RU2189996C2 - Method of rapid acidic hydrolysis of lignocellulose material and hydrolytic reactor - Google Patents

Abstract

FIELD: chemical technology. SUBSTANCE: invention relates to a method of acidic hydrolysis of lignocellulose material, for example, wood, straw, vegetables and so on used for production of sugars and lignin and also to a hydrolytic reactor unit for realization of the method to be proposed. The continuous acidic hydrolysis is carried out by the simultaneous delignification and saccharification in a single reaction cycle using an organic solvent dissolving lignin and a strong inorganic acid to provide the isolation of highly concentrated sugar solution. By combining the stages of saccharification and deliginification the invention provides the increase of sugar yield and the use of diluting acid. EFFECT: improved method of hydrolysis, decreased time of process and consumption for equipment. 18 cl, 3 dwg, 2 ex

Description

FIELD OF THE INVENTION
The invention relates to a method for the acid hydrolysis of lignocellulosic material, such as wood, squeezed sugarcane, straw, vegetables, etc., to obtain, among other products, sugars and lignin, as well as a hydrolysis reactor for implementing this method.

BACKGROUND OF THE INVENTION
With regard to the hydrolysis effect, lignocellulosic materials can be described as a complex of cellulose, hemicellulose and lignin, which additionally contains lower organic components such as tannins, waxes, oils, etc., the so-called "extractable substances", and mineral substances (silica, calcium , potassium, sodium, etc. ash). Cellulose (or glycan, 36-40 wt.%) Is a polymer of glucose in amorphous form (most) and in microcrystalline form. Hemicellulose (34%) is a complex amorphous polymer containing glycan (8%), xylan (22%), arabinan and galactan (only 4%). It was shown that hemicellulose hydrolyzes almost instantly, microcrystalline cellulose is quite resistant to acids, and amorphous cellulose takes an intermediate place. Lignin (a polymer made from phenylpropene containing active phenolytic functional groups) is not soluble in an exclusively acidic environment, but can be dissolved using certain organic solvents. Ashes are formed by silica and aluminum, as well as iron oxides, which are very slightly soluble in hydrolytic agents, and potassium, sodium, etc. oxides, which are soluble in acids. Such properties require suitable conditions for hydrolysis devices and methods.

 In the processes of acid hydrolysis of lignocellulosic materials, among other things, hexoses (sugars with 6 carbons) are formed, such as glucose, galactose and mannose; pentoses (5-carbon sugars) such as xylose and arabinose; lignin; furfural; 5-hydromethylfurfural; acetic acid and, among others, methanol in variable proportions, depending on the processed raw materials.

 Known methods of acid hydrolysis of lignocellulosic materials are divided into two main groups: methods using concentrated acids and methods using dilute acids.

 From the first group, the Bergius and Udik Rheinau processes are distinguished, in which 40-45% hydrochloric acid is used, and the Riga process, in which 75% sulfuric acid.

 Although such processes have increased hydrolysis yields (approximately 94% of the stoichiometric value), large investments are required in the equipment, since it must be assembled from a material resistant to such highly concentrated acids. In addition, the handling of such acids makes the process extremely difficult.

Of the methods in which diluted acids are used and which are designed to overcome the above disadvantages, the Schoeller process should be noted. According to this method, the wood is heated in percolators at 134 ^{° C.} using sulfuric acid, thereby obtaining, by repeated extraction, sugar at a concentration of 2-4% in a solution obtained by hydrolysis.

 Obviously, this process, which is carried out according to the method with periodic loading, has a much lower yield than expected from a commercial point of view.

In order to improve the diluted acid method described above, a process called the Madison process using a 0.6% dilute sulfuric acid was developed at the Laboratory of Forest Products of the United States. in the range of 18 m ³ per 1 ton of dried processed material and which is carried out in 3-5 hours, reaching a maximum yield of 67% of its stoichiometric value. Although the Madison process is significantly improved relative to the Scholler process, its output is still below what is desired. In addition, due to the elevated temperature at which it is carried out, even when diluted acid is used, the equipment must be made of special materials, such as titanium and zirconium, which increases the investment for him, even though they are less than the investment for the methods, which use strong acids.

 In addition to the above disadvantages, which are special for each type of process, both processes have one common problem: during the saccharification operation, delignification practically does not occur from the acid hydrolysis process, and the lignin is kept in the equipment in a viscous state, from which it is removed in a batch process, creating thus, the additional problem of controlling the continuous saccharification stage and the interrupted lignin removal stage in order to combine them into a single process mode.

