Process for the preparation of bio-diesel

FIELD OF THE INVENTION

The present invention relates to an improved process for the preparation of bio-diesel. It has enormous potential application in automobile industry as a substitute fuel for diesel.

BACKGROUND OF THE INVENTION

Biodiesel has of late been recognized as an efficient fuel substitute. As reported by Anjana Srivastava and Ram Prasad (Renewable & Sustainable Energy Reviews—4, 2000, p111-133,) renewable sources such as vegetable oils, animal fats and used cooking oils are normally used as the starting material for preparing this alternate source of fuel. There are also reports that, the engine problems due to carbonization of combustion chamber and wax deposits & engine failure.

As reported by Gerhard Vellguth (Society of Automobile Engines No. 831358, 1983), the fuel injector modifications are needed in standard diesel engines while using vegetable oil as a fuel , otherwise forms deposits on the injectors and in the cylinder head, leading to poor performance, higher emissions and reduces engine life. This limitation has to some extent been resolved by way of transesterification. Reference may be made to Antolin et al., (Bioresource Technology 83, 2002, p 111-114), who transesterified sunflower oil with methanol at a temperature in the range of 40-70° C. under constant stirring for a period of 2-6 hrs. Similar efforts have been made by different research groups to prepare biodiesel from multiple oil sources. As reported by Alcantara et al., (Biomass Bioenergy 18,p515-527,2000) several oils such as soybean, frying oil, tallow have been tried as substitutes for diesel. As reported by Widyan and Shyoukh (Bioresource Technology 85, p253-256,2002), palm oil has also been tried as substitutes.

Conventionally, biodiesel is prepared from oil by reacting with alcohol using a acid/alkali/enzyme catalyst in the temperature range of 40-80° C. under constant stirring for a period of 2-6 hrs. In order to achieve higher product conversion, 1-3 moles per moles of oil in excess to stoichemetric quantity of alcohol is normally used and the unreacted alcohol is removed in the subsequent process steps. The ester obtained is separated from glycerine by suitable separation process and the ester is washed with mild acid. The product is purified further by evaporation to remove unreacted alcohol and traces of moisture. The final product is normally used in combination with regular petroleum fuels to overcome the viscosity and related problems.

The major limitation associated with all these processes is that the overall product conversion in most of the cases is limited to 60-85% only. Moreover, the temperature range limited up to 60° C. results in prolonged time, which may be as high as 6 hrs and thereby enhancing the cost of the process significantly.

Another limitation associated with these processes is that the resulting product exhibits higher viscosity compared with conventional petroleum fuels, thereby necessitating it is blending with petroleum fuels for the use in diesel engines.

OBJECTS OF THE INVENTION

The main object of the present invention is to provide an improved process for the preparation of bio-diesel which obviates the limitations as stated above.

Another object of the present invention is to provide a chemical process for biodiesel with renewable sources of energy.

Still another object of the present invention is to provide a chemical process for biodiesel oil preparation from extracted from agricultural edible and non-edible products.

Yet another object of the present invention is to provide an environmentally friendly fuel.

Still yet another object of the present invention is to provide an improved quality of biodiesel can be used with out any alteration in the diesel engine.

Accordingly the present invention provides an improved process for the preparation of bio-diesel, which comprises

- i) heating oil, characterized by specific gravity in the range of 0.85-0.96 and iodine value not exceeding 208, to a temperature not exceeding 120° C. for not less than 2 hrs followed by transesterification with 8 to 42% w/w, of alcohol of general formula R-OH, where R represents (C_nH_2n+1), n being any integer between 1 and 5, by known method in presence of not more than 0.55% w/w, of a known catalyst, at a temperature higher than the boiling point of the alcohol but not exceeding 215° C. for a period of not less than 30 minutes under continuous turbulent condition to get mixture of ester and glycerol,
- ii) subjecting the mixture, as formed in step(i) to separation of the esterified oil by known method for a period of not less than 4 hrs followed by conventional purification for a period of not less than 8 hrs. and repeating the process of separation as well as purification in succession for not less than three times to get biodiesel.

In an embodiment of the present invention the oil used may be selected from ricebran oil, cottonseed oil , soybean oil, sunflower oil, castor oil, coconut oil.

In another embodiment of the present invention the alcohol used may be selected from methanol, ethanol, n-propanol, n-butanol, n-pentanol

In yet another embodiment of the present invention the catalyst used may be selected from sodium hydroxide, potassium hydroxide.

