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Title:
PROCESS FOR PREPARING AN ALKYLESTER OF FATTY ACID WITH HIGH PURITY VIA ONE-STEP CONTINUOUS PROCESS
Document Type and Number:
WIPO Patent Application WO/2003/066567
Kind Code:
A1
Abstract:
The present invention relates to a process for preparing an alkylester of fatty acid with high purity via one-step continuous process by reacting an animal fat and/or vegetable oil with a lower alcohol in the presence of alkali catalyst by passing through a continuous tubular reactor while maintaining a single-phase, removing residual lower alcohol from the reaction mixture and removing residual glycerin, catalyst, etc. by phase separation. In accordance with the present invention, an alkylester of fatty acid can be produced with a high yield of 97% or more via one-step continuous process in a continuous tubular reactor without any limitation in flow types by reacting an animal fat and/or vegetable oil with a lower alcohol in the presence of alkali catalyst and carrying out a simple separating process.

Inventors:
YOO JEONG-WOO (KR)
Application Number:
PCT/KR2002/000629
Publication Date:
August 14, 2003
Filing Date:
April 09, 2002
Export Citation:
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Assignee:
NEO ENERGY KOREA CO LTD (KR)
YOO JEONG-WOO (KR)
International Classes:
C07C67/03; C07B61/00; C07C67/48; C07C67/58; C07C69/22; C11C3/10; (IPC1-7): C07C67/48; C07C67/03; C07C69/24; C11C3/10
Foreign References:
EP0391485A11990-10-10
US4668439A1987-05-26
US5849939A1998-12-15
JPH10182518A1998-07-07
Attorney, Agent or Firm:
Lee, Han-young (Seowon Bldg. 1675-1 Seocho-don, Seocho-gu 137-070 Seoul, KR)
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Claims:
WHAT IS CLAIMED IS:
1. A process for preparing an alkylester of fatty acid with high purity, which comprises the steps of: (i) mixing an animal fat and/or vegetable oil with a lower alcohol in the presence of alkali catalyst to give a singephase, reacting the mixture in onestep continuous tubular reactor while maintaining the singephase, to obtain a reaction mixture of alkylester of fatty acid, glycerin, lower alcohol and catalyst ; (ii) removing residual lower alcohol from the reaction mixture obtained in (i); and, (iii) separating the mixture obtained in (ii) into a layer of alkylester of fatty acid and a glycerin layer containing glycerin and catalyst, removing residual glycerin layer to prepare an alkylester of fatty acid.
2. The process for preparing an alkylester of fatty acid with high purity of claim 1, which further comprises a step of removing insoluble solid materials from the alkylester of fatty acid obtained in Step (iii).
3. The process for preparing an alkylester of fatty acid with high purity of claim 1 or 2, wherein the animal fat and/or vegetable oil is soybean oil, rape oil, sunflower seed oil, castor oil, corn oil, palm oil, beef tallow or mixture thereofs.
4. The process for preparing an alkylester of fatty acid with high purity of claim 1 or 2, wherein the alkali catalyst is metal hydroxide such as potassium hydroxide (KOH), sodium hydroxide (NaOH), lithium hydroxide (LiOH), rubidium hydroxide (RbOH) or cesium hydroxide (CsOH); metal alkoxide such as sodium methoxide (CH30Na), potassium ethoxide (CH3CH20Na), potassium methoxide (CH30K), potassium ethoxide (CH3CH20K), lithium methoxide (CH30Li), lithium ethoxide (CH3CH2OLi) ; multivalent metal alkoxide such as dibutoxidedibutyl tin (C16H3602Sn), tin butoxide (C16H3604Sn), titanium butoxide (C16H3604Ti), zirconium butoxide (C16H3604Zr), titanium propoxide (C12H2804Ti), zirconium propoxide (C12H2804Zr), titanium ethoxide (C8H2004Ti) zirconium ethoxide (C8H2004Zr), titanium methoxide (C4H1204Ti) ; or, ammonium hydroxide of tetrabutylammonium hydroxide ([CH3 (CH2) 2CH2] 4NOH).
5. The process for preparing an alkylester of fatty acid with high purity of claim 1 or 2, wherein the alkali catalyst is employed in a range of 0.1 to 10% (w/w) of animal fat and/or vegetable oil.
6. The process for preparing an alkylester of fatty acid with high purity of claim 1 or 2, wherein the lower alcohol is methylalcohol, ethylalcohol, propylalcohol, n butylalcohol, 2ethylalcohol, or mixture thereofs.
7. The process for preparing an alkylester of fatty acid with high purity of claim 1 or 2, wherein the lower alcohol is employed in a molar ratio of 6 to 60 times as much as animal fat and/or vegetable oil.
8. The process for preparing an alkylester of fatty acid with high purity of claim 1 or 2, wherein the pressure and temperature are maintained in the ranges of 1 to 10 atm and 60 to 150°C, respectively, to subject a mixture to a state of singlephase and react the mixture while maintaining the singlephase in Step (i).
9. The process for preparing an alkylester of fatty acid with high purity of claim 1 or 2, wherein the mixing of an animal fat and/or vegetable oil and alkali catalyst in a lower alcohol in Step (i) is carried out by using a blender equipped with stirring bar.
10. The process for preparing an alkylester of fatty acid with high purity of claim 1, wherein the removal of residual lower alcohol in Step (ii) is carried out by distillation.
11. The process for preparing an alkylester of fatty acid with high purity of claim 2, wherein the removal of insoluble solid materials is carried out by using a centrifuge.
Description:
"PROCESS FOR PREPARING AN ALKYLESTER OF FATTY ACID WITH HIGH PURITY VIA ONE-STEP CONTINUOUS PROCESS" BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to a process for preparing an alkylester of fatty acid with high purity via one-step continuous process, more specifically, to a process for preparing an alkylester of fatty acid with high purity via one-step continuous process by reacting an animal fat and/or vegetable oil with a lower alcohol in the presence of alkali catalyst by passing through a continuous tubular reactor while maintaining a single-phase, removing residual lower alcohol from the. reaction mixture and removing residual glycerin, catalyst, etc. by phase separation.

