RU2467781C2 - Device for extracting vegetable stock and method of operating vegetable stock extractor - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to extraction from vegetable stock. Proposed device comprises housing 1, pulsation chamber 7, stock feed and discharge zones, extractant feed zone, and extract discharge zone. V-shape housing consists of vertical and inclined sections for interaction between vegetable stock and extractant at counter streams and pulsations. Note here that vertical housing represents a tube-in-tube design wherein transfer auger 3 is arranged in inner tube 2 and communicated with stock feed bin via horizontal proportioning auger 4 with fluid feed union 5. Note also that tube bottom is open to feed stock into extraction column 11 arranged in inclined housing and comprising extractant feed zone and stock discharge zone composed of squeezing auger 14. Note that used fluid collector is communicated with extractant load and feed zones arranged at said extraction column. Mind that extract pickup zone is located above stock feed zone. Proposed method consists in interaction between vegetable stock and extractant at counter streams and pulsations.

EFFECT: new design with higher extraction efficiency.

1 tbl, 2 dwg

Description

The invention relates to a device for producing extracts from plant materials and the method of its operation.

For the extraction, plants of various designs are used, as a rule, containing extractors of various designs, the casing of which is connected to containers for the extractant and the extract obtained (PM RF №12365, 2000, class B01D 11/02; PM RF №24396, 2002, class. B01D 11/02, Pat. RF No. 2174032, 2001, CL B01D 11/02, Pat. RF No. 1491540, 1989, CL B01D 11/02).

Numerous methods are known for isolating biologically active substances from plant materials using extractants (RF application No. 2001135097, 2004, CL 1/10; Pat. RF No. 2150852, 2000, CL 1/10, Pat. RF No. 2154560, 1999, CL C13D 1/00; US Pat. No. 3,573,892, 1971, CL C13D 1/00; US Pat. No. 4,857,279, 1989, CL C13D 1/00, etc.). The choice of a specific extraction method and the mode of its implementation, as a rule, is determined by the characteristics of the processed raw materials obtained by the target product, as well as the characteristics of the equipment used.

A device is known for conducting mass transfer processes in heterogeneous systems, comprising a housing equipped with extractor input and output nozzles, between which a layer of the processed dispersed material is located (Planovsky A.I., Nikolaev P.I. Basic processes and apparatuses of chemical and petrochemical technology. M. : Chemistry, 1987, Fig. 15.4.a, p. 372).

The disadvantages of the known device are the possibility of channel formation in the processed material, which leads to an increase in the extraction time and a reduction in the contact surface of the phases, a significant diffusion resistance in the boundary layer, which reduces the efficiency of mass transfer processes.

The most promising from the point of view of mass transfer are the methods associated with periodic or continuous mixing of the extracted plant material, for example, using a mixer (US Pat. RF No. 2091121, 1997, CL B01D 11/02). The extraction plants used in this case are characterized by the installation of appropriate devices in the extractor.

The disadvantage of these extraction methods and the installations used is the low efficiency due to the insufficiently high extraction of biologically active substances from raw materials.

Known extraction plant and method of extraction (US Pat. RF No. 2142314, MKI B01D 11/02, 1999).

The installation contains a pulsating batch extractor, containers for extractant and extract, as well as a piping system for supplying extractant and extracting the extract with control equipment. The extractor contains a cylindrical body with a lid containing a filter baffle built into it, a bottom, technological fittings and a pulsation chamber made in the form of a bell located coaxially in the body, and a device for turning it 180 °.

The method consists in the fact that after loading the raw materials in a pulsation chamber, alternating pressure is created, as a result of which the suspension of plant materials in the extractant comes in a reciprocating motion, due to which the concentration of the extracted biologically active substances in the volume of the extractor is equalized and the extraction process is possible until equilibrium is reached values. Then the extractant is removed, the apparatus is turned over, a new extractant is introduced and the process continues in a similar manner.

The disadvantages of this extractor are large overall dimensions, a large amount of extractant required for complete depletion of raw materials. The disadvantages of the method are the necessity of carrying out the process in several stages, non-optimal conditions for carrying out the mass transfer process, since there is no maximum difference in the concentrations of extractable substances in solid raw materials and liquids.

