It was 2.3 mmol / g as a result of investigating the acid amount of the solid acid catalyst which consists of the obtained sulfonic acid group containing carbonaceous material by back titration.
(Analysis of solid acid catalyst)
X-ray analysis of the solid acid catalyst A made of a sulfonic acid group-containing carbonaceous material was performed. For X-ray analysis, measurement was performed using an X-ray diffractometer (MXP18VAHF) manufactured by Mac Science. As a result, no peak capable of specifying the structure was detected from the analysis pattern of the solid acid catalyst made of the obtained sulfonic acid group-containing carbonaceous material, and it was found to be an amorphous substance. Elemental analysis of the solid acid catalyst A made of a sulfonic acid group-containing carbonaceous material was performed. In addition, the elemental analysis was measured using Elementary Vario EL. As a result, 7.0 × 10 −3 sulfur was detected in the S / C ratio in the solid acid catalyst made of the sulfonic acid group-containing carbonaceous material, and it was found that sulfonic acid groups were introduced.
The 13C-DDMAS nuclear magnetic resonance spectrum analysis of the solid acid catalyst A made of a sulfonic acid group-containing carbonaceous material was performed. In this analysis, the measurement was performed using NMR System 400WB manufactured by Varian. As a result, it was confirmed that most of the carbon was derived from aromatics.
The degree of graphitization of the solid acid catalyst A made of a sulfonic acid group-containing carbonaceous material was measured. For the measurement, a Raman spectroscopic analyzer was used. For this analysis, a laser Raman spectroscopic analyzer HOLOLAB5000R was used. At that time, it calculates the integrated intensity ratio of D peak observed around G peak and 1400 cm ^-1 observed around 1580 cm ^-1, and the peak intensity ratio D / G and degree of graphitization. As a result, it was confirmed that the degree of graphitization was 0.597.
(Hydration reaction)
A 200 cc autoclave with a stirrer is charged with 9.0 g (0.5 mol) of distilled water and 15.0 g of dioxane (solvent), and 0.20 g of a solid acid catalyst A made of a sulfonic acid group-containing carbonaceous material is added and sealed. 10.5 g (0.25 mol) of propylene was enclosed. Next, the temperature was raised to 120 ° C. while stirring at 700 rpm, the pressure was adjusted to 5 MPa with nitrogen, and a hydration reaction was performed for 2 hours while maintaining 120 ° C. After completion of the reaction, the reaction solution was cooled and then quantitative analysis was performed by TCD-GC. As a result, the amount of isopropyl alcohol converted per unit catalyst amount per unit time was 0.57 mmol / g-cat. / Hr. The results are shown in Table 1.
(Etherification reaction)
A 200 cc autoclave with a stirrer is charged with 15 g (0.25 mol) of isopropyl alcohol, 0.20 g of solid acid catalyst A made of a sulfonic acid group-containing carbonaceous material is added and sealed, and 21.0 g (0. 5 mol) was enclosed. Next, the temperature was raised to 110 ° C. while stirring at 700 rpm, the pressure was adjusted to 5 MPa with nitrogen, and then the etherification reaction was performed for 2 hours while maintaining the temperature at 110 ° C. After completion of the reaction, the reaction solution was cooled, and the product was quantitatively analyzed by TCD-GC. As a result, the amount of unit catalyst and the amount of diisopropyl ether converted per unit time were 1.26 mmol / g-cat. / Hr. The results are shown in Table 1.
[Example 2] and [Comparative Examples 1 and 2]
(Preparation of solid acid catalyst comprising sulfonic acid group-containing carbonaceous material)
Using the raw materials, carbonization treatment conditions and sulfonation treatment conditions described in Table 1, solid acid catalysts B, D, and E each made of a sulfonic acid group-containing carbonaceous material are produced by the same operations as in Example 1 above. did. The cellulose used as the raw material was the same as that used in Example 1. Table 1 shows the results of examining the acid amount of the obtained solid acid catalyst comprising the sulfonic acid group-containing carbonaceous material by back titration.
(Analysis of solid acid catalyst made of sulfonic acid group-containing carbonaceous material)
The X-ray analysis, 13C-DDMAS nuclear magnetic resonance spectrum analysis, and graphitization degree measurement were performed on the solid acid catalysts B, D, and E made of the sulfonic acid group-containing carbonaceous material. The same results as in Example 1 were obtained for X-ray analysis and 13C-DDMAS nuclear magnetic resonance spectrum analysis.