Description of the Prior Art In general, alkylester of fatty acid is prepared by reacting an animal fat and/or vegetable oil with a lower alcohol in the presence of a homogeneous catalyst of strong base such as sodium hydroxide or strong acid such as sulfuric acid.

As a conventional process using a homogeneous catalyst of strong acid, German Patent No. 1, 909, 434 discloses transesterification between methylacetate and butylalcohol in the presence of a catalyst of concentrated sulfuric acid at a temperature of 95 C to 105C. Harrington has also reported the transesterification reaction, in which vegetable oil from sunflower seed is mixed with 100 or more molar ratio of methanol and reacted in the presence of a catalyst of concentrated sulfuric acid for 3 to 4 hours, to produce methylester of fatty acid with a yield of

40.7% (see: Harrington, Ind. Eng. Chem. Prod. Res. Dev., 1985,24 : 314-318).

Meanwhile, transesterification using a homogeneous catalyst of strong base has been also reported in the art (see: B. Freedman, J. A. O. C. S. , 1984,61 (10): 1638-1643): for example, European Patent No. 301,634 teaches a process for preparing ester using a hydrophilic strong base catalyst such as KOH, K2CO3 and NaOH, inter alia, a process for preparing ester using a catalyst of strong base became commercially available owing to its higher reaction rate than that of using acid catalyst.

In a commercial process employing a catalyst of strong base, animal fat and/or vegetable oil are diluted in a lower alcohol which is several or dozens times as much as oil, then reacted in the presence of a catalyst of sodium hydroxide for 1 to 10 hours to produce a mixture of alkylester of fatty acid and glycerin. And then, a layer of alkylester of fatty acid and a glycerin layer are separated in a separating tower, the glycerin layer is subsequently neutralized with sulfuric acid and the catalyst is removed by way of precipitation and filtration, a filtered solution is transferred to a distillating tower and the lower alcohol is removed by distillation to give glycerin, and the layer of alkylester of fatty acid is washed several times with water, finally to produce alkylester of fatty acid in a drying tower. The said process is not satisfactory in the senses that: the efficiency and productivity are not good since most of the steps using a hydrophilic homogeneous catalyst of base are carried out in separate batch reactors ; and, the reactivity is not good because of the high hydrophilicity of catalyst and the low miscibility of catalyst with an animal fat and/or vegetable oil. To solve these problem, needs for continuous process for preparing an alkylester of fatty acid and the development of catalyst improved in terms of reactivity have been continued in the art.