In still another embodiment of the present invention, the known method of separation used may be such as decanting, centrifuging, gravity separation, settling.

In yet another embodiment of the present invention the conventional method of purification used may be selected from bubble washing involving bubble size of 1-3 mm, micro filtration with not less than 5 micron filter, centrifuging, either alone or in any combination.

In still another embodiment of the present invention, the Reynolds number (N_Re) used for maintaining turbulence may be adjusted at not less than 4000 irrespective of the type of reactor.

The process of the present invention is described below in detail.

Oil having specific gravity in the range of 0.85-0.96 and iodine value not exceeding 208 is heated to a temperature not exceeding 120° C. for not less than 2 hrs and is transesterified using 8 to 42% w/w, of alcohol of general formula R-OH, where R represents (C_nH_2n+1), n being any integer between 1 and 5, by known method in presence of not more than 0.5% w/w, of a known catalyst, at a temperature higher than the boiling point of the alcohol but not exceeding 215° C. for not less than 30 minutes under continuous turbulent condition at rpm in the range of 100-150 to get a mixture of ester and glycerol. The Reynolds number (N_Re) is maintained at not less than 4000 irrespective of the type of the reactor.

The mixture of ester and glycerol is subjected to separation by known method for a period of not less than 4 hrs and the top layer ester is purified by conventional method for a period of not less than 8 hrs. The process of separation as well as purification is repeated for not less than three times in succession to get biodiesel.

The inventive step of the present invention lies not only in selecting the temperature of transesterification at higher than the boiling point of the alcohol while not exceeding 215° C., but also in maintaining turbulence monitored by adjusting the Reynolds number (N_Re) at not less than 4000 irrespective of the type of the reactor, to ensure about 97% conversion of the oil into ester within a period of as low as 30 minutes, thereby enhancing the formation of fuel properties in the resulting product called biodiesel.

The following examples are given by way of illustration only and therefore should not be construed to limit the scope of the present invention.

EXAMPLE 1

100 ml of rice bran oil having a moisture content of 3% was heated at 120° C. for a period of 2 hrs. Later the moisture content of the oil was found to be 0.5%. This oil was taken in the specially modified batch Continuous Stirred Tank Reactor (CSTR) with provision for alcohol recycle/recovery system, condenser, thermometer and feeding funnel. 20 ml of methanol was taken in a beaker and 0.5 gm sodium hydroxide was added to it under continuous stirring. The resulting solution was then added to the reactor rapidly. The reactor system was maintained at turbulent condition by stirring at 100 rpm in order to maintaining the Reynolds number (N_Re) at the minimum of 4000. The reaction was continued for 30 minutes. The excess methanol of 4 ml used for above reaction was later is recovered.

The resulting solution was taken in separating funnel, and two layers were found to form. The mixture was allowed to settle for 4 hrs and the top layer was taken for further processing.

This was then subjected to bubble washing by aeration with 15 ml of distilled water for a period of 8 hrs and the resulting material was allowed to settle for 8 hrs. It was taken for micro filtration to remove the micro particles present in the product. The bubble washing, settling and filtration operations were repeated for two more times to attain improved fuel properties. The resulting biodiesel was stored.

97% of rice bran oil was estimated to has been converted into biodiesel, which was found to meet the specifications of conventional petroleum fuel. The biodiesel was used for running a test engines. The emission properties of this biodiesel were found to be better than of the conventional fuels.

EXAMPLE 2

100 ml of rice bran oil having a moisture content of 3% was heated at 120° C. for a period of 2 hrs. Later the moisture content of the oil was found to be 0.5%. This oil was taken in the specially modified batch Continuous Stirred Tank Reactor (CSTR) with provision for alcohol recycle/recovery system, condenser, thermometer and feeding funnel. 32 ml of propanol was taken in a beaker and 0.5 gm sodium hydroxide was added to it under continuous stirring. The resulting solution was then added to the reactor rapidly. The reactor system maintained at turbulent condition by stirring at 100-rpm in order to maintaining the Reynolds number (N_Re) at the minimum of 4000. The reaction was continued for 30 minutes. The excess methanol of 7 ml used for above reaction was later is recovered by the special recovery system. The resulting solution was taken in separating funnel, and two layers were found to form. The mixture was allowed to settle for 4 hrs and the top layer was taken for further processing.

This was then subjected to bubble washing by aeration with 25 ml of distilled water for a period of 8 hrs and the resulting material was allowed to settle for 8 hrs. It was taken for micro filtration to remove the micro particles present in the product. The bubble washing, settling and filtration operations were repeated for two more times to attain improved fuel properties. The resulting biodiesel was stored.

