JP2008212772A - Solid catalyst for manufacturing bio-diesel oil and manufacturing method of the catalyst - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a solid catalyst suitable for manufacturing of bio-diesel oil from raw fat and oil, and a manufacturing method of the catalyst. <P>SOLUTION: The solid catalyst is calcium diglyceroxide obtained by reacting a raw material of calcium oxide with a specific basic strength and an amount of base, or calcium hydroxide obtained by hydrating the calcium oxide, with a methanol solution of glycerol in a heated circulating flow, or calcium methoxide obtained by reacting the raw material with methanol in a heated circulating flow, the calcium methoxide having a surface area of 40m<SP>2</SP>/g or more. The surface of a carrier of the catalyst is coated with calcium diglyceroxide or calcium methoxide. The carried type catalysts are obtained by fixation of calcium carbonate by a carbon dioxide combining method or impregnating and fixation of calcium acetate followed by firing. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a solid catalyst (solid catalyst for biodiesel oil production) suitable for producing biodiesel oil (BDF) from raw oil and fat, and a method for producing the solid catalyst.

Biodiesel oil, which is extremely important for reducing the emissions of greenhouse gases and air pollutants and building an “energy-recycling society”, is obtained by the alcoholysis reaction of various triacylglycerides that make up the fats and oils.
The “alkali hydroxide method” using alkali hydroxide as a catalyst is described in, for example, Patent Documents 1 and 2 below. In such a method, alkali is mixed into the produced biodiesel oil. Therefore, water washing purification becomes indispensable and a large amount of alkaline waste water is generated. In addition, by-product glycerin is also strongly alkaline and requires a large amount of cost for its disposal. Furthermore, in the case of this method, the product is emulsified due to the formation of soap, so that the separation operation is difficult, and since the production apparatus is a batch operation method, the reaction efficiency is low and the operation is complicated. There was also a problem.
US Pat. No. 2,380,944 JP-A-7-197047

  Therefore, in order to solve these problems, the present inventors proposed a solid catalytic reaction method using highly active calcium oxide obtained by a special preparation operation in WO 2006/134845. According to the present invention, biodiesel oil can be produced with the same reaction efficiency as in the case of using alkali hydroxide, with greatly reduced alkali contamination. However, in consideration of the load on the diesel engine, it is preferable to remove the calcium content remaining in the generated biodiesel oil with an adsorbent or the like. In Western countries, the content of inorganic components such as calcium is standardized to be 200 to 300 ppm or less based on its sulfate.

An object of the present invention is to provide a solid catalyst suitable for producing a higher-quality biodiesel oil with a small amount of inorganic content and a method for producing the solid catalyst.
As a result of studies on mixing of calcium content, the present inventors have found that highly active calcium oxide reacts with glycerin produced as a by-product in the reaction field for biodiesel production and changes to calcium diglyceroxide. It has been found that it acts as an active catalyst. It was also found that water was by-produced during the reaction of calcium oxide and glycerin, and this promoted the mixing of calcium into the produced biodiesel oil. The cause of the promotion of calcium contamination by by-product water is not clear, but it is presumed that the increase in the polarity of the liquid phase increased the dispersibility of the ionic crystalline calcium compound in the liquid. Based on this result, the present inventors have proposed the present invention characterized in that calcium oxide is reacted with glycerin in advance to be converted into calcium diglyceroxide and used as a reaction after removing by-product water. Thereby, mixing of the calcium to the biodiesel oil to produce | generate was able to be reduced significantly.

The solid catalyst for producing biodiesel oil of the present invention is a solid catalyst used when producing biodiesel oil by transesterification of raw material fats and alcohol, and the catalyst has a base strength (H_) of 9. One of three or more calcium oxides or calcium hydroxide obtained by hydrating the calcium oxide is used as a raw material, and calcium disulfide obtained by reacting the raw material with a methanol solution of glycerin under heating and refluxing. It is characterized by being glyceroxide.
In the specification of the present application, “base strength (H_)” that determines the catalytic activity represents an acid dissociation index (pKa) indicating a discoloration point (change from acidic color to basic color) of Hammett reagent, The solid base that changes the color of phenolphthalein with pKa = 9.3 evaluates that the base strength exceeds 9.3 which is the pKa of phenolphthalein, and “base strength (H_) 9.3 or higher” It is written.

Moreover, the solid catalyst for producing biodiesel oil of the present invention is a solid catalyst used in producing biodiesel oil by transesterification of raw material fat and alcohol, and the catalyst has a base strength (H_). Calcium methoxide obtained by using 9.3 or more calcium oxide or calcium hydroxide obtained by hydrating the calcium oxide as a raw material and reacting the raw material with methanol under heating and refluxing The surface area of the calcium methoxide is 40 m ² / g or more.

Furthermore, the present invention is a solid catalyst used in producing biodiesel oil by transesterification of raw material fats and alcohol, and the catalyst has calcium methoxide or calcium diglyceroxide on the surface of a carrier material. It is also characterized by being a coated composite material.

Furthermore, this invention is a manufacturing method of the solid catalyst used when manufacturing biodiesel oil by transesterification with raw material fats and alcohol, Comprising: The said method is the following processes A and B:
Process A: Base strength (H_) 9.3 is prepared by preparing a catalyst raw material selected from the group consisting of quicklime, calcium carbonate, calcium acetate, and slaked lime, and firing the catalyst raw material in an inert gas atmosphere. Obtaining the above calcium oxide,
Step B: The method includes a step of reacting the calcium oxide obtained in Step A with a methanol solution of glycerin or a mixed solution of vegetable oil and methanol with heating under reflux to obtain calcium diglyceroxide.