As an example of continuous process for preparing an

alkylester of fatty acid, Austrian Patent No. PJ 1105/88 (1988) discloses two-step continuous process, in which two continuous stirred tank reactors are linked in a serial manner: methylester of fatty acid is first obtained by mixing an animal fat and/or vegetable oil, methylalcohol and catalyst in the first reactor and a glycerin layer containing catalyst and lower alcohol is removed, and then methylalcohol and catalyst are added and reacted in the second reactor to produce methylester of fatty acid with a yield of 97%. In the said process, reaction is initiated under a condition that oil and methylalcohol form two-phase of liquid/liquid, and the reaction system is changed to a single-phase by the production of diglyceride and monoglyceride, and converted to two-phase again with the increase in the concentrations of hydrophilic glycerin and lipophilic alkylester of fatty acid.

In carrying out the process, vigorous stirring is essential at the beginning and end of the reaction due to the extremely high solubility of catalyst in a hydrophilic material, and a powerful blender should be provided in the reactor to prevent the decrease in the reaction rate or the production yield because most catalyst and significant amount of methanol are dissolved in the glycerin layer.

Furthermore, transesterification is reversible even in a case the reactants are mixed well, which leads the two- phase reaction to reach to an equilibrium state in a range of yield of 80 to 90%, therefore, transesterification with two or more steps is essentially required. As a consequence, although the afore-mentioned process is a continuous process firstly introduced for preparing an alkylester of fatty acid, there are drawbacks that the process is complicated and requires two steps, and the reaction rate is low and large facilities are accompanied, because large amount of catalyst and methylalcohol are transferred to the glycerin layer due to the nature of two- phase reaction.

Under the circumstances, efforts for improving the

reactivity of catalyst in a continuous process have been continuously made in the art: for example, French Patent No.

1,583, 583 discloses a process using Na metal catalyst instead of alkali catalyst, and US Patent No. 3,853, 315 teaches transesterification of vegetable oil by using Na and K.

Particularly, WO 91/05034, EP 409 177 and DE 3925514 by Henkel Inc. a German company, suggest a process for preparing an alkylester of fatty acid with high yield by ranging the catalyst in a layer of lipophilic methylester using a catalyst of sodium methoxide, which is highly soluble in lipophilic material, while preventing the decrease in the efficiency of catalyst and the yield of process. The said process practically realized a yield of about 85% in the first reactor at a temperature of 100C or below, and yield of 98% in total through the second reactor after the removal of glycerin and the addition of alcohol and catalyst, by using a multi-step continuous tubular reactor with two or more serially linked continuous tubular reactors and facilities for separating glycerin and supplying lower alcohol and catalyst between the reactors, and by employing alcohol/oil in a molar ratio of 4.5 to 7. 5.

The said patents have contributed to a yield increase at the latter part of reaction through controlling the migration of catalyst into the glycerin layer by using a catalyst of sodium methoxide. However, a flow rate in the continuous tubular reactor should be required to maintain Reynold's number of above 2300 to minimize the decrease in catalytic efficiency while increasing the mixing power in the continuous tubular reactor due to the two-phase nature of the reaction system. And, two-step reactor for transesterification should be further provided to prepare the alkylester of fatty acid with high yield.

Recently, the usage of high-purity alkylester of fatty acid, inter alia, methylester of fatty acid as bio- diesel has been rapidly increased. To pass the revelent European standard, the purity of methylester of fatty acid

for bio-diesel should be more than 96.5%, which naturally motivated the studies on a process for preparing a methylester of fatty acid with a high yield of 96.5% or more. For example, Japanese patent laid-open publication No. 10-182518 discloses a process for preparing methylester of fatty acid with a yield of 96.5% via one-step process from decayed edible oil, in which the molar ratio of alcohol/oil is controlled in a range of 4.3 to 6.6, and reaction is carried out for 15 min by using a catalyst of sodium hydroxide. However, the said process has revealed shortcomings that: the yield is highly dependent on the flow rate, since the process is performed via two-phase reaction; and, high-purity alkylester of fatty acid cannot be produced in a continuous tubular reactor without special techniques.