A device for producing extracts of plant materials is known (US Pat. RF No. 2312697, class B01D 11/00, 2006). A device for obtaining extracts of plant materials contains a casing, divided by a vertical partition that does not reach the bottom of the casing, into two zones. In one zone of the housing there is a pipe, in the upper part of which there is a hatch for loading raw materials. This zone is closed by a lid with a pulsator mounted on it with a drive and a liquid level sensor, interconnected via a control unit. In this area, above the pipe for loading raw materials, but below the liquid level sensor there is a pipe for extracting. Another zone is connected to the pipe for unloading the extracted raw material, on which there is a pipe for supplying extractant. The invention allows to provide a high degree of extraction at a lower temperature and in less time than in known devices and extraction methods used in industry.

The device operates as follows.

The crushed vegetable raw material enters through a loading hatch and a pipe for loading raw materials into zone 3 and moves to the lower part of the housing. At the same time, the extractant in the amount corresponding to the technological regulations enters through the pipe nozzle. A pulsator with a drive feeds pneumatic pulses into the system with compressed air, which cause the raw materials to move into the zone in countercurrent to the incoming extractant. The frequency and duration of the pulses is regulated by the control unit. When the level of the liquid phase falls below the level of the sensor, the signal enters the control unit, which drives the actuator and the pulsator, and the pulse is vented to the atmosphere. The meal is discharged through the pipe. The extract is taken through a pipe.

The disadvantages of the design of the closest analogue are as follows.

The device body is divided by vertical partitions into two zones.

Due to the formation of a dense layer of raw materials, a large hydraulic and pneumatic resistance is created at the interface between the two zones in the lower part of the apparatus, which violates the hydrodynamics of the process and reduces its efficiency.

The pipe for loading raw materials is connected directly to the extraction zone of the extract.

a) Since the pulse is supplied from above to the working area of the device case, the pulse efficiency decreases due to its distribution both to the working area of the device case and to the loading zone.

b) Due to the fact that the raw materials are supplied in dry form, a “plug” is formed from the floating raw materials, which impedes the efficiency of impulse energy transfer to the raw material layer formed in the device.

The selection of the extract occurs in the feed zone.

In this case, particles of the loaded feed are carried through the loading zone to the extract selection zone, which leads to the risk of “clogging” of the extract selection unit and removal of fresh raw materials to waste.

The extracted material is unloaded through a pipe connected to the device body at an angle, which creates a lot of resistance, which leads to a violation of the hydrodynamics of the process.

The closest to the claimed solution in terms of a set of matching features and the technical result achieved is a device for producing extracts of plant materials (US Pat. RF No. 2308308, class B01D 11/00, 2006). The extractor for the system is a solid body - a liquid containing a housing divided by a vertical partition that does not reach the bottom into two zones, one of which is equipped with a cover with a pulsator located on it with a drive connected to a compressor for supplying pneumatic pulses and a liquid level sensor, moreover, a sensor the level and the pulsator drive are connected to the control unit, and in its lower part there is a branch pipe for extracting the extract, the second zone has a loading hatch in its upper part, and an inclined lower part a discharge pipe, in the upper part of which the unextracted raw material is unloaded and there is a pipe for supplying the extractant. The known device has, as well as the previously presented technical solutions, a number of significant drawbacks, the main of which is low productivity due to the lack of a transporting vertical screw, a metering horizontal screw, the lack of preliminary impregnation of raw materials, which together with the missing devices for process automation lead to account to a significant reduction in the controlled parameters of the resulting product and thereby reduce its qualitative and quantitative s performance.

The objective of the claimed technical solution is to create a new, more effective structural device for the extraction of plant materials, eliminating all of the above disadvantages of the closest analogue, and implementing on its basis an extraction method that allows for a high degree of extraction of plant materials in less time with a higher efficiency d. the claimed technical solution.