Further, the present invention provides the step B in the above-described method for producing a solid catalyst, wherein the calcium oxide is reacted with water to form calcium hydroxide and then heated to reflux with a methanol solution of glycerin or a mixture of vegetable oil and methanol. It is made to react under, and it is also characterized by obtaining calcium diglyceroxide.

Furthermore, this invention is a manufacturing method of the solid catalyst used when manufacturing biodiesel oil by transesterification with raw material fats and alcohol, Comprising: The said method is the following processes A and B ':
Process A: Base strength (H_) 9.3 is prepared by preparing a catalyst raw material selected from the group consisting of quicklime, calcium carbonate, calcium acetate, and slaked lime, and firing the catalyst raw material in an inert gas atmosphere. Obtaining the above calcium oxide,
Step B ′: The method includes a step of obtaining calcium methoxide having a surface area of 40 m ² / g or more by reacting the calcium oxide obtained in Step A with methanol under heating and reflux.

In the step B ′ in the method for producing a solid catalyst according to the present invention, the calcium oxide is reacted with water to form calcium hydroxide and then reacted with methanol under heating and reflux to obtain calcium methoxide. It is also characterized by this.

Furthermore, the present invention is a method for producing a solid catalyst for the production of biodiesel oil in which the surface of a support material is coated with calcium methoxide or calcium diglyceroxide,
After preparing these mixed water slurries with a composition in which the molar ratio of the carrier substance and calcium hydroxide is 4 or more, carbon dioxide gas is blown into the slurry, and the above-mentioned carrier substance is produced without generating non-immobilized bulk particles. Immobilization is performed in several times so that calcium carbonate is deposited on the surface with a layer thickness of 2.5 μm or more, and then the composite material coated with calcium carbonate is taken out from the mixed water slurry, and the obtained composite material Is fired under an inert gas atmosphere to obtain a composite material whose surface is coated with calcium oxide, and the composite material is further heated under reflux with methanol, a mixed solution of vegetable oil and methanol, or a methanol solution of glycerin. To obtain a composite material whose carrier surface is coated with calcium methoxide or calcium diglyceroxide. To.

The present invention also provides a method for producing a solid catalyst for producing biodiesel oil in which the surface of a carrier material is coated with calcium methoxide or calcium diglyceroxide,
A carbonaceous material is selected as the carrier material, and calcium acetate, calcium nitrate, or calcium hydroxide is impregnated with the aqueous solution or alcohol solution to be immobilized on the carrier material, and the resulting composite material is inert gas. By firing in an atmosphere to obtain a composite material whose surface is coated with calcium oxide, and further reacting the composite material with methanol, a mixed solution of vegetable oil and methanol, or a methanol solution of glycerin with heating under reflux The present invention is characterized in that a composite material whose carrier surface is coated with calcium methoxide or calcium diglyceroxide is obtained.

  High-quality biodiesel oil with less residual inorganic content can be obtained while giving a reaction performance comparable to that when using highly active calcium oxide.

(1) Preparation of calcium diglyceroxide according to the present invention In the present invention, calcium oxide or calcium hydroxide obtained by hydrating this calcium oxide is used as a raw material, and this raw material is heated with a methanol solution of glycerin. Calcium diglyceroxide (Ca (C ₃ H ₇ O ₃ ) ₂ ) obtained by the reaction under reflux is used as a catalyst for producing biodiesel. The raw material calcium oxide is obtained by the method described in WO2006 / 134845. The obtained base strength of 15.0 or more and the base amount of 0.1 mmol / g or more are preferable for improving the preparation efficiency, but those having a base strength of 9.3 or more whose surface is slightly poisoned can be used. . Calcium oxide having such physical properties can be obtained by firing a raw material selected from the group consisting of quick lime, calcium carbonate and slaked lime in an inert gas atmosphere (step A). If the inert gas used in this step A is a high-purity specification that has a carbon dioxide concentration of 1 ppm or less and does not substantially contain water, it is more preferable as a catalyst raw material, with a base strength of 15.0 or more and a base amount of 0. A calcium oxide of 1 mmol / g or more is obtained. Although it is possible in the present invention to use calcium hydroxide as a raw material, in this case, the production rate of calcium diglyceroxide is slow, and if the surface of calcium hydroxide is carbonated, the production rate is slower. It must be noted that Glycerin and methanol used in the reaction are preferably those having a low water content, and reagent-grade grades (water content of 0.1 wt% or less) are desirable. The glycerin may be 100% glycerin.

In the next step B, the above methanol solution of calcium oxide and glycerin is charged into a container equipped with a cooling condensation tube for steam generated by heating and heated. The reaction temperature is in the vicinity of the boiling point of methanol (approximately 65 ° C.) by balancing the generation and condensation of methanol vapor by heating. The outlet of the cooling condensing tube is preferably open to the atmosphere and provided with a fluid sealing mechanism. Moreover, it is preferable to distribute | circulate inert gas, such as nitrogen gas, at the time of a heating. The reaction between calcium oxide and glycerin is carried out for 2 hours or more under stirring. The reaction operation may be carried out by either a batch system or a distribution system.
After the reaction, the powdered solid product is separated and recovered from the remaining solution by an operation such as filtration, and a drying operation is performed to remove water adhering to the product. Of calcium diglyceroxide catalyst ". The calcium diglyceroxide catalyst for producing biodiesel oil of the present invention leads to effective utilization of glycerin, which is a by-product of biodiesel oil production.