Under the circumstances, there are strong reasons for exploring and developing a process for preparing an alkylester of fatty acid with high purity by employing a continuous tubular reactor via one-step continuous process.

SUMMARY OF THE INVENTION The present inventors have made an effort to develop a process for preparing an alkylester of fatty acid with high purity via one-step continuous process, and found that an alkylester of fatty acid with a high purity of 98% or more can be prepared via one-step continuous process by reacting an animal fat and/or vegetable oil with a lower alcohol in the presence of alkali catalyst by passing through a continuous tubular reactor while maintaining a single-phase.

A primary object of the present invention is, therefore, to provide a process for preparing an alkylester of fatty acid with high purity via one-step continuous process.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 depicts a diagram showing a process for preparing an alkylester of fatty acid via one-step continuous process of the present invention *Explanation of symbols in the major parts of Figure* 0-heat exchanger ... booster pump @-blender @ continuous tubular reactor t) evaporator -separating apparatus DETAILED DESCRIPTION OF THE INVENTION A process for preparing an alkylester of fatty acid with high purity of the present invention comprises the steps of: (i) mixing an animal fat and/or vegetable oil with a lower alcohol in the presence of alkali catalyst to give a singe-phase, reacting the mixture in one-step continuous tubular reactor while maintaining the singe-phase, to obtain a reaction mixture of alkylester of fatty acid, glycerin, lower alcohol and catalyst; (ii) removing residual lower alcohol from the reaction mixture obtained in (i); and, (iii) separating the mixture obtained in (ii) into a layer of alkylester of fatty acid and a glycerin layer containing glycerin and catalyst, removing residual glycerin layer to prepare an alkylester of fatty acid.

The process for preparing an alkyester of fatty acid with high purity, if necessary, may further comprise a step of removing insoluble solid materials from the alkylester of fatty acid obtained in Step (iii).

The process for preparing an alkylester of fatty acid is further illustrated, in more detail, in accordance with the steps as followings.

Step 1: Transesterification via one-step continuous tubular reaction An animal fat and/or vegetable oil is mixed with alkali catalyst dissolved in a lower alcohol to give a single-phase, and the mixture is reacted in one-step continuous tubular reactor while maintaining the single- phase to obtain a reaction mixture of alkylester of fatty acid, glycerin, lower alcohol and catalyst: The animal fat and/or vegetable oil includes soybean oil, rape oil, sunflower seed oil, castor oil, corn oil, palm oil, beef tallow and mixture thereofs, where C8~C30 saturated or unsaturated fatty acids such as stearic acid, oleic acid, linoleic acid, linolenic acid, palmitic acid, myristic acid, arachidic acid and lauric acid are present in a form of mono-, di-or triglyceride, linked to glycerin.

The lower alcohol includes methylalcohol, ethylalcohol, propylalcohol, n-butylalcohol, 2-ethylalcohol and mixture thereofs. The amount of lower alcohol, as one of parameters to give a single-phase, is controlled preferably in a range of 6 to 60 times (in molar ratio) as much as the animal fat and/or vegetable oil. Less than 6 times and more than 60 times of alcohol are not preferable, since the former lowers a conversion ratio of oil to ester and the latter requires more energy to separate lower alcohol after reaction.

The alkali catalyst is used in a range of 0.1 to 10% (w/w) of the animal fat and/or vegetable oil, preferably 0.3 to 3% (w/w), which includes metal hydroxide such as potassium hydroxide (KOH), sodium hydroxide (NaOH), lithium hydroxide (LiOH), rubidium hydroxide (RbOH) or cesium hydroxide (CsOH); metal alkoxide such as sodium methoxide (CH30Na), sodium ethoxide (CH3CH2ONa), potassium

methoxide (CH30K), potassium ethoxide (CH3CH20K), lithium methoxide (CH30Li), lithium ethoxide (CH3CH2OLi) ; multivalent metal alkoxide such as dibutoxide-dibutyl tin (C16H3602Sn), tin butoxide (Cl6H3604Sn), titanium butoxide (C16H3604Ti), zirconium butoxide (C16H3604Zr), titanium propoxide (C12H2804Ti), zirconium propoxide (C12H2804Zr), titanium ethoxide (C8H2004Ti), zirconium ethoxide (C8H2004Zr), titanium methoxide (C4H1204Ti) ; and, ammonium hydroxide of tetrabutylammonium hydroxide ([CH3 (CH2) 2CH2] 4NOH).

