DE102008060558A1 - Process for the catalytic cracking of vegetable oils and animal fats - Google Patents

Abstract

The invention relates to a process for the catalytic cracking of natural triacylglycerols with the aim of producing alternative fuels or their components from renewable raw materials. According to the invention, the catalyst is lignocellulose or cellulose in the form of granules, powder, sawdust particles or fibers, the catalyst particles having at least one dimension between 0.01 and 10 mm. The catalyst is made from wood, straw, hay, dry leaves and various other waste from agriculture and the woodworking industry. The proportion of the catalyst in the reaction mixture is between 0.5 and 20 wt .-%.

Description

Field of the invention

The The invention relates to a process for the catalytic cracking of vegetable oils and / or animal fats as natural triacylglycerols with the aim of recovering liquid condensates after a certain treatment as vehicle fuel or as components of a vehicle fuel based on renewable raw materials can be.

State of the art

There are known methods for the catalytic cracking of triacylglycerols with the aim of converting the triacylglycerols into hydrocarbons at high temperatures of up to 500 ° C, the cracking products being usable as vehicle fuels. A group of such methods according to the Canadian Patent 1 313 200 (1993) and the U.S. Patent 4,992,605 (1991) employs, in the presence of hydrogen, transition-metal based catalysts commonly used in the petroleum industry for catalytic hydrocracking at temperatures of 350 to 450 ° C and pressures of 1 to 25 MPa. On the basis of the catalysts NiMo / Al ₂ O ₃ and CoMo / Al ₂ O ₃ alkanes, cycloalkanes and alkylbenzenes can be obtained with a total conversion of up to 100%, with a yield of C12-C18 alkanes between 65 and 75%. Three independent processes are combined here - deoxygenation, decarboxylation and hydrogenation. After partial isomerization, the products are similar to fossil diesel. The disadvantages of this process, which results in products with excellent fuel properties, are that expensive high pressure technology using hydrogen and expensive catalysts are required, and that catalyst activity decreases. The next group of known methods for the catalytic cracking of natural triacylglycerols employs zeolites as catalysts. Zeolite catalysts are crystalline aluminosilicate materials based on a three-dimensional network of AlO ₄ and SiO ₄ tetrahedrally linked by oxygen atoms. Zeolites are porous and contain pores of defined size with areas of strong electrostatic field associated with the presence of cations. These areas are catalytically highly reactive. The pore size can be changed depending on the requirements of the product. The synthetic zeolite catalysts ZSM-5 or HZSM-5 convert triacylglycerols into gasoline-like products. On the other hand, mesoporous forms of MCM zeolite catalysts produce linear, long-chain hydrocarbons with the boiling range of diesel. The disadvantage of this group of processes is the high price of zeolite catalysts and their limited recyclability as well as problems with the spent catalyst handling.

Subject of the invention

These Disadvantages are achieved by the method according to the invention for the catalytic cracking of triacylglycerols, whose Subject matter is that as a catalyst lignocellulose or a cellulosic material in the form of granules, powder, sawdust particles or fibers is used, wherein the catalyst particles at least have a dimension between 0.01 and 10 mm.

