CN104248991B - The preparation method of the composite mesoporous carrier of spherical montmorillonite and loaded catalyst and its preparation method and application and ethyl acetate - Google Patents

Abstract

The preparation method that the invention discloses the application in the esterification reaction of a kind of composite mesoporous carrier of spherical montmorillonite and preparation method thereof and support type benzenesulfonic acid Catalysts and its preparation method and this catalyst and a kind of ethyl acetate.The composite mesoporous carrier montmorillonite of this spherical montmorillonite and the meso-porous molecular sieve material with three-dimensional cubic duct structure, the mean diameter of this composite mesoporous carrier of spherical montmorillonite is 20-50 micron, specific surface area is 150-600 meters squared per gram, pore volume is 0.5-1.5 ml/g, pore-size distribution is bimodal distribution, and the most probable pore size of described bimodal correspondence respectively 2-8 nanometer and 20-50 nanometer.Support type benzenesulfonic acid catalyst provided by the invention not only has higher catalysis activity, and can Reusability.

Description

The preparation method of the composite mesoporous carrier of spherical montmorillonite and loaded catalyst and its preparation method and application and ethyl acetate

Technical field

The preparation method that the present invention relates to the application in the esterification reaction of a kind of composite mesoporous carrier of spherical montmorillonite, the preparation method of a kind of composite mesoporous carrier of spherical montmorillonite, the method composite mesoporous carrier of spherical montmorillonite prepared, a kind of support type benzenesulfonic acid catalyst, the preparation method of a kind of support type benzenesulfonic acid catalyst, this support type benzenesulfonic acid catalyst and a kind of ethyl acetate.

Background technology

Montmorillonite is that earth's surface is distributed one of most commonly used clay mineral, it has the physical and chemical performances such as the interchangeability of the particle diameter of nano-micrometer level, bigger serface, interlayer ion, therefore can pass through physico-chemical process the Intercalation reaction of montmorillonite or surface graft some with the lewis' acid of specific functional groups, thus realizing the modification to its surface and performance regulation and control.Acidization can make effective hole of montmorillonite and surface scission of link increase, such that it is able to inlay and be detained the suitable material of external particle diameter (such as pollutant etc.) or carry out surface adsorption, and montmorillonite is carried out acidifying its specific surface area can be made to increase, and make it have the characteristic of acidic catalyst, and there is higher catalytic reaction ability.

Meso-porous molecular sieve material has that duct is orderly, aperture is adjustable, specific surface area and the advantage such as pore volume is bigger, is good catalyst and carrier material.In recent years the heterogeneous catalyst such as solid acid, heteropoly acid is prepared with meso-porous molecular sieve material for template, high for esterification catalytic activity, and side reaction is few, post processing is simple.The similar MCM-48 of pore passage structure of mesoporous KIT-6, for the meso-hole structure that three-dimensional cubic is orderly, but its aperture is big compared with the latter, and duct interconnects, this provides a good template for the direct load of active specy, loaded article can be made dispersed and be formed without the bulky grain of reunion in whole duct, but ordered mesoporous material KIT-6 mobility is poor, and its big specific surface area and high pore volume cause and make it have stronger water suction, moisture absorption ability, this will be further exacerbated by the reunion of bar-shaped ordered mesopore material, thus can cause that the loaded catalyst being made up of this mesoporous material is easily reunited in esterification reaction process, and then can seriously reduce the conversion ratio of acetic acid in ethyl acetate preparation technology.

At present, industrial concentrated sulphuric acid is as catalyst synthesizing ethyl acetate, it has, and equipment investment is big, side reaction is many, product separates the defects such as complicated and liquid waste processing difficulty, therefore, in order to overcome drawbacks described above, the catalyst of the esterification that exploitation makes new advances is to replace concentrated sulphuric acid, and people have carried out substantial amounts of correlational study.Wherein, solid acid, solid super-strong acid and cation exchange resin etc., as the catalyst of esterification, are all more successfully explore, these catalyst have higher catalysis activity, but still come with some shortcomings, for instance adopting solid super-strong acid as the esterification of catalyst, by-product is more.

Summary of the invention

It is an object of the invention to overcome the loaded catalyst adopting existing meso-porous molecular sieve material to make defect of reaction raw materials low conversion rate in for esterification reaction process, and the preparation method that the application in the esterification reaction of a kind of composite mesoporous carrier of spherical montmorillonite, the preparation method of a kind of composite mesoporous carrier of spherical montmorillonite, the method composite mesoporous carrier of spherical montmorillonite prepared, a kind of support type benzenesulfonic acid catalyst, the preparation method of a kind of support type benzenesulfonic acid catalyst, this support type benzenesulfonic acid catalyst and a kind of ethyl acetate are provided.

In order to achieve the above object, the present inventor is by finding after studying, the meso-porous molecular sieve material with three-dimensional cubic duct structure introduces montmorillonite, montmorillonite is made to enter in the duct of meso-porous molecular sieve material, and this mesoporous composite material is made and is not susceptible to the spherical of reunion, so can retain the high-specific surface area of meso-porous molecular sieve material, big pore volume, large aperture and there is the features such as three-dimensional cubic duct structure, the reunion of meso-porous molecular sieve material can be reduced again, increase its mobility, make the loaded catalyst adopting this mesoporous composite material to make can obtain the reaction raw materials conversion ratio significantly improved when for esterification, thus completing the present invention.

The invention provides a kind of composite mesoporous carrier of spherical montmorillonite, wherein, the described composite mesoporous carrier of spherical montmorillonite contains montmorillonite and has the meso-porous molecular sieve material of three-dimensional cubic duct structure, and the mean diameter of the described composite mesoporous carrier of spherical montmorillonite is 20-50 micron, specific surface area is 150-600 meters squared per gram, pore volume is 0.5-1.5 ml/g, and pore-size distribution is bimodal distribution, and the most probable pore size of described bimodal correspondence respectively 2-8 nanometer and 20-50 nanometer.

Additionally, the preparation method that present invention also offers a kind of composite mesoporous carrier of spherical montmorillonite, the method comprises the following steps:

(1) under the existence of template and butanol, tetraethyl orthosilicate is contacted with acid agent, and the product after contact is carried out crystallization and filtration, obtain the filter cake with the meso-porous molecular sieve material of three-dimensional cubic duct structure；

(2) waterglass is contacted with mineral acid, and the product obtained after contact is filtered, obtain silica gel filter cake；

(3) filter cake of the described mesoporous material with three-dimensional cubic duct structure, described silica gel filter cake are mixed homogeneously and ball milling with montmorillonite, and spray drying will carry out after the pressed powder water slurrying obtained after ball milling, then by the described template removal in the product that obtains after spray drying.

Present invention also offers a kind of composite mesoporous carrier of spherical montmorillonite prepared by said method.