 Attempts to achieve a continuous process of acid hydrolysis of lignocellulosic materials, which would ensure both delignification and saccharification, have led to a continuous countercurrent method for producing lignin and sugars from wood and other lignocellulosic materials by delignification and saccharification using an organic solvent at elevated temperatures and pressures, and the method mainly includes the continuous introduction from one end of the reactor of crushed lignocellulosic material; countercurrent introduction from the other end of the reactor of a cooking solution containing a larger amount of an organic solvent and a smaller amount of water, as well as a small amount of inorganic acid; contacting said lignocellulosic material with said cooking liquor; removing the latter after it has been mixed with sugars and dissolved them and the remaining substances of the crushed lignocellulosic material.

 Despite the fact that in this method, increased degrees of lignin extraction and conversion into sugars are achieved, such performance has not been quantified. In addition, carrying out the indicated process on a laboratory scale indicated many opportunities for improvement: since there is a large delignification or saccharification, different at each level of the reactor, and the discussed process ensures the supply of the cooking solution and removal of the product from the solution in the same flows, then the conditions for the solvent and reagent in temperature and concentration along the height of the reactor are almost random, which makes it difficult and even impossible to properly control the process in the sense of achieving the complete conversion of lignocellulosic material without excess reacting acid, and also in terms of preventing decomposition of sugars resulting from hydrolysis of cellulosic material.

Description of the invention
Thus, the aim of the present invention is to propose a method for the rapid acid hydrolysis of lignocellulosic material using a hydrosolvent system, which makes it possible to simultaneously delignify and saccharify it, in accordance with the temperature and concentration parameters of the solvent and reagent, which are precisely controlled at several levels reactor, so as to achieve dissolution of lignin and maximum conversions of sugars, while essentially avoiding tsya thermal decomposition of the resulting sugar.

 In addition, the aim of the present invention is to provide a reactor for the rapid acid hydrolysis of the above lignocellulosic material.

 The above and other objects and advantages of the present invention are achieved by a method for rapidly acid hydrolyzing a lignocellulosic material comprising a cellulosic part and a lignin part, the method comprising the following steps.

As the closest analogue, patent US 4,941,944 is adopted, which describes the process of acid hydrolysis of lignocellulosic material, comprising the following steps:
a) a continuous flow from above the reactor under high pressure, a homogeneous stream, which is heated and ground to a particle size acceptable for hydrolysis;
b) contacting said lignocellulosic material at various levels of the reactor with a plurality of streams of a hydrosolvetic system containing most of the solubilizing lignin of an organic solvent and water, and a smaller part of an extremely dilute solution of a strong inorganic acid, so as to simultaneously carry out the reaction of the cellulosic material and dissolving the lignin, to obtain a liquid phase in the form of a hydrolysis extract containing the reaction products of the cellulose portion and a solution of lignin, and a solid phase containing n unreacted and undissolved material;
e) removing from the indicated levels of the reactor the remainder of the liquid phase, drastically lowering its temperature at the outlet of said reactor so as to avoid decomposition reactions of said reaction products of the cellulosic part, and obtaining, by evaporation of the solvent, a concentrate of the reaction product of the cellulosic part and lignin;
f) transferring said lignin by decantation.

 The proposed method differs from the known one in that after stage (b), the indicated solid phase is retained so that it is deposited at the bottom of the specified reactor (stage (c)), and the controlled flow of the liquid phase obtained in stage (b) is recirculated to different levels of the reactor to a properly adjusted temperature and introducing the specified stream into the corresponding stream of the hydrosolvent so as to ensure at the indicated levels of the reactor the temperature and concentration of the organic solvent and the proper a strong inorganic acid necessary for the reaction of the cellulosic material and dissolution of the lignin present at the appropriate levels of the reactor (stage (g)), as well as the fact that the specified concentrate of the reaction products of the cellulose part is transferred to the subsequent processing stages (stage (g)).