Moreover, the elemental analysis and carbonization degree measurement (Raman spectroscopic analysis) of the solid acid catalyst B, D, and E which consist of a sulfonic acid group containing carbonaceous material were performed by the method similar to Example 1, and the result was shown in Table 1.
(Hydration reaction)
Instead of the solid acid catalyst A comprising a sulfonic acid group-containing carbonaceous material as a catalyst, a solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material obtained in Example 2 and Comparative Examples 1 and 2 was used. Were hydrated with propylene under the same conditions and operating procedures as in Example 1. Table 1 shows the amount of isopropyl alcohol converted per unit catalyst amount per unit time.
(Etherification reaction)
As the etherification reaction of Comparative Example 2, the above Example was used except that instead of the solid acid catalyst A comprising a sulfonic acid group-containing carbonaceous material as a catalyst, the solid acid catalyst E comprising a sulfonic acid group-containing carbonaceous material was used. The synthesis reaction of diisopropyl ether was carried out under the same conditions and operating procedures as in 1. As a result, the amount of unit catalyst and the amount of diisopropyl ether produced per unit time are shown in Table 1.
[Example 3] and [Comparative Example 3]
(Preparation of solid acid catalyst comprising sulfonic acid group-containing carbonaceous material)
Using the raw materials, carbonization treatment conditions, and sulfonation treatment conditions described in Table 2, solid acid catalysts C and F made of a sulfonic acid group-containing carbonaceous material were produced in the same manner as in Example 1 except that. In addition, the composition (Phenolite (trademark) TD-739A by Dainippon Ink and Chemicals Inc.) which mix | blended 8 mass% of hardening | curing agents hexamethylenetetramine was used for the novolak-type phenol resin used for the raw material. The acid amount of the obtained solid acid catalyst comprising the sulfonic acid group-containing carbonaceous material was examined by back titration. The results are shown in Table 2.
(Analysis of solid acid catalyst made of sulfonic acid group-containing carbonaceous material)
The X-ray analysis, 13C-DDMAS nuclear magnetic resonance spectrum analysis, and graphitization degree measurement were performed on the solid acid catalysts C and F made of a sulfonic acid group-containing carbonaceous material. The same results as in Example 1 were obtained for X-ray analysis and 13C-DDMAS nuclear magnetic resonance spectrum analysis. Table 2 shows the results of elemental analysis of the solid acid catalysts C and F made of the sulfonic acid group-containing carbonaceous material by the same method as in Example 1. On the other hand, in the carbonization measurement (Raman spectroscopic analysis), the solid acid catalyst C or F made of a sulfonic acid group-containing carbonaceous material, that is, a solid acid catalyst made of a sulfonic acid group-containing carbonaceous material using a novolac type phenol resin as a raw material. As shown in Table 2, no clear spectrum was observed, and the degree of carbonization could not be obtained.
(Hydration reaction)
Instead of the solid acid catalyst A comprising a sulfonic acid group-containing carbonaceous material as a catalyst, except that the solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material obtained in Example 3 and Comparative Example 3 was used, Propylene hydration was carried out under the same conditions and operating method as in Example 1. Table 2 shows the amount of isopropyl alcohol converted per unit catalyst amount per unit time.
[Comparative Example 4]
(Preparation of solid acid catalyst comprising sulfonic acid group-containing carbonaceous material)
A solid acid catalyst G made of a sulfonic acid group-containing carbonaceous material was produced using the same raw materials as in Example 3 except that the carbonization treatment conditions and the sulfonation treatment conditions were changed to the conditions described in Table 2. As shown in Table 2, the acid amount of the obtained solid acid catalyst G composed of the sulfonic acid group-containing carbonaceous material was very small as shown in Table 2.
(Analysis of solid acid catalyst made of sulfonic acid group-containing carbonaceous material)
X-ray analysis, 13C-DDMAS nuclear magnetic resonance spectrum analysis, and graphitization degree measurement of the solid acid catalyst G made of a sulfonic acid group-containing carbonaceous material were performed in the same manner as in Example 3. The same results as in Example 3 were obtained for X-ray analysis and 13C-DDMAS nuclear magnetic resonance spectrum analysis. In addition, as a result of elemental analysis of the solid acid catalyst G made of the sulfonic acid group-containing carbonaceous material by the same method as in Example 3, the sulfur content was not detected as shown in Table 2, and the introduction of the sulfonic acid group was I was not able to admit. On the other hand, in the carbonization measurement (Raman spectroscopic analysis), the solid acid catalyst G made of the sulfonic acid group-containing carbonaceous material showed a high carbonization degree as shown in Table 2.