The essence of the claimed technical solution lies in the fact that the device for the extraction of plant materials, containing a housing, a pulsator, a loading and unloading zone of raw materials, an extractant supply zone, an extract selection zone, a “V” shaped housing is made up of a vertical and inclined housing, in which interacts plant materials with the extractant countercurrent and when exposed to pulsations, characterized in that the vertical casing is made in the form of a pipe-in-pipe construction and contains in the inner a conveyor screw connected to the top with a feed hopper through a horizontal metering screw with a fluid supply unit made in the form of a fitting, and the bottom of the pipe is made open with the ability to feed raw materials to an extraction column located in an inclined housing containing an extractant supply zone and a feed discharge zone made in the form of a squeezing screw, and the waste liquid collector is connected to the loading zone and the extractant supply zone located on the extraction column, while the extract extraction zone is located married above the zone of supply of raw materials to the extraction column according to claim 1, and is characterized in that a self-cleaning filter is installed in the extraction selection zone, turns of the squeezing screw are made with perforation, the method of operation of the device for extracting plant materials consists in the interaction of plant materials with countercurrent extractant and the effect of pulsations and is characterized in that in the feed process the raw materials are pre-impregnated and fed directly to the extractor, extraction is carried out at a given temperature and exposed to the pool pulsation with a frequency in the range of 5-70 pulsations per minute of 0.83-1.17 Hz and a power (pulse) in the range of 10-3 to 102 MJ / mol in zone B, then the extract is taken in the extraction zone (zone A) and the spent raw materials are subjected to squeezing and washing in the discharge zone, while the spent liquid after filtration is again fed to recirculation to wet the feed raw material to the loading zone and in parallel to the extractor for extraction.

The technical result is achieved due to the presented set of features of the claimed device and method.

The essence of the claimed technical solution is illustrated by drawings:

figure 1 is a General view of a device for the extraction of plant materials and the method of its operation;

figure 2 is a schematic block diagram of the operation of the device for producing extracts of plant materials.

The device consists of a housing 1.

The housing 1 of the device is made "V" -shaped, at an angle of 45 °, consisting of:

- vertical housing - zone A.

- inclined body - located to it at an angle of 45 ° - zone B;

- the sector connecting the vertical and inclined buildings - zone C.

The design of the vertical casing, zone A, is “pipe in pipe”.

Inside the vertical casing to the right is a pipe 2 coaxially adjacent to the wall of the casing 1.

The pipe 2 has an open lower part, and the upper part is connected to the loading unit system. Inside the pipe 2 is located the auger transporting raw materials 3. The auger is driven by an electric drive 18.

The supply of raw materials to the transporting vertical screw 3 occurs through the metering horizontal screw 4, where it is impregnated with the liquid supplied through the nozzle 5 (from the collector 16 after the squeezing screw 14) for preliminary impregnation of the raw material. The metering auger is driven by an electric drive 17. The flow rate of the liquid for preliminary impregnation of the raw material is measured by the flow meter 37.

To heat the mass of raw materials to the extraction temperature on a horizontal metering screw 4, a heating jacket 4a is made, which has two fittings for supplying and removing heat carrier 19 and 20. To prevent the screw from skewing, a support 25 is provided.

In the metering screw 4, the raw material comes from a cone-shaped hopper 6 to load the raw material, where it is loaded in dry form.

On the hopper 6, a two-position sensor-relay of level 31 is installed, which, when the raw materials reach the upper or lower level in the hopper, sends a corresponding signal to the drive. The lower part of the hopper is combined through a flange connection with the metering screw 4.

The vertical case - zone A - is closed by a lid and a pulsation chamber 7, a pulsating conduit 8 are installed on it.

The pulsation chamber 7 is designed to transmit air pulses to the working mass in the device.

The air is supplied by the compressor 32 through the valves 33. The valves are controlled by a timer 34.

In the vertical part of the body, the liquid extract is collected. Zone A is also a pulse conduit, an air-liquid zone. In the liquid-solid contact zone, in the section of the pulsation chamber — zone A, where the extract is collected, there is a temperature sensor 35 for measuring temperature and a regulator 36 for regulating the set temperature for each type of raw material separately.

In the same part of the body - zone A - there is an extract selection unit.

The extract sampling unit is made in the form of a fitting with a thread 9 and is located on the pulsation chamber of zone A. The knot includes an integrated filter 10 for trapping particles of raw materials that have fallen into the pulsation chamber as a result of hydraulic vibrations. The filter 10 is a perforated cylinder, covered with a mesh, which is inserted into the nozzle 9. The filter is self-cleaning, due to oscillatory movements of the fluid in the pulsation chamber. It is possible to mechanically clean the filter, which is performed when the device is turned off.