The method includes the following steps:
a) a continuous feed from above the reactor, in which increased pressure is created, to a homogeneous stream of lignocellulosic material, which is heated and ground to a particle size acceptable for hydrolysis, namely 5-50 mm long, 1-10 mm wide and 1-5 mm thick;
b) contacting said lignocellulosic material at various levels of the reactor with a plurality of streams of a hydrosolvent system containing most of the lignin-dissolving organic solvent and water and a smaller part of an extremely dilute strong inorganic acid solution so as to simultaneously carry out the reaction of the cellulosic material and dissolving the lignin in the form of a hydrolysis extract, containing the reaction products of the cellulose portion and the lignin solution, and a solid phase containing unreacted and non-solution venerable material;
c) holding said solid phase so that it is deposited at the bottom of the reactor;
d) recirculating the controlled flow of the liquid phase obtained in stage (b) to various levels of the reactor, to a suitably adjusted temperature, and introducing the specified stream into the corresponding stream of the hydrosolvent so as to ensure at the indicated levels of the reactor the temperature and concentration of the organic solvent and strong inorganic acids that are suitable for the reaction of cellulosic material and dissolution of lignin present at appropriate levels of the reactor;
e) removing from the indicated reactor levels the remainder of the indicated liquid phase, drastically lowering its temperature at the outlet of the said reactor so as to avoid decomposition reactions of the indicated reaction products of the cellulose part, and obtaining, by evaporation of the solvent, the reaction product concentrate of the cellulose part and lignin;
f) separating said lignin by decantation;
g) transferring the specified concentrate of the reaction products of the cellulosic part to subsequent stages of the process.

 The second aspect of the present invention relates to a hydrolysis reactor for implementing the method of rapid acid hydrolysis of the above lignocellulosic material, said hydrolyser comprising a vertical tubular body including a plurality of captures for the hydrolysis extract along its longitudinal direction; an opening for supplying lignocellulosic material through which lignocellulosic material is continuously supplied to said reactor; a plurality of pipes for supplying a hydraulic solvent, through which the hydraulic solvent is continuously fed into the reactor so as to ensure close contact between the specified hydraulic solvent and lignocellulosic material inside the latter; as well as a plurality of liquid circuits, each of which is fluidly connected to at least one hydrolysis extract trap so as to receive a hydrolysis extract from said reactor through it and to selectively and in a controlled manner re-supply said extract to the latter and / or transfer it to a subsequent process step through a flow control means.

 In practical terms, the method of acid hydrolysis of lignocellulosic material has, among others, the following advantages: the use of extremely dilute acid, which does not require equipment made from special and very expensive materials; simultaneous delignification and saccharification stages, resulting in a reduced amount of equipment; and carrying out the specified process in such temperature conditions so that the least decomposition of the resulting sugars occurs. Since the hydrolysis extract leaving the reactor is partially recycled, it is possible to precisely control the concentration and temperature of the reagents supplied to each level of the reactor by simply controlling the flow and temperature of the recyclable material, which in the absence of reagents acts as a diluent for a given supply of fresh reagent, introduced into the hydrosolvent. Abrupt cooling of the hydrolysis extract directly at the outlet of the reactor is a characteristic of the method, which provides rapid evaporation of the solvent, even almost spontaneously, thus leading to the cessation of the aforementioned sugar decomposition reactions. In addition, the evaporation of the solvent by 15-30 wt.% Reduces the load on the distillation column, which, therefore, reduces the cost of it. In addition, in the aforementioned method, extraction levels of up to 85% and sugar concentrations of up to 35% are achieved, that is, to values that were never achieved in the known methods: in the present case, the achieved sugar concentration is seven times higher than the previously described concentrations.

 From another point of view, the proposed method is extremely fast: while the shortest periods of time known for acid hydrolysis of lignocellulosic materials are in the range from 3 to 5 hours, in the present method this period is from 10 to 40 minutes, providing thus, a 7-18-fold increase in the productivity of the reactor and its auxiliary equipment, which is expressed in tons of dried processed material per cubic meter per hour, and a proportional reduction in the time for reimbursement of share capital dix.

The invention will be described with reference to the accompanying drawings as follows:
figure 1 presents a schematic vertical section of a reactor designed to implement the proposed method of rapid hydrolysis;
in FIG. 2 is an enlarged view of a capturing structure for a hydrolysis extract in the reactor of the present invention in accordance with the assembly of FIG. 1;
figure 3 shows a block diagram of a method according to the present invention.

The best way of carrying out the invention
Although the cellulosic component of the processed lignocellulosic material contains a portion of hemicellulose as such, to simplify the following statement, the expression "cellulosic portion" will refer to both of these parts in this group.