Present invention also offers a kind of support type benzenesulfonic acid catalyst, wherein, this catalyst includes the above-mentioned composite mesoporous carrier of spherical montmorillonite and the load benzenesulfonic acid on the described composite mesoporous carrier of spherical montmorillonite.

The preparation method that present invention also offers a kind of support type benzenesulfonic acid catalyst, wherein, the method includes the above-mentioned composite mesoporous carrier of spherical montmorillonite, benzenesulfonic acid and water mix homogeneously, and the mixture obtained is carried out spray drying.

Present invention also offers the application in the esterification reaction of above-mentioned support type benzenesulfonic acid catalyst.

The preparation method that present invention also offers a kind of ethyl acetate, the method includes: in the presence of a catalyst and when esterification, is contacted with ethanol by acetic acid, obtains ethyl acetate, and wherein, described catalyst is above-mentioned support type benzenesulfonic acid catalyst.

The inventors found that, including the above-mentioned composite mesoporous carrier of spherical montmorillonite with certain physical property and load, the catalyst activity of the benzenesulfonic acid on the described composite mesoporous carrier of spherical montmorillonite is higher, can the esterification of catalysis acetic acid and ethanol obtain higher acetic acid conversion and ethyl acetate selectivity, this is possibly due to: on the one hand, carrier provided by the invention is spherical, the reunion of powder body can be reduced, improve its mobility；On the other hand, carrier provided by the invention not only retains that the high-specific surface area of ordered mesoporous material, big pore volume, aperture be big and the feature of three-dimensional cubic duct structure, and its pore-size distribution presents the bimodal distribution of uniqueness, is more beneficial for the load of active component, thus having higher catalysis activity.

Additionally, cheap montmorillonite is incorporated in composite, it is possible to reduce the production cost of carrier to a great extent.Namely, micro-sphere structure, the advantage of meso-porous molecular sieve material and montmorillonite with three-dimensional cubic duct structure are combined by the composite mesoporous carrier of spherical montmorillonite provided by the invention dexterously, thus the application for the described composite mesoporous carrier of spherical montmorillonite provides better platform, and expand its application.

Additionally, catalyst provided by the invention also has and does not corrode that instrument, side reaction be few and the simple advantage of aftertreatment technology.

It addition, when preparing described support type benzenesulfonic acid catalyst by the method for spray drying, described support type benzenesulfonic acid catalyst may be repeated utilization, and still can obtain higher reaction raw materials conversion ratio in recycling process.

Other features and advantages of the present invention will be described in detail in detailed description of the invention part subsequently.

Accompanying drawing explanation

Accompanying drawing is used to provide a further understanding of the present invention, and constitutes the part of description, is used for explaining the present invention, but is not intended that limitation of the present invention together with detailed description below.In the accompanying drawings:

Fig. 1 is X-ray diffracting spectrum (XRD figure spectrum), and wherein, a is the XRD spectra of the composite mesoporous carrier of the spherical montmorillonite (C1) according to the present invention；B is the XRD spectra of the composite mesoporous carrier of the spherical montmorillonite (Cat-1) of the load benzenesulfonic acid obtained by spray drying method according to the present invention, and abscissa is 2 θ, and vertical coordinate is intensity；

Fig. 2 is the scanning electron microscope (SEM) photograph (SEM) of the microscopic appearance of the composite mesoporous carrier of the spherical montmorillonite (C1) according to the present invention；

Fig. 3 is the scanning electron microscope (SEM) photograph (SEM) of the microscopic appearance of the composite mesoporous carrier of the spherical montmorillonite (Cat-1) of the load benzenesulfonic acid obtained by spray drying method according to the present invention；

Fig. 4 is the pore size distribution curve figure of the composite mesoporous carrier of the spherical montmorillonite (C1) according to the present invention；

Fig. 5 is the pore size distribution curve figure of the composite mesoporous carrier of the spherical montmorillonite (Cat-1) of the load benzenesulfonic acid obtained by spray drying method according to the present invention.

Detailed description of the invention

Hereinafter the specific embodiment of the present invention is described in detail.It should be appreciated that detailed description of the invention described herein is merely to illustrate and explains the present invention, it is not limited to the present invention.

The present invention provides a kind of composite mesoporous carrier of spherical montmorillonite, wherein, the described composite mesoporous carrier of spherical montmorillonite contains montmorillonite and has the meso-porous molecular sieve material of three-dimensional cubic duct structure, and the mean diameter of the described composite mesoporous carrier of spherical montmorillonite is 20-50 micron, specific surface area is 150-600 meters squared per gram, pore volume is 0.5-1.5 ml/g, and pore-size distribution is bimodal distribution, and the most probable pore size of described bimodal correspondence respectively 2-8 nanometer and 20-50 nanometer.Under preferable case, the mean diameter of the described composite mesoporous carrier of spherical montmorillonite is 20-40 micron；Specific surface area is 210-600 meters squared per gram；Pore volume is 0.8-1.5 ml/g；Pore-size distribution is bimodal distribution, and the most probable pore size of described bimodal correspondence respectively 2-6 nanometer and 25-30 nanometer.

The composite mesoporous carrier of spherical montmorillonite according to the present invention has three-dimensional cubic duct structure, and the mean diameter of its granule adopts laser fineness gage to record, and specific surface area, pore volume and most probable pore size record according to nitrogen adsorption methods.

The composite mesoporous carrier of spherical montmorillonite according to the present invention, by the particle size of composite mesoporous for spherical montmorillonite carrier is controlled within above-mentioned scope, may insure that the described composite mesoporous carrier of spherical montmorillonite is not susceptible to reunite, and the reaction raw materials conversion ratio that the loaded catalyst made used as carrier can improve in esterification reaction process.When the specific surface area of described spherical montmorillonite mesoporous composite material less than 150 meters squared per gram and/or pore volume less than 0.5 ml/g time, the catalysis activity of the support type benzenesulfonic acid catalyst made used as carrier can significantly reduce；When the specific surface area of the described composite mesoporous carrier of spherical montmorillonite more than 600 meters squared per gram and/or pore volume more than 1.5 mls/g time, the support type benzenesulfonic acid catalyst made used as carrier is susceptible to reunite in esterification reaction process, thus the reaction raw materials conversion ratio affected in esterification reaction process.

In the described composite mesoporous carrier of spherical montmorillonite, relative to the meso-porous molecular sieve material described in 100 weight portions with three-dimensional cubic duct structure, the content of described montmorillonite can be 1-50 weight portion, it is preferred to 20-50 weight portion.

In the present invention, the described composite mesoporous carrier of spherical montmorillonite can also contain the silicon dioxide introduced by waterglass." by the silicon dioxide that waterglass introduces " refers in the preparation process of the described composite mesoporous carrier of spherical montmorillonite, waterglass bring the silica component in the final spherical montmorillonite complex carrier prepared into as preparing raw material.In the described composite mesoporous carrier of spherical montmorillonite, relative to the meso-porous molecular sieve material described in 100 weight portions with three-dimensional cubic duct structure, the content of the described silicon dioxide introduced by waterglass can be 1-200 weight portion, it is preferred to 50-150 weight portion.