In carrying out the present invention, mixing and reacting of the reactants should be made at a temperature range of 60 to 150C, depending on the amount of used alcohol. The temperature is preferably maintained above 70C in a soybean oil/methylalcohol reaction system.

Though high reaction temperature is required to maintain a high reaction rate in a completely mixed state, it is not preferred for the reaction temperature to exceed 150 C which may cause detrimental problems in terms of carbonization and saponification of fat and/or oil.

In carrying out the present invention, a pressure should be maintained in a range of 1 to 10 atm for preventing alcohol from evaporation and maintaining a single-phase of reactants. The higher the pressure is, the easier the single-phase is made. However, it is preferable that the pressure is maintained to the minimum required for preventing the evaporation of alcohol and maintaining the single-phase at a certain temperature since much higher pressure increases the working expenses.

In carrying out the present invention, the major parameters for subjecting reactants and a reaction mixture to a state of single-phase includes a ratio of lower alcohol to animal fat and/or vegetable oil, temperature and pressure. After selecting a reaction temperature, the amount of lower alcohol is determined, which is necessary for initiation of reaction and preventing the phase separation of reaction products, i. e. , alkylester of fatty acid and glycerin. Practically, the amount of residual

lower alcohol necessary for preventing the phase separation is determined based on three-phase solubility curve of three materials, i. e. , alkylester of fatty acid, glycerin and alcohol, and from which the total amount of alcohol to alkylester of fatty acid is determined. The amount of alcohol used at a certain temperature is changed depending on the kind of alcohol, and ranges in a molar ratio of 6 or more to animal fat and/or vegetable oil, preferably in a range of 10 or more. For example, in case of methanol/soybean oil reaction system, the molar ratio of methanol to soybean oil should be 25.5 or more at 60C, and 14.7 or more at 80C, respectively. The pressure should be maintained in a range of 1 to 10 atm to prevent lower alcohol from evaporation at a certain temperature and a certain amount of lower alcohol.

Transesterification of the present invention is made in a single-phase unlike prior art. The reaction of an animal fat and/or vegetable oil and a lower alcohol is carried out via a novel reaction mechanism : 1) alkali catalyst is linked to ester group of fat and/or oil, which is relatively more acidic than the lower alcohol, to give an intermediate with increased reactivity; and, 2) transesterification between alcohol and reactive ester group of oil is followed (see: Reaction Scheme 1).

Reaction Scheme 1 In accordance with the conventional process, where phase separation takes place at the beginning and end of reaction, the reaction is carried out via formation of alkoxide between lower alcohol and alkali catalyst and transesterification between alkoxide and ester. In the prior art, since the alkali catalyst is dissolved only in a hydrophilic component, the reaction is made only in an interface between the two phases. Accordingly, at the beginning of, reaction, the catalyst exists only in a layer of lower alcohol, and the reaction rate abruptly drops without vigorous stirring, and long reaction time is required in a tubular reactor with low mixing efficiency and catalyst and lower alcohol are migrated to a layer of glycerin produced at the end of the reaction, which, in turn, results in a decrease in the concentrations of catalyst and lower alcohol needed to be reacted. As a consequence, high-yield of alkylester of fatty acid cannot be realized in the prior art.

The present invention successfully solved the said problems caused by two-phase reaction through the transesterification employing a single-phase reaction mechanism shown in Reaction Scheme 1.

In accordance with the present invention, besides the aspects of catalytic efficiency, an improvement in terms of yield can be accomplished by minimizing the reverse reaction by three alcohol groups of glycerin, by way of blocking the phase separation of alkylester of fatty acid and glycerin. That is, in a case that hydrophilic glycerin with three polar alcohol groups is forced to be mixed with lipophilic phase, the glycerin, due to rare polar groups in the vicinity of the molecule, forms pseudo-ring depicted in chemical formula (I), which lowers its polarity, and decreases reverse reaction.