 The delignification and saccharification operations of the lignocellulosic material in the present method are carried out in a single step in the reactor 10 using a hydrosolvent system designed to simultaneously react the cellulosic part and dissolve the lignin part that forms the specified lignocellulosic material, thereby obtaining a liquid phase or extract, containing hydrolysis products of the specified cellulosic part, mainly sugar, and the specified solution is further discharged, and a lignin solution, the same solid phase, which contains unreacted and undissolved substances, mainly mineral substances, and is deposited at the bottom of the specified reactor 10.

 Since the proposed method is continuous, the supply of both lignocellulose and hydrosolvent should be constant and uniform. To this end, and in order to guarantee a satisfactory contact area between the specified hydrosolvent and lignocellulosic material, as well as to avoid clogging by the material at the inlet of the reactor, the latter is ground until a particle size suitable for hydrolysis is reached.

Further, the supplied lignocellulosic material is heated to a temperature of 80-180 ^° C, preferably 100-150 ^° C so as to soften the plant fibers, expel the air bubbles occluded in them, thereby facilitating the penetration of the hydrosolvent and, therefore, dissolving the lignin inside the reactor for 10 s the release of the cellulose portion for a quick and effective acid exposure.

 In order to function as described above, the hydrosolvent system contains from 40 to 90% by volume and preferably from 50 to 80% by volume of a solubilizing lignin organic solvent selected from the group consisting of carbon, ketones with 2-6 carbon atoms and mixtures thereof, preferably methanol, ethanol, acetone, etc., or mixtures thereof and more preferably acetone; from 10 to 60% by volume and preferably from 20 to 50% by volume of water; and a strong inorganic acid selected from the group consisting of sulfuric acid, hydrochloric acid, phosphoric acid and the like, or mixtures thereof, and preferably sulfuric acid in such an amount as to provide a concentration of 0.01 to 0.1 n, preferably from 0.02 to 0.05 n of the specified acid in the specified hydrosolvent system.

 The stages of delignification and saccharification of lignocellulosic material are carried out in different ways at each level inside the reactor 10. Various concentrations of the reagent acids between the feed and the hydrosolvent must be provided, and at each level of the reactor different reaction temperatures must be provided, and adjustment of such parameters is carried out by means of a stage that is a fundamental feature of the proposed method, no matter what the recirculation of part of the hydrolysis extract exiting the reactor 10 without reacting acid: for example, a fresh hydrosolvent is introduced at a constant temperature and concentration, a simple temperature control of the recirculated extract and its streams and a fresh hydrosolvent will adjust the acid concentration to strictly necessary for its reaction with the cellulose part of lignocellulose fed into the reactor 10.

In general, the delignification and saccharification step is carried out inside the reactor 1 at a temperature of 160-250 ^{° C.} and preferably from 180 to 190 ^{° C.} , preferably under a pressure of 20-40 bar and preferably from 20 to 30 bar. The supply of the hydrosolvent and lignocellulosic material is distributed evenly, in accordance with the radial flows of the hydrosolvent, in a proportion of 2-18 and preferably from 3 to 10 m ^{3 of the} hydrosolvent per 1 ton of lignocellulosic material being processed. Under such conditions, both streams are in close contact with each other, with the receipt of the above liquid and solid phases. In order to prevent a greater decomposition of the sugars formed, said liquid phase or extract is immediately transferred to a solvent evaporation apparatus (“instantaneous evaporator”) with a sharp decrease in temperature.

 The extract obtained in the delignification and saccharification step, properly cooled and preferably filtered, is transferred to a distillation column, in which it is concentrated by extracting more solvent that is returned to the process. The concentrated extract thus obtained is taken into a first settling tank, in which it is separated into a lower layer containing lignin, an upper layer that determines a concentrate or solution containing sugar, according to analysis up to 35 wt.% Depending on the initial lignocellulosic material; remaining products resulting from the saccharification reaction; and a precipitate of lignin transferred into an undissolved state by removal of the solvent.

 In a second design, the concentrated and decanted extract can be fed into a second settling tank, marked with a dashed line in FIG. 3.

 Decanted lignin is recovered, at least partially dried, and can be used in several applications, starting from fuel, due to its lower calorific value (TS) of 24.4 MJ / kg and low ash analysis results (0.30 %) and sulfur (0.14%), as well as even as a raw material for the production of phenolic resins (replacing phenol), due to its high reactivity.

 The solution is subjected to further processing to recover the remaining products.