In the present invention, in the above-described catalyst production method, calcium diglyceroxide obtained by reacting a mixed solution of vegetable oil and methanol with calcium oxide under heating reflux can be used as a catalyst for biodiesel production. In this case, glycerin is produced by the transesterification reaction (biodiesel production reaction) of vegetable oil and methanol, and this reacts with the raw material to obtain calcium diglyceroxide. An edible grade is desirable, and oil types such as soybean oil, rapeseed oil and palm oil are not limited. This catalyst production method is useful as an alternative method when it is difficult to prepare glycerin in advance.

(2) Preparation of calcium methoxide according to the present invention In the present invention, calcium oxide having a base strength of 9.3 or more is prepared as a raw material (step A), and the raw material is reacted with methanol under heating and reflux (step). B ′), calcium methoxide (Ca (OCH ₃ ) ₂ ) having a surface area of 40 m ² / g or more, obtained as a catalyst for biodiesel production, can be used. Calcium hydroxide obtained by hydration can also be used as a raw material.
As a result of examining the influence of methanol coexisting in the reaction field when investigating the mechanism of conversion to calcium diglyceroxide in the reaction field for biodiesel production, the present inventors have produced a reaction by the reaction of calcium oxide and methanol. It has been found that calcium methoxide also exhibits high catalytic activity as a stable chemical species. Calcium methoxide has been conventionally known to be an active catalyst for biodiesel production reaction (for example, Non-Patent Document 1 below). However, what was obtained by reaction of metallic calcium and methanol was used, and had a difficulty in catalyst preparation compared with this invention. Since calcium metal is highly reactive in the atmosphere and may ignite, it must be handled with great care. On the other hand, in the present invention, since calcium oxide with high safety is handled, handling is extremely easy. Obtaining calcium methoxide from calcium oxide and methanol is also described in the past literature, but since it is a reaction at room temperature, the surface area of the obtained calcium methoxide is extremely small (2 m ² ) for a long time for preparation. / G), utilization as a “catalyst” is not assumed at all (for example, Non-Patent Document 2 below). On the other hand, in the present invention, since the reaction is carried out under heating and reflux, the obtained calcium methoxide has a large surface area (40 m ² / g), which causes high activity. Therefore, in the present invention, one of the characteristics is that calcium methoxide having a high surface area obtained by reacting calcium oxide and methanol under heating and refluxing is used as a catalyst. In addition, since it produces | generates a water | moisture content also when calcium methoxide produces | generates, it is indispensable to remove this.
S. Gryglewicz, Bioresources Technology, 70 (1999) 249-253 Yasuo Arai et al., Journal of the Chemical Society of Japan, 9 (1981) 1402-1408

(3) Preparation of supported catalyst of the present invention using reaction of calcium hydroxide and CO _{2 In} the present invention, as a catalyst that can be mounted in a reaction apparatus, a composite in which calcium diglyceroxide or calcium methoxide is immobilized on a carrier material Material is also proposed. Such a composite material is excellent in moldability, and separation of the catalyst and the product in the reaction apparatus becomes extremely easy. In the immobilization of the catalyst substance, the porosity and surface chemical properties of the support substance act as anchor forces, so that an effect of suppressing the calcium content in the biodiesel oil is expected.
The present inventors have found that calcium oxide, which is a precursor of calcium diglyceroxide and calcium methoxide, easily reacts with general carrier substances such as silica and alumina, and is inactive during the firing operation in the pretreatment step of the composite material. Clarified the disadvantage of forming calcium silicate and aluminum silicate. In order to compensate for this, it has been conceived that a large amount of a calcium compound as a catalyst precursor is supported on the surface of the support material, and the active component particles remain at the expense of the calcium compound in the vicinity of the surface. However, when such a composite material is prepared by a normal impregnation operation, many bulk particles that are not immobilized on the carrier substance are generated. Therefore, a method for easily immobilizing a large amount of catalyst precursor (calcium oxide) on a support material has been developed by utilizing an industrial technique for producing fine particles of calcium carbonate by blowing carbon dioxide into calcium hydroxide. According to this method, only the raw material composition (carrier substance / calcium hydroxide molar ratio) is controlled, and by repeating the immobilization operation a plurality of times, calcium carbonate is deposited on the surface of the carrier substance with a layer thickness of 2.5 μm or more. Thus, a precursor of a mounting catalyst that exhibits high activity is obtained. In this case, calcium carbonate is immobilized in a multilayer state on the surface of the carrier material, and those close to the carrier material become inactive compounds upon firing, but a part of them remains as calcium oxide. Here, when the number of repetitions of the fixing operation is small and the calcium carbonate layer thickness is less than 2.5 μm, all of the calcium oxide on the surface of the carrier reacts with the carrier substance to generate an inactive compound (FIG. 1). reference). In addition, if calcium oxide is fixed by a single operation without considering the raw material composition, the rate at which heterogeneous nucleation occurs on the surface of the carrier decreases, so the generation of bulk particles due to uniform nucleation increases. More non-immobilized particles.