That is, only oxygen 0 of glycerin, in the lipophilic environment, has a reactivity, which decreases the number of alcohol groups in the glycerin molecule capable of driving reverse reaction. Further, the reactivity can be decreased compared with primary alcohol or alcohol groups of glycerin in hydrophilic phase, because the hydrogen of alcohol group of glycerin can be linked to adjacent oxygen in the same molecule by hydrogen bond. Accordingly, the reverse reaction of glycerin and alkylester of fatty acid can be minimized, which, in turn, makes it possible to produce alkylester of fatty acid with a high yield of 97% or more even in one-step process.

Transesterification in the present invention preferably proceeds in a continuous tubular reactor, without accompanying phase separation, which provides an excellent mixing nature even in a continuous tubular

reactor with poor mixing efficiency. Accordingly, in comparison with German Patent No. 3925514, which requires to maintain a turbulent flow of above Reynold's number 2300 to maximize the mixing of reactants in a continuous tubular reactor, the present invention has an advantage of realizing a homogeneous reaction in a laminar flow domain and in a turbulent flow domain as well.

Step 2: Removal of lower alcohol Lower alcohol is removed from the reaction mixture obtained in Step 1: the method of removing the lower alcohol, not limited thereto, includes distillation (simple distillation, distillation under reduced pressure, fractional distillation, distillation using thin layer distiller) etc. , which are conventional in the art.

According to the conventional methods, the reaction mixture can be separated into a mixed layer of alkylester of fatty acid and lower alcohol and a mixed layer of glycerin, lower alcohol and catalyst, in which two separate apparatuses for the removal of the residual lower alcohol in each of the layers are essentially required. Further, there may exist a problem that glycerin, catalyst and soap components are dissolved into the mixed layer of alkylester of fatty acid and lower alcohol. In the present invention, the removal of lower alcohol from the single-phase mixture obtained after transesterification is first carried out, which provides the following advantages: the process is performed in a simple manner; and, the dissolution of glycerin, catalyst and soap components into a layer of alkylester of fatty acid, which may be caused by the co- existence of alkylester of fatty acid and lower alcohol, can be prevented.

Step 3: Phase separation of mixture and preparation of alkylester of fatty acid

Alkylester of fatty acid is prepared by separating the mixture obtained in Step 2 into a layer of alkylester of fatty acid and a glycerin layer containing glycerin, catalyst and soap components in a form of precipitate, and removing the glycerin layer therefrom: the method of separating the layer, not limited thereto, includes simple separation, liquid/liquid centrifuge, etc. , which are conventional in the art.

In the present invention, catalyst is present only in a glycerin layer because residual lower alcohol is removed prior to the separation of an ester layer and a glycerin layer. Accordingly, catalyst can be removed together with the removal of glycerin layer, and small amounts of soap components produced during transesterification, can be removed through simple separation step because they are not dissolved into the layer of alkylester of fatty acid. As a consequence, alkylester of fatty acid with high purity can be prepared.

A process for preparing alkylester of fatty acid in the present invention may further comprise a step of removing insoluble solid materials from the alkylester of fatty acid obtained in Step 3, in a case that the insoluble solid materials such as soap, etc. exist in the layer of alkylester of fatty acid.

The present invention is further illustrated in the following examples, which should not be taken to limit the scope of the invention.

Reference Examples 1 to 7: Determination of mixing ratio of animal fat and/or vegetable oil to lower alcohol In carrying out the present invention, a reaction system should be maintained in a single-phase to produce an alkylester of fatty acid with high purity, for this purpose, it is critical to subject the reaction products, i. e.,

lipophilic alkylester of fatty acid and hydrophilic glycerin, to a state of single-phase to the end of reaction.

Therefore, the point that the final reaction products reach to a single-phase was determined, while varying the concentrations of lower alcohol at a certain temperature, and the amount of lower alcohol to animal fat and/or vegetable oil at the initial point was determined therefrom, for the purpose of maintaining a single-phase of reaction products to the end of reaction.