(Hydration reaction)
As shown in Table 2, the solid acid catalyst G comprising the sulfonic acid group-containing carbonaceous material of Comparative Example 4 produced by carbonization treatment at a very high carbonization temperature and then sulfonation treatment showed no olefin hydration activity. There wasn't. The results are shown in Table 2.
(Acid decomposition reaction of cumene hydroperoxide)
[Example 4 and Comparative Example 5]
Using the raw materials, carbonization treatment conditions, and sulfonation treatment conditions described in Table 3, solid acid catalysts H and I made of a sulfonic acid group-containing carbonaceous material were produced in the same manner as in Example 1 except that. H is the solid acid catalyst of the present invention, and I is a solid acid catalyst for comparison.
The acid decomposition reaction which decomposes | disassembles cumene hydroperoxide and produces | generates a phenol using solid acid catalyst H and I was implemented. A 100 cc three-necked flask was charged with 13.8 g of ethanol and 0.2 g of a solid acid catalyst composed of a sulfonic acid group-containing carbonaceous material, and heated and stirred at a reflux temperature (80 ° C.) in a nitrogen atmosphere. 15.2 g of cumene hydroperoxide (content 88%) was added dropwise thereto. Two hours after the completion of the dropwise addition, the reaction solution was cooled and quantitative analysis was performed by LC. The results are shown in Table 3. As is clear from Table 3, the solid acid catalyst of the present invention exhibits a higher phenol yield than the solid acid catalyst of the comparative example.
(Synthesis reaction of ethyl acetate)
[Example 5 and Comparative Example 6]
Using the raw materials, carbonization treatment conditions, and sulfonation treatment conditions described in Table 3, solid acid catalysts J and K each consisting of a sulfonic acid group-containing carbonaceous material were produced in the same manner as in Example 1 except that. J is the solid acid catalyst of the present invention, and K is a solid acid catalyst for comparison.
In an eggplant-shaped flask having an internal volume of 100 ml, 30 ml of ethanol was charged, acetic acid was added at a molar ratio of 1/50 with respect to alcohol, and 0.20 g of a sulfonic acid group-containing carbonaceous material was added and heated. The mixture was reacted at reflux temperature (80 ° C.) for 2 hours with stirring, and then quenched in a water bath to stop the reaction. After completion of the reaction, the product was quantitatively analyzed by a gas chromatograph equipped with an FID detector. The results are also shown in Table 3. As is apparent from Table 3, the solid acid catalyst of the present invention shows a higher ethyl acetate yield than the solid acid catalyst of the comparative example.
[Example 6] and [Comparative Example 7]
(Manufacture of sulfonic acid group-containing carbonaceous material from wood)
Using the raw materials, carbonization treatment conditions, and sulfonation treatment conditions described in Table 3, solid acid catalysts L and M made of a sulfonic acid group-containing carbonaceous material were produced in the same manner as in Example 1 except that. The number average particle diameter of the eucalyptus powder used as a raw material is 0.250 mm. Table 3 shows the results obtained by measuring the acid amount of the obtained sulfonic acid group-containing carbonaceous material by titration.
(Butene-1 hydration reaction)
A 500 cc autoclave reactor was charged with 45.0 g (2.5 mol) of distilled water, 4.0 g of solid acid catalyst L made of a sulfonic acid group-containing carbonaceous material was added and sealed, and 92.5 g of butene-1 ( 1.25 mol) was enclosed. Next, the temperature was raised to 145 ° C. while stirring at 200 rpm, the pressure was adjusted to 5 MPa with nitrogen, and a hydration reaction was performed for 7.5 hours while maintaining 150 ° C. After completion of the reaction, the reaction solution was cooled and then quantitative analysis was performed by TCD-GC. As a result, the unit catalyst amount of 2-butanol and the amount of product converted per unit time were 0.78 mmol / g- each when the sulfonic acid group-containing carbonaceous material L and the sulfonic acid group-containing carbonaceous material M were used. cat. / Hr, 0.42 mmol / g-cat. / Hr. The amounts produced were 1.7 g and 0.9 g, respectively.