95% of rice bran oil was estimated to has been converted into biodiesel, which was found to meet the specifications of conventional petroleum fuel. The biodiesel was used for running a test engines. The emission properties of this biodiesel were found to be better than of the conventional fuels.

EXAMPLE 3

100 ml of sunflower oil having a moisture content of 1.5% was heated at 120° C. for a period of 2 hrs. Later the moisture content of the oil was found to be 0.5%.

This oil was taken in the specially modified batch Continuous Stirred Tank Reactor (CSTR) with provision for alcohol recycle/recovery system, condenser, thermometer and feeding funnel. 40 ml of butanol was taken in a beaker and 0.5 gm sodium hydroxide was added to it under continuous stirring. The resulting solution was then added to the reactor rapidly. The reactor system maintained at turbulent condition by stirring at 100-rpm in order to maintaining the Reynolds number (N_Re) at the minimum of 4000. The reaction was continued for 30 minutes. The excess butanol of 8.3 ml used for above reaction was later is recovered by the special recovery system.

The resulting solution was taken in separating funnel, and two layers were found to form. The mixture was allowed to settle for 4 hrs and the top layer was taken for further processing.

98.0% of sunflower oil was estimated to have been converted into biodiesel, which was found to meet the specifications of conventional petroleum fuel. The biodiesel was used for running a test engines. The emission properties of this biodiesel were found to be better than of the conventional fuels.

EXAMPLE 4

200 ml of coconut oil having a moisture content of 2% was heated at 120° C. for a period of 2 hrs. Later the moisture content of the oil was found to be 0.5%.

This oil was taken in the specially modified batch Continuous Stirred Tank Reactor (CSTR) with provision for alcohol recycle/recovery system, condenser, thermometer and feeding funnel. 47 ml of methanol was taken in a beaker and 1 gm sodium hydroxide was added to it under continuous stirring. The resulting solution was then added to the reactor rapidly. The reactor system maintained at turbulent condition by stirring at 100-rpm in order to maintaining the Reynolds number (N_Re) at the minimum of 4000. The reaction was continued for 60 minutes. The excess methanol of 10 ml used for above reaction was later is recovered by the special recovery system.

The resulting solution was taken in separating funnel, and two layers were found to form. The mixture was allowed to settle for 8 hrs and the top layer was taken for further processing.

98.0% of coconut oil was estimated to have been converted into biodiesel, which was found to meet the specifications of conventional petroleum fuel. The biodiesel was used for running a test engines. The emission properties of this biodiesel were found to be better than of the conventional fuels.

EXAMPLE 5

100 ml of coconut oil having a moisture content of 2% was heated at 120° C. for a period of 2 hrs. Later the moisture content of the oil was found to be 0.5%.

This oil was taken in the specially modified batch Continuous Stirred Tank Reactor (CSTR) with provision for alcohol recycle/recovery system, condenser, thermometer and feeding funnel. 35 ml of ethanol was taken in a beaker and 0.5 gm sodium hydroxide was added to it under continuous stirring. The resulting solution was then added to the reactor rapidly. The reactor system maintained at turbulent condition by stirring at 100-rpm in order to maintaining the Reynolds number (N_Re) at the minimum of 4000. The reaction was continued for 45 minutes. The excess ethanol of 8 ml used for above reaction was later is recovered by the special recovery system.

The resulting solution was taken in separating funnel, and two layers were found to form. The mixture was allowed to settle for 8 hrs and the top layer was taken for further processing.

97.0% of coconut oil was estimated to have been converted into biodiesel, which was found to meet the specifications of conventional petroleum fuel. The biodiesel was used for running a test engines. The emission properties of this biodiesel were found to be better than of the conventional fuels.

EXAMPLE 6

100 ml of sunflower oil having a moisture content of 1.5% was heated at 120° C. for a period of 2 hrs. Later the moisture content of the oil was found to be 0.5%.

This oil was taken in the specially modified batch Continuous Stirred Tank Reactor (CSTR) with provision for alcohol recycle/recovery system, condenser, thermometer and feeding funnel. 20 ml of methanol was taken in a beaker and 0.5 gm sodium hydroxide was added to it under continuous stirring. The resulting solution was then added to the reactor rapidly. The reactor system maintained at turbulent condition by stirring at 100-rpm in order to maintaining the Reynolds number (N_Re) at the minimum of 4000. The reaction was continued for 30 minutes. The excess methanol of 4 ml used for above reaction was later is recovered by the special recovery system. The resulting solution was taken in separating funnel, and two layers were found to form. The mixture was allowed to settle for 4 hrs and the top layer was taken for further processing.