 At the stages before the concentration of the liquid phase, it is very important to adjust the solvent extraction operation so as to load the lignin into the distillation stage, thereby avoiding its dense deposition on equipment, as is usually the case with most known methods. Although the present invention can be carried out with conventional equipment for which small modifications are ultimately made and which have higher yields than those already known in the art, the best results were achieved with a reactor 10 specially designed to carry out the present method.

 In accordance with figure 1, the hydrolysis reactor 10 contains a vertical cylindrical tubular body formed of a suitable metal material, such as stainless steel, and at the corresponding levels of the specified reactor 10 internally introduced many, preferably six traps 11 for the hydrolysis extract, each of which is specified two rings 12 for attaching the filter, preferably formed from the same material as the specified reactor 10, and inserted, for example, by welding into its inner a wall, said rings 12 being substantially parallel and spaced apart with respect to their inner edges; a cylindrical filter mesh 13 formed of a suitable material, such as stainless steel, fastened, for example, by a screw connection, and in addition, characterized by Tyler mesh from 16 to 200, preferably Tyler mesh 100, as well as an opening that is not shown, but provided in the wall of the reactor 10, is located radially with respect to the specified filter mesh 13 and provides fluid contact between the inner and outer spaces of the specified reactor 10.

 It is preferable that lignocellulosic material is fed into the reactor 10 from above, through an opening 14 for supplying lignocellulosic material, and a hydraulic solvent through a plurality, preferably three pipes 15a, 15b, 15c for supplying a hydraulic solvent, which are arranged concentrically and internally with respect to the latter [hole 14] and the length of which increases from the outside inward, and the free ends are closed, and on each of them there are many lateral spray holes 16 so as to radially spray the hydraulic solvent into the lignocell Lozno material inside said reactor 10, providing intimate contact therebetween.

 Outside, every two adjacent captures 11 for the hydrolysis extract are fluidly connected, parallel to each other, through the corresponding openings in the reactor 10 with the corresponding fluid circuit 1, the latter including a circulation pump 2, after which the specified fluid circuit 1 branches, defining a pipe 17 for re-supply into the reactor and the exhaust pipe of the reactor 18; while the flows through both branches can be selectively controlled using a suitable flow control means, such as a valve 19 provided on the pipe 18.

 The hydrolysis reactor 10 described above operates in a flooded state, and the liquid medium floods it at least until the upper captain 11 is covered, this level is constant, the process is continuous and the total supply of lignocellulose and hydrosolvent entering the reactor 10 is essentially equal to the volume of the product taken through the exhaust pipe 18. In accordance with the above construction, the reactor 10 should be initially flooded, and the hydraulic solvent is fed into it until then, until you reach the desired level. After that, the process is initiated by feeding the lignocellulosic material and the hydrosolvent into the reactor 10 through the feed hole 14 and through the feed pipes 15a, 15b and 15c, respectively.

 As the lignocellulosic material passes downward inside the reactor 10 through washing with a hydrosolvent, which is then sprayed through the spray holes 16, it is gradually consumed, the cellulose part being hydrolyzed to form sugars, while the lignin dissolves, and the resulting liquid mixture determines the hydrolysis extract, which is pumped out of the reactor 10 through a few captures 11. Thus, each liquid circuit 1 receives a stream of filtered hydrolysis extract, in other words, he, about substantially free of solid material, as the latter having half the treated feedstock is held mesh filter 13, from which it is separated due to the mixing caused by flow gidrosolventnogo solution and returned to the reaction medium. The mineral component of the plant is separated as the latter dissolves and is deposited at the bottom of the reactor 10. As indicated above, the hydrolysis extract obtained at a specific level of the reactor 10 is pumped through the corresponding liquid circuit 1, and part of it is recycled through the reactor in accordance with the pipe re-supply 17 and is introduced into the supply of the hydraulic solvent in the corresponding pipe 15A, 15b, 15C to supply the hydraulic solvent. As a result, the hydrolysis extract without reacting acid dilutes the fresh hydrosolvent, bringing the acid concentration in it to that which is strictly necessary for the reaction with the cellulosic part of the feedstock at this level of the reactor 10.

 Thermal control of the process inside the hydrolysis reactor 10 is also carried out through the recycle stream of the hydrolysis extract. For this, the supply pipes 17 of the reactor are equipped with appropriate heating means A, such as steam jackets, each of which in a controlled manner heats the extract stream in the corresponding supply pipe 17 of the reactor so as to provide the required temperature at the outlet of the corresponding pipe for supplying the hydraulic solvent 15a, 15b, 15c process at a given reactor level 10.