In the present invention, the meso-porous molecular sieve material described in three-dimensional cubic duct structure for meso-porous molecular sieve material commonly used in the art, and can prepare according to conventional method.As a rule, it is mainly composed of silicon dioxide, and the mean diameter of described meso-porous molecular sieve material is 20-50 micron, specific surface area is 150-600 meters squared per gram, pore volume is 0.5-1.5 ml/g, pore-size distribution is bimodal distribution, and the most probable pore size of described bimodal correspondence respectively 2-8 nanometer and 20-50 nanometer.

The preparation method that present invention also offers a kind of composite mesoporous carrier of spherical montmorillonite, the method comprises the following steps:

(1) under the existence of template and butanol, tetraethyl orthosilicate is contacted with acid agent, and the product after contact is carried out crystallization and filtration, obtain the filter cake with the meso-porous molecular sieve material of three-dimensional cubic duct structure；

(2) waterglass is contacted with mineral acid, and the product obtained after contact is filtered, obtain silica gel filter cake；

(3) filter cake of the described mesoporous material with three-dimensional cubic duct structure, described silica gel filter cake are mixed homogeneously and ball milling with montmorillonite, and spray drying will carry out after the pressed powder water slurrying obtained after ball milling, then by the described template removal in the product that obtains after spray drying.

In the preparation process of the above-mentioned composite mesoporous carrier of spherical montmorillonite, mainly through controlling the composition with silica gel filter cake of the meso-porous molecular sieve material filter cake with three-dimensional cubic duct structure, the pore-size distribution of the described composite mesoporous carrier of spherical montmorillonite is controlled as bimodal distribution, and make this composite mesoporous carrier of spherical montmorillonite have three-dimensional cubic duct structure, and by controlling forming method (namely, first by meso-porous molecular sieve material filter cake, silica gel filter cake is mixed homogeneously with montmorillonite and ball milling, then by spray drying after the pressed powder water slurrying obtained) microscopic appearance of the described composite mesoporous carrier of spherical montmorillonite is controlled as spherical.

According to the present invention, the mol ratio of described template, butanol and tetraethyl orthosilicate can change in wider scope, as long as the meso-porous molecular sieve material filter cake with three-dimensional cubic duct structure can be formed, under preferable case, the mol ratio of described template, butanol and tetraethyl orthosilicate is 1:10-100:10-90, it is preferred that in situation, the mol ratio of described template, butanol and tetraethyl orthosilicate is 1:60-90:50-75.Wherein, when described template is polyoxyethylene-poly-oxypropylene polyoxyethylene template, the molal quantity of described template calculates according to the mean molecule quantity of polyoxyethylene-poly-oxypropylene polyoxyethylene and obtains.

According to the present invention, to the kind of described template, there is no particular limitation, as long as can so that the composite mesoporous carrier of spherical montmorillonite obtained has above described holes structure, for instance, described template can be triblock copolymer polyoxyethylene-poly-oxypropylene polyoxyethylene template.Wherein, this template can be commercially available that (for example, it is possible to available from Aldrich Co, commodity are called P123, and molecular formula is EO₂₀PO₇₀EO₂₀), it is also possible to prepared by existing various methods.When described template is polyoxyethylene-poly-oxypropylene polyoxyethylene, the molal quantity of described template calculates according to the mean molecule quantity of polyoxyethylene-poly-oxypropylene polyoxyethylene and obtains.

According to the present invention, described butanol is preferably n-butyl alcohol.

According to the present invention, to the kind of described acid agent, there is no particular limitation, it is possible to for the conventional selection of this area, it is possible to for the mixture of existing various acid or acid.Under preferable case, described acid agent is hydrochloric acid.Hydrochloric acid as acid agent preferably uses in form of an aqueous solutions.The pH value of aqueous hydrochloric acid solution can be 1-6.

The condition that described tetraethyl orthosilicate is contacted by the present invention with acid agent does not limit especially, for instance, the condition of described tetraethyl orthosilicate and acid agent generally includes: temperature can be 10-60 DEG C, and the time can be 10-72 hour, and pH value is 1-7.In order to be more beneficial for the Homogeneous phase mixing between each material, described tetraethyl orthosilicate contacts with acid agent and preferably carries out under agitation.The consumption of described acid agent is preferably so that the pH value of haptoreaction system of tetraethyl orthosilicate and acid agent is 1-7.

There is no particular limitation to the condition of described crystallization for the present invention, the condition of described crystallization can be the selection that this area is conventional, such as, the condition of described crystallization may include that temperature is 30-150 DEG C, time is 10-72 hour, under preferable case, the condition of described crystallization includes: temperature is 40-100 DEG C, and the time is 20-40 hour.Described crystallization is implemented by hydrothermal crystallization method.

According to the present invention, to described template, butanol, tetraethyl orthosilicate and acid agent the way of contact there is no particular limitation, such as above-mentioned four kinds of materials can be mixed contact simultaneously, wherein several materials first can also be mixed contact, more remaining material is added continuation mixing contact in the mixture obtained.Under preferable case, the mixture obtained, for adding butanol stirring after first described template being mixed with described acid agent stirring, is then placed in a water bath, keeps temperature-resistant by the described way of contact, again tetraethyl orthosilicate is slowly added dropwise to gained mixture, and continues stirring reaction.

The condition that waterglass is contacted by the present invention with mineral acid is not particularly limited, it is possible to the common process according to preparing silica gel is suitably determined.Under preferable case, the condition that waterglass contacts with mineral acid generally includes: temperature can be 10-60 DEG C, it is preferred to 20-40 DEG C；Time can be 1-5 hour, it is preferred to 1.5-3 hour；PH value is 2-4.In order to be more beneficial for the Homogeneous phase mixing between each material, described waterglass contacts with mineral acid and preferably carries out under agitation.

As well known to those skilled in the art, described waterglass is the aqueous solution of sodium silicate, and its concentration can be 10-50 weight %, it is preferred to 12-30 weight %.

The kind of described mineral acid can be the conventional selection of this area, for instance, it is possible to for one or more in sulphuric acid, nitric acid and hydrochloric acid.Described mineral acid can use in pure form, it is also possible to uses with the form of its aqueous solution.The consumption of described mineral acid is preferably so that the pH value of waterglass and the haptoreaction system of mineral acid is 2-4.

According to the present invention, in the filter cake of the described meso-porous molecular sieve material with three-dimensional cubic duct structure and the preparation process of described silica gel filter cake, the mode of described filtration can adopt and well known to a person skilled in the art that various mode carries out, it is preferred to sucking filtration separates.It is well-known to those skilled in the art utilize air pressure to realize a kind of mode that liquid separates with solid particle that described sucking filtration separates.