The calcium hydroxide used for the raw material should have a purity of 95% or more. Calcium hydroxide having the same purity may be prepared and reacted with water before the reaction with CO ₂ to obtain calcium hydroxide. The water may be of the same grade as ion exchange water. CO ₂ having a purity of 100% may be supplied, but industrially, it is generally supplied after being diluted with an inert gas such as nitrogen (CO ₂ concentration is about 30%). The support material for immobilizing calcium carbonate produced by the reaction of calcium hydroxide and CO ₂ is not particularly limited, and general silica or alumina can be used as an industrial catalyst support. It should be noted here that the molar ratio of the carrier substance to calcium hydroxide is 4 or more, which limits the amount of calcium carbonate produced and immobilizes all the produced calcium carbonate to the carrier substance. . When the molar ratio is less than 4, as shown in FIG. 1, bulk particles are generated, and complete fixation of the uniformly dispersed catalyst precursor cannot be achieved.

Of the above raw materials, calcium hydroxide and a carrier substance are dispersed in water in a metal or resin open-air container. This container is provided with a jacket through which a temperature adjusting fluid can be passed, and has a nozzle for blowing CO ₂ gas at the bottom. A water slurry in which calcium hydroxide and a carrier substance are dispersed is adjusted to a temperature of 18 ° C. or lower with stirring, and then CO ₂ is blown into the slurry. The amount of CO ₂ blown is such that the contact speed with calcium hydroxide is 0.6 mol / (mol · min) or more. The reaction between calcium hydroxide and CO ₂ can be controlled by pH. From the beginning of the reaction to the end of the reaction, the pH gradually decreases from about 12 to about 11, and then rapidly decreases to about 7, and then settles at 7.5 to 8. If the pH is settled, the reaction between calcium hydroxide and CO ₂ is complete. It should be noted that the layer thickness of calcium carbonate deposited on the surface of the support material must be 2.5 μm or more by repeating the immobilization operation a plurality of times.

Thereafter, the coated calcium carbonate / carrier substance-coated composite material obtained by the above operation is fired to convert the immobilized calcium carbonate into calcium oxide as a catalyst precursor. The firing operation at this time is performed in an inert gas atmosphere. As in WO2006 / 134845, it is preferable to use an inert gas having a CO ₂ concentration of 1 ppm or less and substantially free of moisture because the preparation efficiency is high. The firing temperature is 750 ° C. or higher, and calcium oxide cannot be obtained by firing at 750 ° C. or lower. The fired composite material is reacted with glycerin or methanol to convert calcium oxide into calcium diglyceroxide or calcium methoxide. The solid catalyst for producing biodiesel oil of the present invention thus obtained exhibits activity in the biodiesel production reaction.

(4) Preparation of supported catalyst according to the present invention using a carbonaceous material as a support material If a carbonaceous material is selected as the support material, it is impregnated with calcium acetate, calcium nitrate or calcium hydroxide in the form of an aqueous solution or an alcohol solution. By doing so, it can be immobilized on a carrier substance. The carbonaceous material impregnated with the calcium compound is then fired at a temperature of 750 ° C. or higher under a flow of inert gas to form a composite material whose surface is coated with calcium oxide. A carbonaceous material coated with calcium methoxide or calcium diglyceroxide obtained by reacting with a vegetable oil-methanol mixture or a methanol solution of glycerin with heating under reflux is used as a catalyst for biodiesel production.
Since the carbonaceous material that is the support material does not react with the calcium oxide of the catalyst precursor even at high temperatures, a small amount of calcium compound is used as the support material of the catalyst precursor by an impregnation operation that is a known simple technique. Can be fixed. As the carbonaceous material, carbon black, activated carbon or the like can be used.
The firing operation is performed in an inert gas atmosphere. Similar to WO 2006/134845, it is more preferable to use an inert gas having a CO ₂ concentration of 1 ppm or less and substantially free of moisture. The firing temperature varies depending on the calcium compound used as a raw material, and is 750 ° C. or higher for calcium acetate, 450 ° C. or higher for calcium hydroxide, and 600 ° C. or higher for calcium nitrate. The fired composite material is reacted with glycerin or methanol to convert calcium oxide into calcium diglyceroxide or calcium methoxide.

I. Catalytic performance of calcium diglyceroxide and calcium methoxide (1) Catalyst preparation <Catalyst A> 1.40 g of calcium carbonate fine particles (surface area 10 m ² / g) obtained by the reaction of calcium hydroxide and CO ₂ were converted into high purity helium. While circulating gas (Taiyo Nissan: CO ₂ concentration 1 ppm or less, dew point -70 ° C. or less) in a stainless steel tubular reactor (inner diameter 30 mm × length 600 mm), firing at 900 ° C. for 1.5 hours. Obtained calcium oxide. The amount produced was 0.78 g, and it was confirmed by the indicator method that the base strength was 15.0 or higher and 18.4 or lower and the base amount was 0.15 mmol / g. The surface area was 13 m ² / g.
<Catalyst B> 0.78 g of the same calcium oxide as described above was reacted with 150 ml of a glycerin methanol solution (glycerin concentration of 50 wt%, both of which are Wako Pure Chemical reagent special grades) in a nitrogen gas atmosphere for 2 hours under heating and refluxing conditions. The obtained powdery solid particles. From the powder X-ray diffraction measurement result, the generated powdery solid particles were identified as calcium diglyceroxide. The surface area was 10 m ² / g.
<Catalyst C> Obtained by reacting 0.78 g of the above calcium oxide with a mixed liquid of 100 ml of vegetable oil and 50 ml of methanol (both Wako Pure Chemicals reagent special grade) in a nitrogen gas atmosphere for 2 hours under heating and refluxing conditions. Powdered solid particles. From the powder X-ray diffraction measurement result, the generated powdery solid particles were identified as calcium diglyceroxide. The surface area was 11 m ² / g.
<Catalyst D> Powdered solid particles obtained by reacting 0.78 g of the above calcium oxide with 100 ml of methanol (special grade product manufactured by Wako Pure Chemical Industries, Ltd.) in a nitrogen gas atmosphere for 2 hours under heating and refluxing conditions. From the powder X-ray diffraction measurement result, the generated powdery solid particles were identified as calcium methoxide. The surface area was 44 m ² / g.