First, 36g of methylester of fatty acid (98.5%) and 4g of glycerin (99.5%) produced from soybean oil were injected into a 250ml reactor with fixed-quantity injection device, temperature and pressure controller, and stirrer, then, the temperature of the reactor was elevated to a certain point shown in Table 1 below. Methanol was added gradually under a condition of maintaining the temperature, and the concentration of methanol was determined when the mixture was turned into a single-phase, and the minimum amount of methanol mixed with soybean oil was determined at a certain temperature of reaction in order to adjust the concentration ratio of methanol/methylester of fatty acid after transesterification to the said ratio of concentration, whose results are shown in Table 1 below.

[Table 1] Molar ratiio of Concentration of methanol/soybean Reference Temp (C) methanol in a oil to maintain a Example reactor conferring single-phase of a single-phase reaction 1 40 57. 8% 45.5 2 50 47. 1% 35.0 3 60 39. 9% 25.5 4 70 32. 9% 19.2 5 75 28.4% 16.4 6 80 24. 9% 14.7 7 85 21. 7% 13. 3

As can be seen in Table 1, it was determined that molar ratio of methanol/soybean oil necessary to maintain a single-phase of reaction varies depending on the temperature, and 10 or more molar ratio of methanol to soybean oil was required thereto.

Example 1: Preparation of alkylester of fatty acid with high purity in a continuous tubular reactor As depicted in Figure 1, animal fat and/or vegetable oil heated at about 100°C in a heat exchanger 1, and methylalcohol, in which sodium hydroxide is dissolved in a ratio of 0.5% (w/w) to the animal fat and/or vegetable oil, heated at about 60°C in a heat exchanger 2 were injected into 15L of a blender equipped with stirring bar at a uniform speed of 81kg/hr using a booster pump, while maintaining the temperature and pressure of the blender at 78°C and 5 atm, respectively. Reactants were left to stand in the blender for 30 sec to reach to a single-phase, which was then transferred to a continuous tubular reactor 6. A tubular reactor of duct-form was provided in a thermostat facility maintaining a temperature of 80°C, whereby preventing a decrease in the temperature of reactants, and the retention time of the mixture in the reactor was adjusted to 15 min in total by passing the mixture through a reactor with 4cm of diameter, 35.8m of total length at a speed of 180L/hr. After completing the reaction, the final mixture from the reactor was immediately directed to an evaporator 7 to remove methylalcohol, then transferred to a separator 8 in which a glycerin layer containing catalyst and a layer of methylester of fatty acid were separated, respectively. In a case that insoluble solid materials are present in the layer of methylester of fatty acid, they were further removed in a separator 9. The methylester of fatty acid thus prepared was analyzed by the aid of Gas Chromatography (HP6890, FID) equipped with BPX5 column. The result showed that the conversion ratio of alkylester of

fatty acid was 98.5%. In this example, the physicochemical parameters of a mixture in the reactor were as follows (see: Table 2).

[Table 2] Physicochemical parameters of a mixture Numerical value in a continuous tubular reactor Density, ? <-L = y Ji gOC. 5 850kg/m p I P. [ Viscosity. (InA, 5atm 0. 665cp Volume flow rate 0. 18m/hr ReynoldTs number 4Q 712 3cDrL Yield of methylester of fatty acid 98. 5% As can be seen in Table 2, the yield of methylester of fatty acid was 98.5% even in a laminar flow domain that the Reynold's number (ReD) is below 2100.

Comparative Examples 1 and 2: Reaction in case of two-phase of reactants Methylester of fatty acid was prepared similarly as in Example 1 except that a molar ratio (or weight ratio) of methanol to animal fat and/or vegetable oil was different from each other: first, soybean oil and catalyst-methanol solution were injected into a blender at a speed of 130kg/hr and 30kg/hr, respectively, at the same temperature as in Example 1, and reacted in a continuous tubular reactor with 4 cm of diameter. In carrying out Comparative Example 1, the length of reactor in total was 35.8m, to maintain 15 min of retention time in the reactor. In carrying out Comparative Example 2, the length of reactor in total was 71.6m, allowing 30min of retention time in the reactor. The results of Comparative Examples 1 and 2 revealed that: the conversion ratios of methylester of fatty acid were 64% and 77%, respectively; and, two-phase

reaction employing a continuous tubular reactor cannot provide methylester of fatty acid with a high purity of 97% or more via one-step continuous process.