Have in the filter cake of the meso-porous molecular sieve material of three-dimensional cubic duct structure and the process of silica gel filter cake in above-mentioned preparation, be may include that after filtration by the process filtered to obtain filter cake, with deionized water (distilled water) cyclic washing (washing times can be 2-10 time), then carry out sucking filtration.

According to the present invention, in step (3), the described consumption with the meso-porous molecular sieve material filter cake of three-dimensional cubic duct structure, silica gel filter cake and montmorillonite can select according to the component of the composite mesoporous carrier of spherical montmorillonite that expection obtains, such as, with the consumption of the filter cake of the meso-porous molecular sieve material described in 100 weight portions with three-dimensional cubic duct structure for benchmark, the consumption of described silica gel filter cake is 1-200 weight portion, it is preferred to 50-150 weight portion；The consumption of described montmorillonite can be 1-50 weight portion, it is preferred to 20-50 weight portion.

According to the present invention, in step (3), to the concrete operation method of described ball milling and condition, there is no particular limitation, and the structure not destroy or substantially not destroy meso-porous molecular sieve material is as the criterion.Those skilled in the art can select various suitable condition to implement the present invention according to mentioned above principle.Specifically, described ball milling carries out in ball mill, and in described ball mill, the inwall of ball grinder is preferably polytetrafluoroethyllining lining, and wherein, in ball mill, the diameter of abrading-ball can be 2-3mm；The quantity of abrading-ball reasonably can select according to the size of ball grinder, for being sized to the ball grinder of 50-150mL, generally can use 1 abrading-ball；The material of described abrading-ball can be Achates, politef etc., it is preferred to Achates.The condition of described ball milling includes: the rotating speed of abrading-ball can be 300-500r/min, and the temperature in ball grinder can be 15-100 DEG C, and the time of ball milling can be 0.1-100 hour.

In step (3), the process of the pressed powder water slurrying obtained after ball milling can be carried out at 25-60 DEG C.In pulping process, the weight ratio of the consumption of pressed powder and water can be 1:0.1-2, it is preferred to 1:0.3-1.

According to the present invention, concrete operation method and the condition of described spray drying are known to the skilled person.Specifically, described pressed powder and water the slurry being made into is joined in nebulizer high speed rotating to realize spray drying.Wherein, the condition of spray drying includes temperature can be 100-300 DEG C, and the rotating speed of rotation can be 10000-15000r/min；Under preferable case, the condition of described spray drying includes temperature and is 150-250 DEG C, and the rotating speed of rotation is 11000-13000r/min.

According to the present invention, the method for removed template method is generally calcination method.The condition of described removed template method can be the selection that this area is conventional, for instance, the condition of described removed template method includes: temperature can be 300-600 DEG C, it is preferred to 350-550 DEG C, it is most preferred that be 500 DEG C；Time can be 10-80 hour, it is preferred to 20-30 hour, it is most preferred that is 24 hours.

Present invention also offers the composite mesoporous carrier of spherical montmorillonite prepared by said method.

Present invention also offers a kind of support type benzenesulfonic acid catalyst, wherein, this catalyst includes the above-mentioned composite mesoporous carrier of spherical montmorillonite and the load benzenesulfonic acid on the described composite mesoporous carrier of spherical montmorillonite.

According to the present invention, in described support type benzenesulfonic acid catalyst, the content of the described composite mesoporous carrier of spherical montmorillonite and benzenesulfonic acid can be the conventional selection of this area, such as, with the gross weight of described support type benzenesulfonic acid catalyst for benchmark, the content of described benzenesulfonic acid can be 1-50 weight %, the content of the described composite mesoporous carrier of spherical montmorillonite can be 50-99 weight %, under preferable case, with the gross weight of described support type benzenesulfonic acid catalyst for benchmark, the content of described benzenesulfonic acid can be 5-50 weight %, the content of the described composite mesoporous carrier of spherical montmorillonite can be 50-95 weight %.

In the present invention, described support type benzenesulfonic acid catalyst can be prepared according to various methods commonly used in the art, it is only necessary to by benzenesulfonic acid load on the carrier.

In a preferred embodiment, in order to make the support type benzenesulfonic acid catalyst of preparation may be repeated utilization, and in recycling process, still can obtain higher reaction raw materials conversion ratio, the method preparing loaded catalyst includes: by carrier, benzenesulfonic acid and water mix homogeneously, and the mixture obtained is carried out spray drying, wherein, described carrier is the above-mentioned composite mesoporous carrier of spherical montmorillonite provided by the invention.

In the above-mentioned process preparing support type benzenesulfonic acid catalyst, with total consumption of described carrier and benzenesulfonic acid for benchmark, the consumption of benzenesulfonic acid can be 1-50 weight %, it is preferred to 5-50 weight %；The consumption of described carrier can be 50-99 weight %, it is preferred to 50-95 weight %.Additionally, the mol ratio of described benzenesulfonic acid and water can be 1:15-35, it is preferred to 1:20-25.

Described spray drying can be implemented according to conventional mode, for instance can carry out in nebulizer.The condition of described spray drying may include that temperature is 100-300 DEG C, and the rotating speed of rotation can be 10000-15000r/min；Under preferable case, the condition of described spray drying includes: temperature is 150-250 DEG C, and the rotating speed of rotation is 11000-13000r/min.

Present invention also offers the support type benzenesulfonic acid catalyst prepared by above-mentioned spray drying method.

Present invention also offers the application in the esterification reaction of above-mentioned support type benzenesulfonic acid catalyst.

Additionally, the preparation method that present invention also offers a kind of ethyl acetate, wherein, the method includes: in the presence of a catalyst and when esterification, is contacted with ethanol by acetic acid, obtains ethyl acetate, wherein, described catalyst is above-mentioned support type benzenesulfonic acid catalyst.

There is no particular limitation to the consumption of described acetic acid and ethanol for the present invention, as long as ethyl acetate can be obtained by reacting, but in order to improve the utilization rate of raw material, it is preferable that in situation, the mol ratio of described acetic acid and ethanol is 1:0.5-10.

In addition, the present invention to the consumption of described support type benzenesulfonic acid catalyst also without special restriction, suitably can select according to the addition of acetic acid in course of reaction and/or ethanol, as a rule, acetic acid relative to 100 weight portions, the consumption of described support type benzenesulfonic acid catalyst can be 1-15 weight portion, it is preferred to 2-14 weight portion.

According to the present invention, the condition of described esterification is conventionally known to one of skill in the art, generally includes reaction temperature and response time.Wherein, in order to be more beneficial for the carrying out of esterification, described reaction preferably under reflux conditions carries out, i.e. described reaction temperature is reflux temperature.The prolongation in response time can improve the conversion ratio of reactant and the yield of product within the specific limits, but the response time long amplitude that reaction-ure conversion-age and product yield are improved is also inconspicuous, therefore, consider effect and efficiency, under preferable case, the described response time is 1-10 hour, more preferably 2-8 hour.