EXAMPLE 7

100 ml of sunflower oil having a moisture content of 1.5% was heated at 120° C. for a period of 2 hrs. Later the moisture content of the oil was found to be 0.5%.

This oil was taken in the specially modified batch Continuous Stirred Tank Reactor (CSTR) with provision for alcohol recycle/recovery system, condenser, thermometer and feeding funnel. 25 ml of ethanol was taken in a beaker and 0.5 gm sodium hydroxide was added to it under continuous stirring. The resulting solution was then added to the reactor rapidly. The reactor system maintained at turbulent condition by stirring at 100-rpm in order to maintaining the Reynolds number (N_Re) at the minimum of 4000. The reaction was continued for 30 minutes. The excess ethanol of 8 ml used for above reaction was later is recovered by the special recovery system.

The resulting solution was taken in separating funnel, and two layers were found to form. The mixture was allowed to settle for 4 hrs and the top layer was taken for further processing.

Emission Analysis of Diesel, Biodiesel and Various Blends

Load

Time for
CO
CO₂
HC
O₂
NOx
Noise
T_exh

KW
Sample
10 cc(sec)
(% vol)
(% vol)
(ppm)
(% VOL)
(ppm)
(db)
(° c.)

0
Diesel
65
0.08
2.1
28
17.53
180
145
140

Biodiesel
65
0.04
2.55
10
17.10
111
116
182

BS1
66
0.02
2.31
0
17.30
154
145
153

BS2
71
0.02
2.14
0
17.50
96
112
154

BS3
69
0.03
2.13
0
17.36
125
113
145

BS4
69
0.03
2.42
5
17.28
113
120
170

BS5
78
0.04
2.09
0
17.47
84
115
169

4
Diesel
49
0.12
3.5
43
15.62
397
145
210

Biodiesel
45
0.04
3.95
20
15.27
118
119
202

BS1
51
0.03
3.61
0
15.70
369
120
190

BS2
49
0.03
3.49
27.5
15.57
277
112
196

BS3
48
0.03
3.84
20
14.94
300
115
180

BS4
49
0.04
3.90
17.5
16.39
283
129
245

BS5
48
0.045
4.02
2.5
14.99
300
116
242

7
Diesel
42
0.13
4.3
63
14.68
582
146
243

Biodiesel
36
0.03
5.06
10
13.53
525
121
277

BS1
46
0.04
4.11
35
14.73
473
117
210

BS2
39
0.04
4.87
12.5
13.56
502
114
225

BS3
38
0.05
5.44
10
12.67
479
116
243

BS4
38
0.05
5.20
10
13.18
496
126
285

BS5
38
0.06
5.46
32.5
12.85
451
119
315

11
Diesel
32
0.2
6.3
85
11.2
689
159
287

Biodiesel
30
0.05
6.74
20
10.99
727
123
329

BS1
32
0.06
6.79
37.5
10.53
800
119
250

BS2
29
0.06
6.91
15
10.43
728
118
240

BS3
30
0.10
7.05
15
10.15
608
119
285

BS4
30
0.10
7.35
45
9.83
605
126
296

BS5
30
0.11
7.01
30
10.36
616
121
362

14
Diesel
27
0.34
7.7
89
9.12
942
169
294

Biodiesel
25
0.09
8.30
35
8.74
904
124
411

BS1
27
0.07
7.58
35
9.24
977
120
266

BS2
26
0.18
8.04
47.5
8.54
858
119
363

BS3
23
0.27
9.03
52.5
6.86
782
122
342

BS4
27
0.14
8.10
45
8.60
782
127
395

BS5
24
0.24
8.30
45
8.22
660
123
380

Note:

BS—Blended with Diesel

BS1-B20, BS2-B80, BS3-B50, BS4-B40, BS5-B60

Oil Specification

Specific gravity: 0.916-0.912

Refractive Index: 1.470-1.473

Iodine value: 99-108

Saponification value: 181-189

Acid value: 4-120

Titer: 24-28° C.

Unsaponifiable matter: 3.5%

Tocopherols average: 400 mg/kg of oil

Fuel Properties

Property
DIESEL
Biodiesel (RBOE)

Density (gm/cc)
0.82
0.865

Viscosity (Cst)
2.4
3.46

Heat Of Combustion
42.57
45.09

(MJ/Kg)

Flash Point (° C.)
74
182

Fire Point (° C.)
87
194

Copper strip Corrosion
No. 3
<No. 1

@ 100 (° C.)