 The other, non-circulating portion of the hydrolysis extract is withdrawn through the corresponding outlet pipe 18 in order to subject it to rapid temperature reduction and subsequent concentration by evaporation of the solvent, the hydrolysis extract concentrated in this way is fed to the subsequent processing.

 In the illustrated and described configuration of the reactor 10, there are six captures 11, each two adjacent captures being fluidly connected in parallel through a corresponding hole provided in said reactor 10 with a corresponding circuit 1 which is fluidly connected to the corresponding supply pipe 15a, 15b 15c hydrosolvent.

 This design is preferred because it combines low production and installation costs in combination with high productivity when it comes to processing commonly used lignocellulosic raw materials, and in accordance with the characteristics generally accepted for the final products.

However, due to the specific requirements for raw materials or for the final product, the hydrolysis reactor may have several modifications, such as:
- the presence of a smaller or larger number of capttions for the hydrolysis extract;
- each capturing for the hydrolysis extract can be equipped with many outlet openings of the reactor, the latter being connected to the liquid circuit using an appropriate collector;
- the upper ring to support the filter in each capture for the hydrolysis extract may be of a larger diameter, so that the corresponding filter mesh will be tilted down, thereby contributing to the deposition of silica;
- each capturing for the hydrolysis extract can be connected to an individual liquid circuit, whereby individual supply pipes for the hydro-solvent and individual outlet pipes of the reactor are provided; and
- each fluid circuit may be associated with three or more captures for the hydrolysis extract.

 In order to allow irregular removal of silica deposited at the bottom of the reactor 10, the latter is provided with a drain hole 3.

 Although the hydrolysis reactor 10 for the proposed method can be made of 316 L stainless steel, using extremely dilute sulfuric acid, if desired, the structural material can be carbon steel coated with a protective metal such as niobium, tantalum or zirconium.

 In order to provide a better view of the proposed hydrolysis process, FIG. 3 is a flowchart showing a possible processing sequence.

 Example 1

Lignocellulosic material containing sugarcane cake with a moisture content of 50% is fed into an 18 L reactor according to the invention at a rate of 126 g / min while supplying a 102 l / h hydrosolvent mixture. The reaction was carried out at a temperature of 186 ^o C and an acidity of 0.04 equiv. sulfuric acid per 1 liter of hydrosolvent mixture for 5 hours. As a result, 68% of sugar is recovered.

 Example 2

Sugarcane cake with a moisture content of 50% is fed into an 18 L reactor in accordance with the invention, with a flow rate of 145 g / min while supplying 100 l / h of a hydrosolvent mixture. The reaction is carried out at a temperature of 191 ^o C and an acidity of 0.03 equiv. sulfuric acid per 1 liter of hydrosolvent mixture for 4.5 hours. As a result, 81% of sugar is recovered.

Claims (18)