According to the present invention, under preferable case, the preparation method of described ethyl acetate is additionally included in after esterification terminates, final reactant mixture is carried out sucking filtration separation, and sucking filtration is separated solid product vacuum drying 1-24 hour at 25-200 DEG C obtained, preferably in vacuum drying at 50-120 DEG C 6-10 hour, to reclaim support type benzenesulfonic acid catalyst.

Hereinafter will be described the present invention by embodiment.

In following example, polyoxyethylene-poly-oxypropylene polyoxyethylene available from Aldrich Co, it is abbreviated as P123, molecular formula is EO₂₀PO₇₀EO₂₀, at the material that registration number is 9003-11-6 of U.S. chemical abstract, average molecular mass Mn is 5800.

In following example and comparative example, X-ray diffraction analysis carries out on the X-ray diffractometer that model is D8Advance purchased from BrukerAXS company of Germany；Scanning electron microscope analysis carries out in the scanning electron microscope that model is XL-30 of purchased from American FEI Co.；Pore structure parameter analysis carries out on the nitrogen adsorption desorption instrument that model is Autosorb-1 of purchased from American Kang Ta company, wherein, before testing, sample is degassed 4 hours at 200 DEG C；The analysis of product liquid phase ingredient is carrying out purchased from Agilent company of Britain 7890A/5973N gas chromatograph-mass spectrometer.

In following EXPERIMENTAL EXAMPLE and Experimental comparison's example, consumption × 100% of the conversion ratio (%) of acetic acid=(in the consumption-product of acetic acid the content of acetic acid) ÷ acetic acid；Theoretical yield × 100% of the actual production ÷ ethyl acetate of selectivity (the %)=ethyl acetate of ethyl acetate.

Embodiment 1

This embodiment is used for the composite mesoporous carrier of spherical montmorillonite provided by the invention and support type benzenesulfonic acid Catalysts and its preparation method are described.

(1) preparation of the composite mesoporous carrier of spherical montmorillonite

By 6g(0.001mol) triblock copolymer polyethylene glycol glycerol-Polyethylene Glycol (P123) is dissolved in 10mL, pH value is in 4 aqueous hydrochloric acid solutions and 220mL deionized water solution, at 15 DEG C, stir 4h to P123 dissolve, form clear solution, 6g(0.08mol is added again in described clear solution) n-butyl alcohol stirring 1h, then this solution is placed in the water-bath of 40 DEG C, by 12.9g(0.062mol) tetraethyl orthosilicate is slowly added dropwise in this solution, keep the temperature at 40 DEG C, when pH value is 4.5, stirring 24h, then again at 100 DEG C of Water Under heat treatment 24h, then deionized water cyclic washing is used 4 times after being filtered, then the meso-porous molecular sieve material filter cake with three-dimensional cubic duct structure is obtained after sucking filtration.

It is after 5:1 is mixed homogeneously by waterglass that concentration is 15 weight % and sulfuric acid solution that concentration is 12 weight % by waterglass and sulphuric acid weight ratio, reaction 2 hours it is stirred at 30 DEG C, and the sulphuric acid that product concentration is 98 weight % that obtains is adjusted pH is 3, then by reaction mass sucking filtration, be washed till sodium ions content with distilled water wash be 0.02 weight %, obtains silica gel filter cake.

The 10 of above-mentioned preparation grams of meso-porous molecular sieve material filter cakes, 10 grams of silica gel filter cakes and 5 grams of montmorillonites are put into together in 100mL ball grinder (wherein, ball grinder material is politef, Material quality of grinding balls is Achates, the diameter of abrading-ball is 3mm, quantity is 1, and rotating speed is 400r/min), closure ball grinding jar, in ball grinder, temperature is ball milling 1 hour at 60 DEG C, obtains 25 grams of pressed powders；This pressed powder is dissolved in 25 grams of deionized waters, is spray drying under 12000r/min at 200 DEG C, at rotating speed；Then the product obtained after spray drying is calcined 24 hours in the Muffle furnace of 500 DEG C, removed template method, obtain the composite mesoporous carrier of spherical montmorillonite in the target product three-dimensional cubic duct of 20 grams of removed template methods, called after C1.

(2) preparation of support type benzenesulfonic acid catalyst

At 25 DEG C of temperature, the above-mentioned composite mesoporous support C 1 of 20 grams of spherical montmorillonites is put in deionized water together with benzenesulfonic acid, stirring is to dissolving, and the weight ratio controlling the composite mesoporous carrier of spherical montmorillonite and benzenesulfonic acid is 50:50, the mol ratio of deionized water and benzenesulfonic acid is 25:1, then by the mixture that obtains at 200 DEG C of temperature, it is under 12000r/min, carry out spray drying at rotating speed, obtain the composite mesoporous carrier of spherical montmorillonite (i.e. support type benzenesulfonic acid catalyst) of load benzenesulfonic acid, called after Cat-1.

With XRD, scanning electron microscope and nitrogen adsorption desorption instrument, this composite mesoporous carrier of spherical montmorillonite and support type benzenesulfonic acid catalyst are characterized.

Fig. 1 is X-ray diffracting spectrum (XRD figure), wherein, a is the XRD spectra of the composite mesoporous carrier of spherical montmorillonite (C1), b is the XRD spectra of the composite mesoporous carrier of spherical montmorillonite (Cat-1) of the load benzenesulfonic acid obtained by spray drying method, and abscissa is 2 θ, and vertical coordinate is intensity.Can be seen that from the result of Fig. 1, in its medium and small angle XRD spectra, (211) of spherical montmorillonite composite mesoporous carrier (C1) sample in three-dimensional cubic duct, (220) and the diffraction maximum peak shape of (311) crystal face intact, the diffraction maximum peak shape of (211) crystal face of support type benzenesulfonic acid catalyst is intact, it was shown that the pore passage structure of the composite mesoporous carrier of the spherical montmorillonite (Cat-1) after load benzenesulfonic acid still can keep the continuous pore passage structure of three-dimensional cubic and have good order.

Fig. 2 is the scanning electron microscope (SEM) photograph of the microscopic appearance of the composite mesoporous carrier of spherical montmorillonite (C1), and as shown in Figure 2, the microscopic appearance of the composite mesoporous carrier of spherical montmorillonite (C1) is particle diameter is the Mesoporous Spheres of 20-50 μm.

Fig. 3 is the scanning electron microscope (SEM) photograph of the microscopic appearance of the composite mesoporous carrier of the spherical montmorillonite (Cat-1) of the load benzenesulfonic acid obtained by spray drying method.From the figure 3, it may be seen that keep spherical by the microscopic appearance of the composite mesoporous carrier of the spherical montmorillonite (Cat-1) of spray drying method load benzenesulfonic acid is still basic, particle diameter is 20-50 μm.