(2) Evaluation of catalyst performance For each of the above catalysts A to D, the total amount (0.56 g in calcium content) after each preparation was combined with 100 ml of soybean oil (special grade product made by Wako Pure Chemical) and 50 ml of methanol, Pyrex (registered trademark) glass. The product was charged into a batch reactor (internal volume 500 ml). About catalyst B, C, D, the water | moisture content which remained on the catalyst surface was removed by vacuum-drying at 90 degreeC for 4 hours before using for reaction. The soybean oil used is of an edible grade having a water content of 0.01 wt% or less and an acid value of 0.1 mg-KOH / g or less. After charging the raw material oil, catalyst, etc., the reactor was heated while being stirred, and the reaction was carried out by maintaining the reflux state for 2 hours. After the reaction, the product was taken out, the glycerol was removed from the specific gravity difference in the stationary layer, the catalyst particles suspended by filtration were removed, and a sample liquid for obtaining the production rate of fatty acid methyl ester as biodiesel oil was obtained. . The production rate of fatty acid methyl ester (FAME) was calculated from the results of gas chromatographic analysis.
The amount of calcium mixed in the produced biodiesel oil was quantified by ICP-AES analysis after extracting calcium content by a wet method.
The results are shown in Table 1 below.

[Table 1]
Table 1 Catalytic performance of calcium diglyceroxide and calcium methoxide


FAME catalyst in oil
Production rate [%] Recovery rate Calcium content
0.5h 1.0h 2.0h [wt%] [ppm]
Catalyst A Calcium oxide 73 92 98 81 187
Catalyst B Calcium diglyceroxide 56 70 87 88 41
(Reaction with glycerin)
Catalyst C Calcium diglyceroxide 60 72 86 88 44
(Reaction with vegetable oil)
Catalyst D Calcium methoxide 15 24 61 87 54

(3) Results From the experimental results in Table 1, it can be seen that all of the catalysts A to D are active in the transesterification reaction between soybean oil and methanol that produce biodiesel oil. Although the catalyst D made of calcium methoxide has a slightly lower activity than others, it can be judged that it can be compensated by increasing the amount of the catalyst in actual production.
Here, paying attention to the calcium content mixed in the produced biodiesel oil, the catalyst A composed of calcium oxide had a concentration of 187 ppm. On the other hand, in catalysts B and C made of calcium diglyceroxide, the amount of calcium mixed in the produced biodiesel oil is about 40 ppm, and the calcium content is significantly reduced as compared with catalyst A. These are 130 to 140 ppm in terms of sulfated ash, and can meet the strict quality standards of Western countries. Further, the catalyst D composed of calcium methoxide also reduced the calcium content to 54 ppm (equivalent to 180 ppm in terms of sulfated ash).
From the above results, it was found that by using the production method of the present invention, high-quality biodiesel oil with less calcium content can be produced with a reaction efficiency comparable to that of highly active calcium oxide.

II. Effect of calcium diglyceroxide / methoxide supported catalyst (1) Catalyst preparation <Catalyst E> 1.85 g of calcium hydroxide (special grade of Wako Pure Chemical reagent: purity 96 wt%) and silica powder as a carrier material (manufactured by Fuji Silysia) 12.0 g of (surface area 470 m ² / g, particle size 53 μm) (carrier substance / calcium hydroxide molar ratio = 8), using 2 L of distilled water in a 3 L stainless steel cylindrical container with a bottom nozzle Dispersed. Thereafter, cooling water was supplied to the container jacket while stirring at 400 rpm, and the temperature of the dispersed slurry in the container was adjusted to 18 ° C. After the temperature adjustment CO 2 _- nitrogen mixed gas (CO ₂ concentration: 30%) of 3.3 L / min was supplied from the bottom of the container nozzle, it was initiated calcium carbonate fine particles immobilizing operation to silica. After confirming that the pH of the slurry was lowered and the formation of calcium carbonate was completed, 1.85 g of calcium hydroxide was added to the slurry, and a second immobilization operation was performed. This immobilization operation was repeated two more times (layer thickness: 2.8 μm).
After performing the immobilization operation four times in total, the powdered solid in the slurry was collected by filtration, and the moisture was removed by vacuum drying at 90 ° C. for 4 hours. The powdered solid after drying is calcined at 900 ° C. for 1.5 hours in a helium atmosphere substantially free of moisture with a CO ₂ concentration of 1 ppm or less, and calcium carbonate immobilized on a silica support is obtained. Converted to calcium oxide. This calcium oxide was reacted with glycerin in the same manner as the above catalyst B to obtain a silica-supported calcium diglyceroxide catalyst for biodiesel production reaction. (Surface area: 37 m ² / g).
<Catalyst F> To 10 g of activated carbon “Carborafine” (powder, 1560 m ² / g) manufactured by Nippon Envirochemical, 3.2 g of calcium acetate tetrahydrate (special grade product manufactured by Wako Pure Chemical Industries, Ltd., purity 99 wt%) (30 ml) Impregnated with distilled water. After impregnation, moisture was removed by drying under reduced pressure at 90 ° C. for 4 hours. Thereafter, firing and the subsequent reaction with glycerin were carried out in the same manner as for catalyst E to obtain a carbon-supported calcium diglyceroxide catalyst for biodiesel production reaction. (Surface area: 71 m ² / g)

(2) Evaluation of catalyst performance The same operation as the above "catalyst performance of calcium diglyceroxide and calcium methoxide" was performed on the catalysts E and F in an amount corresponding to a calcium content of 0.56 g.
The results are shown in Table 2 below.