[Example 7]
(Debutation reaction of 2-butanol)
The 2-butanol obtained in Example 6 was dehydrogenated. To a 100 cc autoclave equipped with a stirrer, 1.7 g of 2-butanol and 0.1 g of copper zinc catalyst (manufactured by Aldrich) are added and sealed, then heated to 500 ° C. while stirring at 700 rpm, and dehydrogenation reaction for 1 hour Went. After completion of the reaction, the reaction solution was cooled and quantitative analysis was performed by TCD-GC to confirm that 0.8 g of methyl ethyl ketone was obtained.
From the above, the solid acid catalyst comprising the sulfonic acid group-containing carbonaceous material according to the production method of the present invention is more active as a solid acid catalyst than the carbonaceous material containing a sulfonic acid group according to the conventional production technique, that is, It has been revealed that it has high activity for acid-catalyzed reactions such as olefin hydration and etherification reactions.

As described above, according to the present invention, the production of a solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material having high activity with respect to an acid catalyst reaction such as an olefin hydration reaction, an etherification reaction or an esterification reaction. It becomes possible to provide a method. In addition, according to the present invention, it is possible to provide a method for producing a solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material from an inexpensive raw material such as woods or herbs. As a result, by using the solid acid catalyst obtained by the production method, an efficient production process of an olefin hydration reaction product or an acid-catalyzed reaction process such as ethers or esters is provided. It becomes possible to do. Further, secondary butanol can be produced efficiently by the hydration reaction of normal butene using the solid acid catalyst of the present invention, and methyl ethyl ketone can be produced efficiently and inexpensively by dehydrogenating it. The solid acid catalyst of the present invention is also effective for the production of phenol by the acid decomposition reaction of cumene hydroperoxide.

Claims (14)

  In the method for producing a solid acid catalyst composed of a sulfonic acid group-containing carbonaceous material obtained by carbonizing and sulfonating an organic substance by heating in an inert gas atmosphere, performing a sulfonation treatment after performing the carbonization treatment, A method for producing a solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material, wherein the carbonization temperature is 300 to 600 ° C. and the sulfonation time is 5 to 150 minutes.   2. The method for producing a solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material according to claim 1, wherein the sulfonation temperature is 20 to 250 ° C. Manufacturing method.   3. The method for producing a solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material according to claim 1 or 2, wherein concentrated sulfuric acid is used as a sulfonating agent, and the solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material. Manufacturing method.   4. A method for producing a solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material according to claim 1, wherein cellulose is used as the organic substance. .   4. The method for producing a solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material according to claim 1, wherein a phenol resin is used as the organic substance. Method.   In the manufacturing method of the solid acid catalyst which consists of a sulfonic acid group containing carbonaceous material of Claim 1 to 3, woods and / or grasses are used as organic substance, From the sulfonic acid group containing carbonaceous material characterized by the above-mentioned The manufacturing method of the solid acid catalyst which becomes.   In the manufacturing method of the solid acid catalyst which consists of a sulfonic acid group containing carbonaceous material of Claim 1 to 6, the integrated intensity of D peak / G peak integrated intensity of the Raman analysis value of the said solid acid catalyst is 0.0- A method for producing a solid acid catalyst comprising a sulfonic acid group-containing carbonaceous material, wherein 0.7 or the peak of the Raman spectrum is not observed.   A method for producing an olefin hydrated product, comprising performing a hydration reaction of an olefin using the solid acid catalyst obtained by the method according to claim 1.   A method for producing ethers, wherein an olefin etherification reaction is carried out using the solid acid catalyst obtained by the method according to claim 1.   A method for producing phenols from aralkyl hydroperoxide, wherein an acid decomposition reaction of aralkyl hydroperoxide is performed using the solid acid catalyst obtained by the method according to claim 1.   The method for producing a phenol according to claim 10, wherein the aralkyl hydroperoxide is cumene hydroperoxide and the phenol is phenol.   8. A method for producing an ester, comprising subjecting an alcohol and a carboxylic acid to an esterification reaction using the solid acid catalyst obtained by the method according to claim 1.   A method for producing a ketone, characterized in that a dehydrogenation reaction of the olefin hydrate product obtained according to claim 8 is carried out.   The method for producing ketones according to claim 13, wherein the olefin hydration product is 2-butanol and the ketones are methyl ethyl ketone.