Fig. 4 is the pore size distribution curve figure of the composite mesoporous carrier of spherical montmorillonite (C1).From fig. 4, it can be seen that the pore-size distribution of this composite mesoporous carrier of spherical montmorillonite is bimodal distribution, and the most probable pore size of bimodal correspondence respectively 2-8 nanometer and 20-50 nanometer.

Fig. 5 is the pore size distribution curve figure of the composite mesoporous carrier of the spherical montmorillonite (Cat-1) in the three-dimensional cubic duct of the load benzenesulfonic acid obtained by spray drying method.From the result of Fig. 5 it can be seen that the pore-size distribution of the composite mesoporous carrier of spherical montmorillonite of this load benzenesulfonic acid is bimodal distribution, and the most probable pore size of bimodal correspondence respectively 2-8 nanometer and 20-50 nanometer.

Table 1 is the pore structure parameter of the composite mesoporous carrier of spherical montmorillonite (C1) and the composite mesoporous carrier of the spherical montmorillonite (Cat-1) of load benzenesulfonic acid.

Table 1

From the data of table 1 it can be seen that the composite mesoporous carrier of spherical montmorillonite is after load benzenesulfonic acid, specific surface area and pore volume all reduce to some extent, and this illustrates that benzenesulfonic acid enters into the inside of the composite mesoporous carrier of spherical montmorillonite in load-reaction process.

Comparative example 1

This comparative example is for illustrating the composite mesoporous carrier of spherical montmorillonite and the Catalysts and its preparation method of reference.

The composite mesoporous carrier of spherical montmorillonite and the preparation of support type benzenesulfonic acid catalyst is carried out according to the method for embodiment 1, the difference is that, in the preparation process of the composite mesoporous carrier of spherical montmorillonite, it is added without montmorillonite, obtains the composite mesoporous carrier of spherical montmorillonite (DC1) and support type benzenesulfonic acid catalyst (DCat-1) of reference.

Comparative example 2

This comparative example is for illustrating the composite mesoporous carrier of spherical montmorillonite and the Catalysts and its preparation method of reference.

The composite mesoporous carrier of spherical montmorillonite and the preparation of support type benzenesulfonic acid catalyst is carried out according to the method for embodiment 1, the difference is that, in the process preparing support type benzenesulfonic acid catalyst, do not include being dissolved in pressed powder in 25 grams of deionized waters, it is the step of spray drying under 12000r/min at rotating speed at 200 DEG C, but directly pressed powder is calcined 24 hours in the Muffle furnace of 500 DEG C, removed template method.Obtain the composite mesoporous carrier of the montmorillonite (DCat-2) of the composite mesoporous carrier of montmorillonite (DC2) and load benzenesulfonic acid.

Comparative example 3

This comparative example is for illustrating the composite mesoporous carrier of spherical montmorillonite and the Catalysts and its preparation method of reference.

The composite mesoporous carrier of spherical montmorillonite and the preparation of support type benzenesulfonic acid catalyst is carried out according to the method for embodiment 1, the difference is that, in the process preparing the composite mesoporous carrier of spherical montmorillonite, the bar-shaped mesoporous silicon oxide SBA-15 filter cake (commercially available from high-tech limited company of Changchun Jilin University) adopting identical weight part substitutes meso-porous molecular sieve material filter cake, obtains the composite mesoporous carrier of the spherical montmorillonite (DCat-3) of the composite mesoporous carrier of spherical montmorillonite (DC3) and load benzenesulfonic acid.

Embodiment 2

This embodiment is used for the composite mesoporous carrier of spherical montmorillonite provided by the invention and support type benzenesulfonic acid Catalysts and its preparation method are described.

(1) preparation of the composite mesoporous carrier of spherical montmorillonite

By 6g(0.001mol) triblock copolymer P123 is dissolved in 10mL, pH value be 5 aqueous hydrochloric acid solution and 220mL deionized water solution in, dissolve at stirring 4h to P123, form clear solution, 4.5g(0.06mol is added again in described solution) n-butyl alcohol stirring 1h, then this solution is placed in the water-bath of 45 DEG C, by 10.4g(0.05mol) tetraethyl orthosilicate is slowly added dropwise in this solution, keep the temperature at 45 DEG C, 48h is stirred when pH value is 5.5, then again at 80 DEG C of Water Under heat treatment 20h, then deionized water wash is used 4 times after being filtered, then the meso-porous molecular sieve material filter cake with three-dimensional cubic duct structure is obtained after sucking filtration.

It is after 4:1 is mixed homogeneously by waterglass that concentration is 15 weight % and sulfuric acid solution that concentration is 12 weight % by waterglass and sulphuric acid weight ratio, reaction 1.5 hours it is stirred at 40 DEG C, and the sulphuric acid that product concentration is 98 weight % that obtains is adjusted pH is 2, then by reaction mass sucking filtration, be washed till sodium ions content with distilled water wash be 0.02 weight %, obtains silica gel filter cake.

The 20 of above-mentioned preparation grams of mesoporous material filter cakes, 30 grams of silica gel filter cakes and 4 grams of montmorillonites are put into together in 100mL ball grinder (wherein, ball grinder material is politef, Material quality of grinding balls is Achates, the diameter of abrading-ball is 3mm, quantity is 1, and rotating speed is 300r/min), closure ball grinding jar, in ball grinder, temperature is ball milling 0.5 hour at 80 DEG C, obtains 54 grams of pressed powders；This pressed powder is dissolved in 27 grams of deionized waters, is spray drying under 11000r/min at rotating speed at 250 DEG C；Then the product obtained after spray drying is calcined 15 hours in the Muffle furnace of 550 DEG C, removed template method, obtain the composite mesoporous carrier of spherical montmorillonite in the target product three-dimensional cubic duct of 50 grams of removed template methods, called after C2.

(2) preparation of support type benzenesulfonic acid catalyst

At 25 DEG C of temperature, the above-mentioned composite mesoporous support C 2 of 30 grams of spherical montmorillonites is put in deionized water together with benzenesulfonic acid, stirring is to dissolving, and the weight ratio controlling the composite mesoporous support C 2 of spherical montmorillonite and benzenesulfonic acid is 95:5, the mol ratio of deionized water and benzenesulfonic acid is 22:1, then by the mixture that obtains at 150 DEG C of temperature, it is under 13000r/min, carry out spray drying at rotating speed, obtain the composite mesoporous carrier of spherical montmorillonite (i.e. support type benzenesulfonic acid catalyst) of load benzenesulfonic acid, called after Cat-2.

Table 2 is the pore structure parameter of spherical mesoporous montmorillonite complex carrier (C2) and the spherical mesoporous montmorillonite complex carrier (Cat-2) of load benzenesulfonic acid.