There are some advantages associated with using lignocellulose as a cracking catalyst. Mainly they are very low and negligible price and their easy availability. As a catalyst, various well-dried waste from agricultural production and from the woodworking industry, such as sawdust particles, ground cereal or rape straw, hay, dry leaves, ground corncobs, nutshells, crushed press cake from rapeseed or sunflower seeds, but also waste paper, due are used to short fibers no reuse, are used. In the case of press cake, the remaining oil in the cake can be utilized. The surprising and unexpected catalytic activity of lignocellulose and cellulose in cracking triacylglycerol can be explained by the fact that lignocellulose has a layered structure with staggered lignin layers and cellulosic layers. Removal of the lignin at the elevated temperature during cracking forms a spongy but strong structure with openings similar in size to those in zeolites. In the case of cellulose, these openings are already finished, they were produced during cellulose production. The porous structure then causes cracking in the same way as in zeolites. Also, the alkali metals present in lignocellulose have the same function that they have in zeolites. At the negligible price of the lignocellulosic catalyst, its concentration in the reaction mixture is not limited. The well-known fact that a higher proportion of catalyst also means a higher reaction rate can be usefully exploited. It is also possible to recycle the catalyst, even if it is not as important and interesting as in other reactions. The lignocellulosic catalyst remains after the first application in the form of a porous material of low density, similar to charcoal. It is possible to treat it without any treatment, without reducing the yield and without changing the Use product parameters more than once. With repeated use of the lignocellulosic catalyst, no phenomenon of catalyst dehydration with foaming is observed. The cracking of triacylglycerol in the presence of the lignocellulosic catalyst requires a shorter reaction time compared to the zeolite in the same concentration. The type of oil / fat used has only a minor influence on the composition of the liquid cracking condensate. The elimination of the spent catalyst is easily and practically associated with no cost. The spent catalyst is simply burned and used for energy. After extraction of the organic residues, it can be used, for example, as valuable charcoal or in steel production.

Similar as in the case of zeolite catalysts, there are also in the case of Lignocellulosic catalysts virtually no limiting parameters with regard to the oil / fat used, such as acidity, Moisture, presence of other materials, etc. In this way can make use of used cooking oils and carcass fats the carcass utilization are used.

The catalytic cracking process according to the invention of triacylglycerols looks like this. A suitable Amount of triacylglycerol is placed in a batch reactor. It may be vegetable oils such as rapeseed oil, soybean oil, sunflower, Palm or cotton oil, inedible oil from the seeds of the plant Jatropha curcas, used cooking oils, Castor oil, oil from algae and the like act. Of the animal fats, tallow, lard, chicken fat, Fish oils, kafilery fat from carcass utilization and the like can be used. When inventive Catalytic cracking can also be mixtures of oils and fats are used. The oils and fats can also free fatty acids or other esters as triacylglycerols, z. For example, methyl esters of fatty acids. The quality of oil and fat, the extent of their pollution or impairment does not play a crucial role here. Consequently Can the oils and fats without any pretreatment be used in catalytic cracking.

To the reaction partner from the oil or fat becomes the catalyst admitted, or it will be reversed, or he will advance admixed. The catalyst is lignocellulose or cellulose in Form of grains, of a powder, of sawdust particles, of waste or fibers, and the proportion of the catalyst in the reaction mixture should be between 0.5 and 20 wt .-%, more often between 2 and 12 wt .-% and most often between 5 and 10 wt .-% lie. The catalyst particles should be shaped so that they in at least one dimension between 0.01 and 10 mm, and most often should measure between 0.1 and 2 mm. Usually have the particles have similar dimensions in all dimensions. The catalyst is made of wood, straw, hay, dry leaves and similar other agricultural waste and the wood industry, such as sawdust particles, corn plants, Rape plants and the like produced. For this purpose can suitable comminution methods, such as sawing, grinding, pulverizing and the like. Also suitable are cakes Rapeseed or sunflower seeds, etc., in which the existing in the cake residual oil is exploited. The catalyst should be well dried, otherwise for elimination the water's time is needed, energy is consumed and the released water causes an intense foaming.

The The reaction mixture prepared in this way is then treated with a Speed of 30 to 40 ° C / min heated. After the initial Mixing does not require further mixing as bubbles are released from Water and decomposition products make the mixture natural Mix the way. Intensive cracking processes run between temperatures from 350 and 450 ° C. The reaction mixture is about 20 to 25 minutes between these temperatures, so the cracking times depending on the batch amount a total of 40 to 50 minutes, including the for cooling the cracking residue required time.

The in the reactor during the inventive catalytic cracking of triacylglycerols formed vapors flow directly into the capacitor, which has sufficient Surface for condensing and cooling and a sufficient length for condensing comprising all condensable components. The condenser / cooler must be big enough to handle the random ones To absorb eruptions of cracking products. The Temperature is in the liquid reaction mixture and measured in the steam inlet into the condenser. In the apparatus becomes no protective atmosphere generated. Fill the evaporating components the entire space in the apparatus, and that is the contact of the hot products with the atmospheric oxygen severely restricted.