Example 2: Preparation of alkylester of fatty acid with high purity in a single continuous turbulent tubular reactor Methylester of fatty acid was prepared similarly as in Example 1 except that Reynold's number in a continuous tubular reactor was changed by adjusting the inner diameter of the continuous tubular reactor to 1.25cm and the total length to 349m. The results revealed that the conversion ratio of methylester was 9. 8. 6%.

In carrying out this Example, the physicochemical parameters of a mixture in the reactor were as follows (see: Table 3).

[Table 3] Physicochemical parameters of a mixture ....,.. Numerical value in a continuous tubular reactor Density, < wt) a 850kg/m3 p, Pi viscosityw fm 0. 665cp Volume flow rate 0. 18m/hr Reynold Is number 4 2279 3EDrL Yield of methylester of fatty acid 98. 6% As can be seen in Table 3, the yield of methylester of fatty acid was 98.6% even in a turbulent flow domain that the Reynold's number (ReD) is above 2100.

Examples 3 to 7: Methylester of fatty acid was prepared analogously as

in Example 1 except for employing different alkali catalysts. The yield of methylester of fatty acid and the catalysts are shown in Table 4.

[Table 4] Yield of methylester of fatty acid 3 sodium hydroxide (NaOH) 97.3% 4 sodium methoxide (CH30Na) 98.2% 5 zirconium 97. 2% butoxide (C16H3604Zr) 6 dibutoxide-dibutyl 97. 3% tin (C16H3602Sn) tetrabutylammonium 97. 6% hydroxide ([CH3 (CH2) 2CH2] 4NOH) As can be seen in the above Table 4, it was clearly demonstrated that alkylester of fatty acid with a high yield of 97% or more can be prepared by reacting alcohol with animal fat and/or vegetable oil in the presence of alkali catalyst such as metal hydroxide, metal methoxide, multivalent metal alkoxide, ammonium hydroxide, etc.

Examples 8 to 12: Methylester of fatty acid was prepared in a similar fashion as in Example 1 except for employing different lower alcohols. The yield of methylester of fatty acid depending on the kind and amount of lower alcohol are shown in Table 5.

[Table 5] Molar ratio of Yield of alcohol to animal Example Lower alcohol alkylester of fat and/or fatty acid vegetable oil 8 methylalcohol 27.8 98.5 9 ethylalcohol 22.2 98.0 10 propylalcohol 23.8 97.8 11 butylalcohol 32.6 97.1 12 2-ethylhexanol 34.8 97.2

As can be seen in the above Table 5, alkylester of fatty acid can be obtained with a high yield of 97% or more by maintaining the reaction in a single-phase by way of controlling the ratio of alcohol to animal fat and/or vegetable oil depending on the kind of alcohol.

As clearly illustrated and demonstrated as above, the present invention provides a process for preparing an alkylester of fatty acid with high purity via one-step continuous process by reacting an animal fat and/or vegetable oil with a lower alcohol in the presence of alkali catalyst by passing through a continuous tubular reactor while maintaining a single-phase. In accordiance with the present invention, all of the used catalysts can be efficiently participated in esterification and reversible reaction can be prevented by decreasing the reactivity of alcohol groups of glycerin, which allows a high yield production of 97% or more of alkylester of fatty acid via one-step process even in a continuous tubular reactor with poor mixing efficiency. Further, residual lower alcohol can be removed prior to the separation of a glycerin layer, which makes all of the used catalysts reside in the glycerin layer, and soap components produced in a small amount as a by-product in the course of preparation, can be precipitated in a layer of alkylester of fatty acid, which can afford the simplified separation with high efficiency and the decrease in the working expenses.

While the present invention has been shown and described with reference to the particular embodiments, it will be apparent to those skilled in the art that many changes and modifications may be made without departing from the spirit and scope of the invention as defined in the claims. Accordingly, the substantial scope of the present invention is defined as the attached claims and their equivalents.