Table 2

From the data of table 2 it can be seen that spherical mesoporous montmorillonite complex carrier is after load benzenesulfonic acid, pore volume and specific surface area all reduce to some extent, it can be said that bright, and in load-reaction process, benzenesulfonic acid has entered into the inside of spherical mesoporous montmorillonite complex carrier.

Embodiment 3

This embodiment is used for the composite mesoporous carrier of spherical montmorillonite provided by the invention and support type benzenesulfonic acid Catalysts and its preparation method are described.

(1) preparation of the composite mesoporous carrier of spherical montmorillonite

By 6g(0.001mol) triblock copolymer P123 is dissolved in 10mL, pH value be 3 hydrochloric acid and 220mL deionized water solution in, stirring 4h to P123 dissolves, form clear solution, 6.75g(0.09mol is added again in described clear solution) n-butyl alcohol stirring 1h, then this solution is placed in the water-bath of 30 DEG C, and by 15.66g(0.075mol) tetraethyl orthosilicate is slowly added dropwise in this solution, keep the temperature at 30 DEG C, 72h is stirred when pH value is 3.5, then again at 40 DEG C of Water Under heat treatment 40h, then filter and with deionized water wash four times, then the meso-porous molecular sieve material filter cake with three-dimensional cubic duct structure is obtained after sucking filtration.

It is after 4:1 is mixed homogeneously by waterglass that concentration is 15 weight % and sulfuric acid solution that concentration is 12 weight % by waterglass and sulphuric acid weight ratio, reaction 3 hours it is stirred at 20 DEG C, adjusting pH followed by the sulphuric acid that concentration is 98 weight % is 4, then the reaction mass sucking filtration that will obtain, and to be washed till sodium ions content with distilled water wash be 0.02 weight %, obtain silica gel filter cake.

The 20 of above-mentioned preparation grams of mesoporous material filter cakes, 10 grams of silica gel filter cakes and 8 grams of montmorillonites are put into together in 100mL ball grinder (wherein, ball grinder material is politef, Material quality of grinding balls is Achates, the diameter of abrading-ball is 3mm, quantity is 1, and rotating speed is 500r/min), closure ball grinding jar, in ball grinder, temperature is ball milling 10 hours at 40 DEG C, obtains 38 grams of pressed powders；This pressed powder is dissolved in 11.4 grams of deionized waters, is spray drying under 13000r/min at rotating speed at 150 DEG C；Then the product obtained after spray drying is calcined 70 hours in the Muffle furnace of 450 DEG C, removed template method, obtain the target product composite mesoporous carrier of spherical montmorillonite of 35 grams of removed template methods, called after C3.

(2) preparation of support type benzenesulfonic acid catalyst

At 25 DEG C of temperature, above-mentioned 20 grams of composite mesoporous carriers of spherical montmorillonite are put in deionized water together with benzenesulfonic acid, stirring is to dissolving, and the weight ratio controlling the composite mesoporous carrier of spherical montmorillonite and benzenesulfonic acid is 85:15, the mol ratio of deionized water and benzenesulfonic acid is 20:1, then by the mixture that obtains at 250 DEG C of temperature, it is under 11000r/min, carry out spray drying at rotating speed, obtain the composite mesoporous carrier of spherical montmorillonite (i.e. support type benzenesulfonic acid catalyst) of load benzenesulfonic acid, called after Cat-3.

The pore structure parameter of the composite mesoporous support C of spherical montmorillonite 3 and support type benzenesulfonic acid catalyst Cat-3 is as shown in table 3 below.

Table 3

Sample	Specific surface area (m2/g)	Pore volume (ml/g)	Most probable pore size (nm)	Particle diameter (μm)
					C3	450	0.9	5.5,23	20-40
Cat-3	340	0.8	4.9,20	20-40

From the data of table 3 it can be seen that spherical mesoporous montmorillonite complex carrier is after load benzenesulfonic acid, pore volume and specific surface area all reduce to some extent, it can be said that bright, and in load-reaction process, benzenesulfonic acid has entered into the inside of spherical mesoporous montmorillonite complex carrier.

Embodiment 4

This embodiment is used for spherical mesoporous montmorillonite complex carrier provided by the invention and support type benzenesulfonic acid Catalysts and its preparation method are described.

Method according to embodiment 1 prepares spherical mesoporous montmorillonite complex carrier and support type benzenesulfonic acid catalyst, different, the process preparing support type benzenesulfonic acid catalyst does not have the step of spray drying, and only by impregnate method by benzenesulfonic acid load on spherical mesoporous montmorillonite complex carrier, thus prepare support type benzenesulfonic acid catalyst Cat-4.

Embodiment 5

This EXPERIMENTAL EXAMPLE is used for the preparation method that ethyl acetate provided by the invention is described.

By support type benzenesulfonic acid catalyst (Cat-1) vacuum drying 6 hours at 120 DEG C in embodiment 1, after being cooled to room temperature 25 DEG C, weigh 0.5 gram, it is sequentially placed in 100mL there-necked flask with 11.5 grams of ethanol and 15 grams of acetic acid, stir 3 hours under heated reflux condition, it is subsequently cooled to room temperature 25 DEG C and sucking filtration separates, utilize the liquid phase ingredient of gas chromatograph-mass spectrometer analytical reactions product, and by calculating the conversion ratio of acetic acid be and ethyl acetate selectivity.

Embodiment 6-8

Embodiment 6-8 is used for the preparation method that ethyl acetate provided by the invention is described.

Method according to embodiment 5 prepares ethyl acetate, institute the difference is that, replace described loaded catalyst Cat-1 with the embodiment 2-4 loaded catalyst prepared respectively.As a result, the conversion ratio of respective calculated acetic acid and ethyl acetate selective data are as shown in table 4 below.

Comparative example 4-6

Comparative example 4-6 is used for illustrating the reference preparation method of ethyl acetate.

Method according to embodiment 5 prepares ethyl acetate, institute the difference is that, replace described loaded catalyst Cat-1 with the comparative example 1-3 loaded catalyst prepared respectively.As a result, the conversion ratio of respective calculated acetic acid and ethyl acetate selective data are as shown in table 4 below.

Table 4

	Catalyst	The conversion ratio of acetic acid	Ethyl acetate selectivity
				Embodiment 5	Cat-1	99.9%	100%
Embodiment 6	Cat-2	99.5%	100%
				Embodiment 7	Cat-3	99.7%	100%
Embodiment 8	Cat-4	95.8%	100%
				Comparative example 4	DCat-1	91.7%	99%
Comparative example 5	DCat-2	91.5%	99%
				Comparative example 6	DCat-3	92.3%	99%

Embodiment 9-12 and comparative example 7-9

Method according to embodiment 5 prepares ethyl acetate, institute the difference is that, replace described loaded catalyst Cat-1 with from embodiment 5-8 and the comparative example 4-6 catalyst reclaimed respectively.As a result, the conversion ratio of respective calculated acetic acid and ethyl acetate selective data are as shown in table 5 below.