At the end of the cracking process, indicated by a decrease in the amount of steam and the decrease in steam temperature at the condenser inlet, the heating is stopped and the reactor will be empty after cooling. The residue after cracking consists mainly of the catalyst, which is now modified compared to a fresh one. The spent catalyst is solid and fragile after washing, with lower density and a structure similar to charcoal. The cataly satorrest is in a viscous, tarry liquid, the residue after cracking of the triacylglycerol. The solid content of the residue of the modified catalyst is about 80 to 90% of the mass of the fresh catalyst. The liquid portion of the residue represents about 3 to 8% of the mass of processed oil / fat. The liquid condensate represents about 80 to 90% and the gaseous portion about 5 to 8% of the mass of the processed oil / fat. It seems likely that some of the fresh catalyst will also be converted into cracking products. The mass loss of the fresh catalyst in cracking is mainly due to water release. The catalyst can be used repeatedly without a wash and without any other treatment in the reaction. Such use of the catalyst in the same amount of fresh oil resulted in similar product yields as well as similar product compositions. The question of catalyst regeneration and recycle is not critical because of negligible costs. The used catalyst, instead of being burned, may be used after suitable treatment for example as charcoal or carbon in steelmaking.

The liquid condensate, which is the major product of the catalytic cracking of triacylglycerols according to the invention, contains a small amount of about 2 to 4% of its mass of water. This water comes in part from the catalyst, partly from the oil / fat as a product of the cracking reactions. The water is practically insoluble in the liquid condensate, it settles spontaneously and forms a separate phase. The liquid condensate is a light brown or brown liquid with a sharp, irritating odor. By heat treating the liquid condensate, which consists of rapid heating to 190 or 195 ° C at a heating rate of about 25 ° C per minute, the light ends evaporate at a level of 7 to 9% from the bulk of the liquid condensate. In this light end, the volatile compounds are concentrated with exceptionally sharp odor and irritating effects on the respiratory tract and the eyes. The remaining distillation residue is a brown liquid, which now has a tolerable odor. Its viscosity is about 9 to 11 mm ² / s at 40 ° C, the density at 15 ° C about 885 to 900 kg / m ³ , the oxygen content at about 12 to 15 wt .-% of the water content at about 500 to 900 ppm, the acid number between 105 and 135 mg KOH / g, the heat of combustion at about 39 to 41 MJ / kg. Comparison of a GLC chromatogram of this distillation residue with that of a fossil diesel shows that similar compounds are present in both materials, but only in terms of volatility and not chemical consistency. While the fossil diesel is a mixture of saturated n-, iso-alkanes and cycloalkanes with aromatics, mainly alkylbenzenes, the distillation residue contains mainly unsaturated hydrocarbons and oxygenated compounds in the form of aldehydes, ketones, alcohols and acids. Such treated liquid condensate may be used as a fuel component for diesel engines in the form of a blend with fossil diesel fuel, which component may be mixed at any temperature at laboratory temperature. By hydrogenating this liquid condensate under mild conditions (temperature up to 360 ° C, hydrogen pressure to 6 MPa, catalyst NiW / Al ₂ O ₃ ), a high quality diesel fuel is obtained.

The gaseous products of the catalytic cracking of triacylglycerols according to the invention contain mainly CO and CO ₂ , and in a small amount also CH ₄ , C ₂ H ₄ and C ₂ H ₆ .

The Catalytic cracking of triacylglycerols according to the invention can also be done as a continuous process.