1. A method for the rapid acid hydrolysis of a lignocellulosic material containing a cellulosic and lignin moiety, comprising the following steps: a) continuously supplying from above a pressurized reactor a uniform stream that is heated and ground to a particle size suitable for hydrolysis; b) contacting said lignocellulosic material at various levels of the reactor with a plurality of streams of a hydrosolvent system containing most of the solubilizing lignin of an organic solvent and water and a smaller part of an extremely dilute solution of a strong inorganic acid so as to simultaneously react the cellulosic material and dissolve the lignin to obtain a liquid phase in the form of a hydrolysis extract containing the reaction products of the cellulose part and a solution of lignin, and a solid phase containing no reacted and undissolved material; c) removing from the indicated levels of the reactor the remainder of the liquid phase, drastically lowering its temperature at the outlet of said reactor so as to avoid decomposition reactions of said reaction products of the cellulose part, and obtaining, by evaporation of the solvent, a concentrate of the reaction product of the cellulose part and lignin; d) transferring said lignin by decantation, characterized in that the pressure in the reactor in stage a) is from 20 to 40 bar, the hydrosolvent system in stage b) contains from 40 to 90 vol. % solubilizing lignin organic solvent and water in an amount of from 10 to 60% and a dilute solution of a strong inorganic acid are introduced in such an amount as to ensure an acid concentration of 0.01-0.1 N, while after phase b) the solid phase is held in this way that it was delayed at the bottom of said reactor, and recycling a controlled flow of the liquid phase obtained in step (b), at different levels of the reactor to a temperature of 80-180 ^o C, and introducing said stream into corresponding flow gidrosolventa so hr Oba provide in said levels of the reactor temperatures and concentrations of organic solvent and adequate strong inorganic acid to react cellulosic material and dissolve the lignin present in the respective levels of the reactor, said cellulosic portion of the concentrate of the reaction products are transferred to subsequent processing steps.  2. The method according to p. 1, characterized in that the remaining part of the liquid phase is removed from the circulation stream of the specified liquid phase.  3. The method according to p. 1, characterized in that the hydrosolvent system introduced into the recirculation stream of the liquid phase is in contact with lignocellulosic material in radial flows.  4. The method according to p. 1, characterized in that the proper temperature at different levels of the reactor is achieved by heating the corresponding recirculated flow of the liquid phase.  5. The method according to p. 1, characterized in that the organic solvent is selected from the group consisting of alcohols with 1-4 carbon atoms, ketones with 2-6 carbon atoms, or mixtures thereof, and a strong acid is selected from the group consisting of sulfuric acid, hydrochloric acid or mixtures thereof.  6. The method according to p. 1 characterized in that the hydrosolvent system contains from 50 to 80% by volume of an organic solvent selected from the group consisting of methanol, ethanol, acetone and the like or mixtures thereof, from 20 to 50% by volume of water, and sulfuric acid in such an amount as to provide a concentration of 0.01-0.05 n of said acid in said hydrosolvent system.  7. The method according to p. 1, characterized in that the organic solvent is acetone.  8. The method according to p. 1, characterized in that the pressure in the reactor is from 20 to 40 bar.  9. The method according to p. 1, characterized in that the pressure in the reactor is from 20 to 30 bar. 10. The method according to p. 1, characterized in that the supplied lignocellulosic material is heated at a temperature in the range from 100 to 150 ^o C. 11. The method according to p. 1, characterized in that the temperatures at several levels of the reactor (10) are from 160 to 250 ^o C. 12. The method according to p. 1, characterized in that the temperatures at several levels of the reactor (10) are from 180 to 190 ^o C.  13. A hydrolysis reactor containing a vertical tubular body with an opening for supplying lignocellulosic material and a hydrosolvent with the possibility of close contact between the hydrosolvent and continuously supplied lignocellulosic material, means for hydrolysis extracts connected to a liquid circuit for receiving a hydrolyzed extract from the reactor, characterized in that for hydrolysis of lignocellulosic material according to one of claims. 1-13, the means for hydrolysis extracts is a plurality of captures arranged along the longitudinal direction of the reactor vessel, each of which is connected to a respective liquid circuit configured to selectively control the re-supply of the extract to the reactor and / or transfer the extract to the last stage of the process by means of a control means flow.  14. The reactor according to claim 13, characterized in that each capturing for the hydrolysis extract contains two rings, essentially horizontal and parallel to each other, mounted on the inner wall of the reactor vessel, bearing a cylindrical filter mesh attached to their inner sides, having from 16 to 200 mesh according to Tyler, and a hole located radially with respect to the filter screen, made in the wall of the reactor vessel, to ensure fluid communication between the interior of the reactor and the corresponding liquid contour.  15. The reactor according to claim 14, characterized in that the filter mesh has 100 mesh.  16. The reactor according to p. 14, characterized in that inside the hole for supplying lignocellulosic material and a hydraulic solvent located in the upper part of the reactor shell, pipes for supplying a hydraulic solvent are placed coaxially to each other, on each of which there are many side spray holes, and the free ends closed, and the length of the pipe increases from outside to inside.  17. The reactor according to claim 14, characterized in that every two captures for the hydrolysis extract are parallelly connected to each other through a corresponding hole in the reactor vessel with a corresponding liquid circuit equipped with a circulation pump for moving the hydrolysis extract, with a recirculation pipe for re-introducing the extract into the reactor by pipes for supplying a hydraulic solvent and an outlet pipe of the reactor conducting the extract to the next stage of the process, and a valve for selectively is installed on the outlet pipe regulation of the recycle and exhaust streams.  18. The reactor according to claim 17, characterized in that each pipe for re-introducing the extract into the reactor is equipped with heating means for controlled heating of the recycle stream of the hydrolysis extract.

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