[Table 2]


Table 2 Performance of supported calcium diglyceroxide catalyst
FAME in oil
Production rate [%] Calcium
0.5h 1.0h 2.0h [ppm]
Catalyst E Calcium diglyceroxide / silica 84 88 98 26
(Calcium carbonate, precipitation method)
Catalyst F Calcium diglyceroxide / activated carbon 91 94 97 19
(Calcium acetate, impregnation method)
Catalyst B Calcium diglyceroxide 56 70 87 41

(3) Results In Table 2, the performance of the catalysts E and F is compared with the catalyst B. In both cases, the catalyst material is calcium diglyceroxide. It can be seen that Catalysts E and F are more active than Catalyst B in the transesterification reaction of soybean oil and methanol. This is presumably because fine catalyst material particles could be immobilized on the support material, and there were more surfaces effective for the reaction than catalyst B which is bulk particles.
Further, the calcium content mixed in the produced biodiesel was 26 ppm for catalyst E and 19 ppm for catalyst F, which was less than that of bulk particle catalyst B. This is presumably because the anchor force of the catalyst substance increased due to the porosity and chemical properties of the support surface.
From the above results, the immobilization on the support material was not only advantageous for the preparation of the mounting type catalyst, but also effective in reducing the calcium content in the produced biodiesel and improving the activity.

III. Effect of catalyst surface area (Catalyst D)
(1) Catalyst preparation <Catalyst D-1> 1008 of methanol and 0.78 g of calcium oxide used as a precursor of the catalyst D were mixed in a glass flask with a sealed stopper, and after nitrogen gas was sealed, the mixture was shaken for 24 hours. Thereafter, the powdered solid recovered through filtration was identified by X-ray diffraction measurement to be a mixture of calcium methoxide and calcium hydroxide. The surface area was 1.8 m ² / g. This was designated as “catalyst D-1” and compared with catalyst D comprising calcium methoxide having a high surface area obtained by the reaction of calcium oxide and methanol in a heated reflux state.
(2) Evaluation of catalyst performance The same operation as the above "catalytic performance of calcium diglyceroxide and calcium methoxide" was performed.
(3) Results Catalyst D composed of calcium methoxide having a surface area exceeding 40 m ² / g produced a FAME production rate of 61% in a reaction for 2 hours, but catalyst D-1 having a surface area of about 2 m ² / g was The activity was very low and only 12% of FAME was produced after 2 hours of reaction.
From the above, it was confirmed that a highly active catalyst for biodiesel oil production reaction can be provided by the present invention in which calcium oxide and methanol are reacted in a heated reflux state to obtain a high surface area calcium methoxide of 40 m ² / g. It was.

IV. Influence of Immobilization Operation of Catalyst E (1) Catalyst Preparation <Catalyst E-1> About the composite material in which calcium carbonate is immobilized on the silica surface by blowing CO ₂ into an aqueous slurry in which calcium hydroxide and silica are dispersed. 3.7 g of calcium hydroxide and 12 g of silica were dispersed with 2 L of distilled water, and a CO ₂ -nitrogen mixed gas was blown at a flow rate of 3.3 L / min. After confirming that all of the calcium hydroxide was changed to calcium carbonate from the change in pH, 3.7 g of calcium hydroxide was added again and the same operation was performed. As a result, a composite material having the same calcium content as that of the catalyst E (repetition of the immobilization operation 4 times) was obtained (calcium carbonate layer thickness: about 2.5 μm). The composite material is subjected to calcination in a helium atmosphere at a CO ₂ concentration of 1 ppm or less in a helium atmosphere at 900 ° C. for 1.5 hours and a reaction with glycerin to provide a catalyst “E -1 "was obtained.
<Catalyst E-2> 7.4 g of calcium hydroxide and 12 g of silica are dispersed in 2 L of distilled water, and a CO ₂ -nitrogen mixed gas is blown at a flow rate of 6.6 L / min to immobilize calcium carbonate on the silica surface. This operation was performed only once, and a composite material having the same calcium content as that of the above-mentioned catalyst E (immobilization operation repeated 4 times) was obtained. This was converted into a catalyst “E-2” to be subjected to a biodiesel production reaction through calcination similar to the above and subsequent reaction with glycerin. (Calcium carbonate layer thickness: about 1.7 μm, bulk particles are generated)
<Catalyst E-3> For 1.40 g of calcium carbonate obtained by blowing 3.3 L / min CO ₂ -nitrogen mixed gas into an aqueous slurry in which 7.4 g of calcium hydroxide is dispersed, the same as above Firing and subsequent reaction with glycerin were performed to prepare calcium diglyceroxide. This was mixed with 1.68 g of silica that had been fired in the same manner as described above to obtain catalyst “E-3”.
<Catalyst E-4> Although it was a calcium carbonate / silica composite material prepared by the same method as that for catalyst E, the repetitive operation in immobilizing calcium carbonate was stopped in three times. As a result, a sample (calcium carbonate layer thickness: about 2.2 μm) in which the calcium content was three-fourths of the catalyst E was obtained. This was converted into catalyst “E-4” to be subjected to biodiesel production reaction through the same calcination as described above and subsequent reaction with glycerin.
<Catalyst E-5> Although it is the calcium carbonate / silica composite material prepared by the same method as Catalyst E, the number of repeated operations in immobilizing calcium carbonate was increased to 6 times. As a result, a sample (calcium carbonate layer thickness: about 3.4 μm) having a calcium content 1.5 times that of the catalyst E was obtained. This was converted into catalyst “E-5” to be subjected to biodiesel production reaction through the same calcination as described above and subsequent reaction with glycerin.