Engine Efficiency

Specific Fuel
Break Thermal
Mechanical
Indicative Thermal

Load
Consumption (kWh)
Efficiency (%)
Efficiency (%)
Efficiency (%)

(kW)
Diesel
Biodiesel
Diesel
Biodiesel
Diesel
Biodiesel
Diesel
Biodiesel

0
∞
∞
0
0
0
0
20.65
30.22

4
0.556
0.611
15.07
14.01
47.41
37.54
31.77
37.33

7
0.378
0.419
22.17
20.08
62.22
51.27
36.22
40.46

11
0.314
0.333
26.67
25.69
71.26
62.31
37.42
41.23

14
0.292
0.328
28.65
26.07
75.94
67.78
37.73
38.45

A comparative study of the Complete specification relating to P03ce04 (an improved process for the preparation of bio-diesel) and the U.S. Pat. No. 6,015,440 apparently reveals the following differences.

Sl. NoU.S. Pat. No. 6,015,440Bio-diesel Process - Ref No. P03ce04/CLRI1.Temperature range of theMore than the boiling point of the alcohol butreaction 70-80° C.less than 215° C.2.Pressure at 20 psigAtmospheric pressure3.Separation alkali using ionSeparation of alkali using waterexchange column4.Top layer approximately 80%More than 80%5.Un-reacted methanol removalUn-reacted methanol has separated immediatelyby an addition process step ofafter the reaction by a specially modifiedflash recovery system (in aprovision built within on within the reactorseparate reactor)6.Fixed bed/Plug flow reactorBatch reactor7.Multiple reactorSingle reactor consists of special provision forexcess alcohol recovery8.Continuous processBatch process9.Increased final productThe final product contains only higher fatty acidvolume due to blending ofesters.higher fatty acid ester withglyceryl ether.10.Reaction with isobutyleneNo such reaction11.Oxidative processBase catalysed transesterification12.Product is Mixture of Bio-The final product contains higher fatty aciddiesel and Ester glycerolesters.13.Transesterifying at least aAlmost all portion.portion only14.This end product of thisThe end product is bio-diesel, no mixing withprocess is a mixture of esterglycerol. In fact glycerol is obtained as by-and the etherified glycerol,productwhich is converted into bio-diesel by blending.15.Only by mixing the etherifiedThis is a bio-diesel process, without mixing theglycerol to the esterified oilglycerol, with all required bio-diesel propertiesmay gives the viscosityand emission norms similar to the normal dieselreduction.fuel.16.Strong acid catalyst processAlkali/base catalyst process17.Approximately 80% of theMore than 95% in pure formbio-diesel is in pure form18.Effect of mixing of etherifiedNo engine difficulties. No need of any change incrude glycerol's effect in thethe engine needed, no engine block etc.engine is not defined, shownonly the viscosity reduction19.Low waste process, notMore than 95% conversion. Glycerol formed asseparating the 20% crudea by-product can be used in other industries.glycerol formed.20.Formation of 20% glycerol,Glycerol formed as a by-product can be used infor economical purpose, afterother industries.reacting with isobutylenemixing with the bio-diesel21.After mixing the crudeThe final product after the reaction is similar toglycerol only, the productdiesel fuelgives properties closelyresembling to have of dieselfuel

In our opinion, the inventive step of the present invention visa-vis the aforesaid U.S. Patent document, however, essentially lies in conducting the reaction at a temperature higher than the boiling point of the alcohol used, besides maintaining the turbulence (N_Re=4000 or more), that is applicable irrespective of the type of the reactor used, to enhance the fuel properties of the resulting product. This step ensures that no blending, as described in the U.S. Patent document.

Following are some of the advantages of the present invention:

- 1. The high temperature with turbulent condition (Reynolds number more than 4000), reduces the reaction time significantly.
- 2. The special provision in the reactor enables the effective recovery of excess alcohol added for the reaction.
- 3. Bubble washing and microfiltration achieved the high quality of the biodiesel.
- 4. The product is based on renewable source.
- 5. The product can be used as substitute fuel for diesel engines without any major modification of engines.
- 6. The final product is a substitute fuel for diesel without blending with other conventional petroleum fuels.
- 7. The products fuel properties and the engine efficiency are comparable with normal diesel engine fuels.
- 8. The emission characteristics are like those of normal fuels.

Process for the preparation of bio-diesel

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