Table 5

	Catalyst	The conversion ratio of acetic acid	Ethyl acetate selectivity
				Embodiment 9	The Cat-1 reclaimed	99.1%	100%
Embodiment 10	The Cat-2 reclaimed	99.3%	99%
				Embodiment 11	The Cat-3 reclaimed	98.9%	100%
Embodiment 12	The Cat-4 reclaimed	96.5%	99%
				Comparative example 7	The DCat-1 reclaimed	85.0%	99%
Comparative example 8	The DCat-2 reclaimed	89%	98%
				Comparative example 9	The DCat-3 reclaimed	76.5%	99%

Be can be seen that by the data of table 4 and table 5, it is 20-50 micron that the preparation method adopting carrier provided by the invention can obtain average particulate diameter, specific surface area is 150-600 meters squared per gram, pore volume is 0.5-1.5 ml/g, pore-size distribution is bimodal distribution, and the most probable pore size of the described bimodal correspondence respectively 2-8 nanometer of composite mesoporous carrier of spherical montmorillonite with 20-50 nanometer.In addition, the catalytic performance of support type benzenesulfonic acid catalyst provided by the invention is better, when applying the esterification that this catalyst comes catalysis acetic acid and ethanol, there is higher acetic acid conversion and ethyl acetate selectivity, and support type benzenesulfonic acid catalyst provided by the invention can through and recovery and Reusability, and aftertreatment technology is simple.

The preferred embodiment of the present invention described in detail above; but, the present invention is not limited to the detail in above-mentioned embodiment, in the technology concept of the present invention; technical scheme can being carried out multiple simple variant, these simple variant belong to protection scope of the present invention.

It is further to note that each the concrete technical characteristic described in above-mentioned detailed description of the invention, in reconcilable situation, it is possible to be combined by any suitable mode.In order to avoid unnecessary repetition, various possible compound modes are no longer illustrated by the present invention separately.

Additionally, can also carry out combination in any between the various different embodiment of the present invention, as long as it is without prejudice to the thought of the present invention, it should be considered as content disclosed in this invention equally.

Claims (15)

1. the composite mesoporous carrier of spherical montmorillonite, it is characterized in that, the described composite mesoporous carrier of spherical montmorillonite contains montmorillonite and has the meso-porous molecular sieve material of three-dimensional cubic duct structure, and the mean diameter of the described composite mesoporous carrier of spherical montmorillonite is 20-50 micron, specific surface area is 150-600 meters squared per gram, and pore volume is 0.5-1.5 ml/g, and pore-size distribution is bimodal distribution, and the most probable pore size of described bimodal correspondence respectively 2-8 nanometer and 20-50 nanometer

The preparation method of the described composite mesoporous carrier of spherical montmorillonite comprises the following steps:

(1) under the existence of template and butanol, tetraethyl orthosilicate is contacted with acid agent, and the product after contact is carried out crystallization and filtration, obtain the filter cake with the meso-porous molecular sieve material of three-dimensional cubic duct structure；

(2) waterglass is contacted with mineral acid, and the product obtained after contact is filtered, obtain silica gel filter cake；

(3) filter cake of the described mesoporous material with three-dimensional cubic duct structure, described silica gel filter cake are mixed homogeneously and ball milling with montmorillonite, and spray drying will carry out after the pressed powder water slurrying obtained after ball milling, then by the described template removal in the product that obtains after spray drying.

2. carrier according to claim 1, wherein, relative to the meso-porous molecular sieve material described in 100 weight portions with three-dimensional cubic duct structure, the content of described montmorillonite is 1-50 weight portion.

3. carrier according to claim 2, wherein, relative to the meso-porous molecular sieve material described in 100 weight portions with three-dimensional cubic duct structure, the content of described montmorillonite is 20-50 weight portion.

4. carrier according to claim 1, wherein, in step (3), with the consumption of the filter cake of the meso-porous molecular sieve material described in 100 weight portions with three-dimensional cubic duct structure for benchmark, the consumption of described silica gel filter cake is 1-200 weight portion；The consumption of described montmorillonite is 1-50 weight portion.

5. carrier according to claim 4, wherein, in step (3), with the consumption of the filter cake of the meso-porous molecular sieve material described in 100 weight portions with three-dimensional cubic duct structure for benchmark, the consumption of described silica gel filter cake is 50-150 weight portion；The consumption of described montmorillonite is 20-50 weight portion.

6. carrier according to claim 1, wherein, in step (1), the mol ratio of described template, butanol and tetraethyl orthosilicate is 1:10-100:10-90.

7. carrier according to claim 6, wherein, in step (1), the mol ratio of described template, butanol and tetraethyl orthosilicate is 1:60-90:50-75.

8. the carrier according to any one in claim 1,6 and 7, wherein, described template is triblock copolymer polyoxyethylene-poly-oxypropylene polyoxyethylene；Described acid agent is hydrochloric acid.

9. the carrier according to any one in claim 1,6 and 7, wherein, the condition that tetraethyl orthosilicate contacts with acid agent includes: temperature is 10-60 DEG C, and the time is 10-72 hour, and pH value is 1-7；The condition of described crystallization includes: temperature is 30-150 DEG C, and the time is 10-72 hour.

10. carrier according to claim 1, wherein, in step (2), the condition that waterglass contacts with mineral acid includes: temperature is 10-60 DEG C, and the time is 1-5 hour, and pH value is 2-4；Described mineral acid is one or more in sulphuric acid, nitric acid and hydrochloric acid.

11. carrier according to claim 1, wherein, in step (3), the condition of described ball milling includes: the rotating speed of abrading-ball is 300-500r/min, and the temperature in ball grinder is 15-100 DEG C, and the time of ball milling is 0.1-100 hour；The condition of described spray drying includes: temperature is 100-300 DEG C, and rotating speed is 10000-15000r/min；The condition of removed template method includes: temperature is 300-600 DEG C, and the time is 10-80 hour.

12. a support type benzenesulfonic acid catalyst, it is characterised in that this catalyst includes in claim 1-11 the composite mesoporous carrier of spherical montmorillonite described in any one and load benzenesulfonic acid on the described composite mesoporous carrier of spherical montmorillonite.

13. the preparation method of a support type benzenesulfonic acid catalyst, it is characterised in that the method includes the composite mesoporous carrier of spherical montmorillonite described in any one in claim 1-11, benzenesulfonic acid and water mix homogeneously, and the mixture obtained is carried out spray drying.

14. the application that the support type benzenesulfonic acid catalyst described in claim 12 is in the esterification reaction.

15. the preparation method of an ethyl acetate, the method includes: in the presence of a catalyst and when esterification, is contacted with ethanol by acetic acid, obtains ethyl acetate, it is characterized in that, described catalyst is the support type benzenesulfonic acid catalyst described in claim 12.