(2) Evaluation of catalyst performance In order to compare the activities of the catalysts E-1 to E-5 with those of the catalyst E, the same operation as the above "catalyst performance of calcium diglyceroxide and calcium methoxide" was performed. In each catalyst, an amount corresponding to 0.56 g in terms of calcium content was used.
The results are shown in Table 3 below.

[Table 3]
Table 3 Effect of calcium carbonate fixation on catalyst performance

FAME
Generation rate [%]
Molar ratio 0.5h 1.0h 2.0h

Catalyst E SiO2 / Ca (OH) 2 = 8, repeated 4 times 84 88 98
Catalyst E-1 SiO2 / Ca (OH) 2 = 4, repeated twice 65 81 97
Catalyst E-2 SiO2 / Ca (OH) 2 = 2, only once 2 5 13
Catalyst E-3 Physical mixing of catalyst components and support 5 10 19
Catalyst E-4 SiO2 / Ca (OH) 2 = 8, repeated 3 times 4 8 17
Catalyst E-5 SiO2 / Ca (OH) 2 = 8, repeated 6 times 86 91 97
* Both catalysts are calcium diglyceroxide / SiO2 composite materials

(3) Results From Table 3 above, the catalyst E obtained by repeating the immobilization operation four times under the condition of silica / calcium hydroxide molar ratio = 8 shows a FAME production rate of 80% after 0.5 hour reaction. It is over. The catalyst E-1 prepared by lowering the silica / calcium hydroxide molar ratio to 4 also exhibits sufficient activity although the FAME production rate is slightly lower than that of the catalyst E. On the other hand, the catalyst E-2 (silica / calcium hydroxide molar ratio = 2) in which the immobilization with calcium hydroxide was completed by only one operation had a FAME production rate of less than 10%. The reason for this is suggested by the result of catalyst E-3. The catalyst E-3 is a physical mixture of calcium diglyceroxide and silica, and there are many bulk particles of calcium diglyceroxide that are not coated with silica. This catalyst E-3 also had a very low FAME production rate. When calcium diglyceroxide is present as bulk particles, it is considered that negative interaction with silica worked and the catalytic activity was lowered. The reason why the activity of the catalyst E-2 was low was probably because there were many bulk particles of calcium diglyceroxide that were not immobilized, and the particle structure was very similar to that of the catalyst E-3.
Catalyst E-4 also had a very low activity compared to catalyst E. This is presumably because although calcium carbonate was uniformly fixed, the calcium carbonate layer was thin because of repeated operations three times, and there were few particles remaining as a catalyst precursor (calcium oxide) after firing. Catalyst E-5 in which the number of repeated operations was increased to 6 times had a higher FAME production rate than Catalyst E.
From the above, in the case where calcium carbonate is immobilized on a carrier material using the reaction of calcium hydroxide and CO ₂ and a catalyst is prepared through a reaction with calcination and subsequent glycerin, the carrier material / calcium hydroxide mole The immobilization operation for generating calcium carbonate at a ratio of 4 or more is repeated a plurality of times, and the thickness of the calcium carbonate layer on the support surface needs to be 2.5 μm or more.

V. Effect of catalyst carrier species (1) Catalyst preparation <Catalyst F-1> To 10 g of the same silica as the catalyst E carrier, 30 ml of calcium acetate tetrahydrate (special grade, manufactured by Wako Pure Chemical Industries, Ltd., purity 99 wt%), 3.2 g Impregnated with distilled water. Thereafter, the same operation as in the preparation of the catalyst F was performed to obtain a silica-supported catalyst (catalyst F-1).
<Catalyst F-2> To 10 g of γ-alumina (catalytic conversion property, surface area of 300 m ² / g), 30 g of 3.2 g of calcium acetate tetrahydrate (special grade product manufactured by Wako Pure Chemical Industries, purity 99 wt%) was distilled. Impregnated with water. Thereafter, the same operation as in the preparation of the catalyst F was performed to obtain an alumina-supported catalyst (catalyst F-2).

(2) Evaluation of catalyst performance The activities of the catalysts F-1 and F-2 were evaluated by the same operation as the above "catalytic performance of calcium diglyceroxide and calcium methoxide". In each catalyst, an amount corresponding to 0.56 g in terms of calcium content was used.

(3) Results FAME was not produced at all even when the catalysts F-1 and F-2 were reacted for 2 hours. This is presumably because when calcium acetate impregnated on the surface of the carrier was converted to calcium oxide by firing, all of it reacted with the carrier substance to become an inactive compound.
Therefore, it was clear that a carbonaceous material such as activated carbon had to be selected in order to obtain a supported calcium glyceroxide catalyst by a known simple technique.