Examples of implementation the invention

example 1

250 g of rapeseed oil, after cold pressing and filtering in a filter press, were placed in a 1000 ml two-necked glass flask connected to an efficient water-cooled condenser with 25 grams of fibrous particulate sawdust approximately 0.1 mm in diameter and approximately equal in length 2 mm mixed. The mixture was heated to 400 ° C within 10 minutes, to 420 ° C during the next 10 minutes, to 450 ° C during the next 10 minutes, and at this temperature the mixture was held for the next 10 minutes, for a total of 40 Heated, and then the heating was interrupted. An intense vapor formation was observed from a temperature of about 350 ° C, but mainly at about 400 ° C, and after 25 minutes of cracking, the evolution of steam was lower. An intense foaming was observed after the 10 minute cracking at the temperature of about 400 ° C, and after the next 10 minutes at the temperature of about 420 ° C, it was lower. The balance of the process: gaseous components 20 g (8% of the mass of the oil used), tar and liquid residue after cracking 6.8 g (3%), solid residue of the catalyst 20 g, liquid condensate 227.4 g (91 %). The increase in the balance by 2% is due to the catalyst (5 g, probably water). From the liquid condensate settled water with a mass of 9.7 g (4%), and thereby the yield of liquid condensate (organic content) was reduced to 87% of the mass of the oil used. The liquid condensate was then distilled, the light ends fraction was removed in the temperature range up to 190 ° C in an amount corresponding to 7% of the mass of the oil used. The yield of distillation residue, the fraction of the main product, was then 80% of the mass of the oil used. Some parameters of the distillation residue: viscosity at 40 ° C 10.18 mm ² / s, density at 15 ° C 891 kg / m ³ , oxygen content 13.69 wt .-%, water content 804 ppm, acid number 129 mg KOH / g, heat of combustion 40.63 MJ / kg.

Example 2

250 Rapeseed oil, the same as in Example 1, was used in the same apparatus as in Example 1 with 25 g kleinschnittem Cereal straw in the form of platelet-shaped particles with dimensions of about 0.1 × 1 × 3 mm mixed. For the experiment were similar Conditions selected as in Example 1. The balance of the process: gaseous components 8.6% of the mass of the oil used, Tar and liquid residue after cracking 3%, solid residue of the catalyst 21 g, liquid Condensate 90%. The increase in the balance sheet by 2% stems from Catalyst (4 g, probably water). From the liquid Condensate separated 13 g of water (5%). The yield of liquid condensate (organic layer) dropped to 85% of the mass of the oil used. The liquid condensate was then distilled; the fraction the light end was in the temperature range up to 190 ° C removed in an amount that is 7% of the mass of the oil used corresponded. The yield of distillation residue, the Fraction of the main product of the cracking process, then stood at 78% the mass of the oil used. The mass balance is in This example is practically the same as in Example 1. Also shows the comparison of the GLC chromatograms of the distillation residues after the treatment of the liquid condensates a good agreement of the both chromatograms.

Example 3

250 Rapeseed oil, the same as in Examples 1 and 2, were with 25 g of recycled cellulose in the form of a powder with particles mixed below 0.1 mm. The conditions and the course of the experiment corresponded to those of Examples 1 and 2. Balance of the process: gaseous Components 11.4%, liquid condensate 85%, residue after cracking 3.4%, water phase in the liquid condensate 3%, yield of liquid condensate (organic layer) 82%. After distillation with removal of 11.9% in the form of Fraction of the light end, the yield of distillation residue is at 70.1% of the mass of the oil used. The balance sheet and the Chromatograms of the distillation residue are those similar to the previous examples.

Industrial Applicability

The catalytic cracking process according to the invention of vegetable oils and animal fats may be in production alternative fuels from renewable raw materials for Vehicles are used. The liquid condensate off Cracking may occur after treatment as a fuel or as a component a fuel used for diesel engines.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - CA 1313200 [0002]
• US 4992605 [0002]

Claims (2)

Process for the catalytic cracking of vegetable oils and animal fats at atmospheric pressure and temperatures of 300 to 500 ° C, characterized in that the catalyst is lignocellulose and / or cellulose in the form of granules, powder, sawdust particles or fibers, wherein the catalyst particles at least one dimension between 0.01 and 10 mm. Process for catalytic cracking according to point 1, characterized in that the proportion of the catalyst in the Reaction mixture is between 0.5 and 20 wt .-%.