The solid catalyst of the present invention is useful for efficiently producing biodiesel oil that can meet quality standards already applied in Western countries by transesterification of raw oil and fat and alcohol. Further, by using the production method of the present invention, a highly active solid catalyst suitable for efficiently producing high quality biodiesel oil can be produced.

(1) When the molar ratio of the carrier substance and calcium hydroxide is 4 or less, (2) When the molar ratio of the carrier substance and calcium hydroxide is 4 or more, and the number of repetitions of the immobilization operation is 1, (3) It is a conceptual diagram which shows the structure of the product (composite material) after baking obtained in each case where the molar ratio of a support | carrier substance and calcium hydroxide is 4 or more and the frequency | count of immobilization operation is 2 times or more.

Claims (9)

A solid catalyst used in producing biodiesel oil by transesterification of raw material fats and alcohol, wherein the catalyst is calcium oxide having a base strength (H_) of 9.3 or more, or the calcium oxide is water. Biodiesel oil characterized in that it is calcium diglyceroxide obtained by reacting any one of the calcium hydroxides obtained by summing with a methanol solution of glycerin under heating and refluxing Solid catalyst for production. A solid catalyst used in producing biodiesel oil by transesterification of raw material fats and alcohol, wherein the catalyst is calcium oxide having a base strength (H_) of 9.3 or more, or the calcium oxide is water. A calcium methoxide obtained by reacting any one of the calcium hydroxides obtained as a raw material and reacting the raw material with methanol under heating reflux, and the surface area of the calcium methoxide is 40 m ² / g. A solid catalyst for the production of biodiesel oil characterized by the above. A solid catalyst used in producing biodiesel oil by transesterification of raw oil and alcohol with a composite material in which calcium methoxide or calcium diglyceroxide is coated on the surface of a carrier substance A solid catalyst for producing biodiesel oil, characterized in that A method for producing a solid catalyst used in producing biodiesel oil by transesterification of a raw material fat and alcohol, the method comprising the following steps A and B:
Process A: Base strength (H_) 9.3 is prepared by preparing a catalyst raw material selected from the group consisting of quicklime, calcium carbonate, calcium acetate, and slaked lime, and firing the catalyst raw material in an inert gas atmosphere. Obtaining the above calcium oxide,
Step B: Biodiesel comprising the step of obtaining calcium diglyceroxide by reacting the calcium oxide obtained in Step A with a methanol solution of glycerin or a mixed solution of vegetable oil and methanol with heating under reflux A method for producing a solid catalyst for oil production. In the step B, the calcium oxide is reacted with water to form calcium hydroxide and then reacted with a methanol solution of glycerin or a mixed solution of vegetable oil and methanol under heating to obtain calcium diglyceroxide. The manufacturing method of the solid catalyst for biodiesel oil manufacture of Claim 4. A method for producing a solid catalyst used in producing biodiesel oil by transesterification of a raw material fat and alcohol, which method comprises the following steps A and B ′:
Process A: Base strength (H_) 9.3 is prepared by preparing a catalyst raw material selected from the group consisting of quicklime, calcium carbonate, calcium acetate, and slaked lime, and firing the catalyst raw material in an inert gas atmosphere. Obtaining the above calcium oxide,
Step B ′: a biodiesel oil comprising a step of obtaining calcium methoxide having a surface area of 40 m ² / g or more by reacting the calcium oxide obtained in Step A with methanol under heating and refluxing A method for producing a solid catalyst for production. The biodiesel oil according to claim 6, wherein in the step B ', the calcium oxide is reacted with water to form calcium hydroxide and then reacted with methanol under heating and reflux to obtain calcium methoxide. A method for producing a solid catalyst for production. A method for producing a solid catalyst for the production of biodiesel oil in which calcium methoxide or calcium diglyceroxide is coated on the surface of a carrier material,
After preparing these mixed water slurries with a composition in which the molar ratio of the carrier substance and calcium hydroxide is 4 or more, carbon dioxide gas is blown into the slurry, and the above-mentioned carrier substance is produced without generating non-immobilized bulk particles. Immobilization is performed in several times so that calcium carbonate is deposited on the surface with a layer thickness of 2.5 μm or more, and then the composite material coated with calcium carbonate is taken out from the mixed water slurry, and the obtained composite material Is fired under an inert gas atmosphere to obtain a composite material whose surface is coated with calcium oxide, and the composite material is further heated under reflux with methanol, a mixed solution of vegetable oil and methanol, or a methanol solution of glycerin. To obtain a composite material whose carrier surface is coated with calcium methoxide or calcium diglyceroxide. Method of producing a biodiesel oil producing solid catalysts. A method for producing a solid catalyst for the production of biodiesel oil in which calcium methoxide or calcium diglyceroxide is coated on the surface of a carrier material,
A carbonaceous material is selected as the carrier material, and calcium acetate, calcium nitrate, or calcium hydroxide is impregnated with the aqueous solution or alcohol solution to be immobilized on the carrier material, and the resulting composite material is inert gas. By firing in an atmosphere to obtain a composite material whose surface is coated with calcium oxide, and further reacting the composite material with methanol, a mixed solution of vegetable oil and methanol, or a methanol solution of glycerin with heating under reflux A method for producing a solid catalyst for producing biodiesel oil, characterized in that a composite material whose carrier surface is coated with calcium methoxide or calcium diglyceroxide is obtained.