Zone B - extraction column 11 - a hollow cylindrical tank, located mainly at an angle of 45 ° relative to the unit for transporting raw materials to the apparatus. Moreover, in the case of increasing or decreasing the angle of inclination of the extraction column 11, the efficiency of the intended use of the device is reduced. To maintain the operating temperature in the range of 20-90 ° C (depending on the type of plant material), shirt 12 was made for the circulating heat carrier - water. The shirt has fittings for the inlet and outlet of the coolant 21 and 22.

In the upper side of the extraction column 11 is a nozzle 13 for supplying extractant.

The main purpose of the nozzle is the uniform distribution of the extractant supplied to the counterflow of raw materials. The extractant flow rate is measured by a flow meter 38.

The extractant is the liquid after squeezing the meal, which comes from the collection 16 to the nozzle 13.

The unloading unit consists of a squeezing screw 14 connected to the extraction unit through a nozzle 15. The turns of the screw can be perforated to ensure high-quality washing of the raw material during the spinning process

The extracted raw material enters the auger, where water is also supplied for washing through the nozzle 26. The amount of water spent on washing is measured by a flow meter 39.

After washing and spinning, the liquid is discharged through the nozzle 27 to the collecting tank 16 and, after filtration, is fed to the raw material impregnation at the loading unit — to the metering screw 4, and to the unit power supply — to the extractant supply nozzle 13.

The washed meal is taken through the pipe 28. The collecting tank 16 is made with a heating jacket 29, which has the inlets and outlets of the coolant 23 and 24. Also, the technological fitting 30 is provided in the tank 16.

The inventive device operates as follows.

The crushed plant material in dry form enters through the lower part of the hopper 6 into a horizontally located metering screw 4, where it is pre-soaked in a certain amount of liquid.

The fluid flow rate is measured by the flow meter 37, and the feed rate is controlled using a two-position sensor-relay level 31.

With the horizontal metering screw 4, the wetted feed is transferred to the transporting vertical screw 3, which moves the feed from top to bottom in the extraction column 11.

This method of mass supply prevents the loss of ripple energy in the nodes of transportation of raw materials. Resistance is created by a layer of raw material on the turns of the screw.

The raw material enters the extraction column 11 and moves to its upper part. At the same time, through the feed unit, made in the form of a nozzle 13, the extractant enters the extraction column in an amount corresponding to the technological regulations.

Pulsator 7 with a drive into the system serves pneumatic pulses of compressed air, which cause the raw materials to move in the extraction column 11 in countercurrent to the incoming extractant.

The pulsation chamber 7 is designed to transmit air pulses to the working mass in the device.

Conventionally, the pulsation chamber is divided into three zones, smoothly passing one into another, namely, the compressed air / gas supply zone, the air-liquid contact zone (zone A), the liquid-solid contact zone (zones C and B).

The compressed air / gas supply zone is the interface between the pulse conduit 8 and the pulsation chamber 7. The diameter of the pulsation chamber in this zone does not exceed 1/3 of the diameter of the extraction column, this is necessary for uniform distribution of the pulse of compressed air over the cross-sectional area.

The air-liquid contact zone is the section of the pulsation chamber in which the transfer of pulse energy directly to the surface of the liquid takes place. The main condition for efficient operation is the uniform distribution of the momentum over the surface of the liquid.

This is the section of the pulsation chamber - zone A.

The liquid-solid contact zone is the section of the pulsation chamber in which the transfer of pulse energy from the liquid to the solid occurs. The main purpose of this zone is to impart directional movement of the solid fraction in a countercurrent to the extractant under the influence of pulses. This is sector-zone C.

In zone B, the wetted material moves in countercurrent to the extractant under the influence of pulses. The frequency and duration of the pulses is regulated by a timer 34. The meal is discharged through a squeezing screw 14 connected to the extraction unit through a pipe 15.

The obtained extract continuously enters the extraction selection zone, made in the form of a fitting with a thread 9, located in zone A of the pulsation chamber.

The meal is discharged through the squeezing screw 14 connected to the extraction unit through the pipe 15.

The screw turns are perforated to ensure high-quality washing of the raw material during the spinning process.

The meal enters the squeezing auger, where water is also supplied to rinse the meal through the nozzle 26. The amount of water spent on rinsing is measured by the flow meter 38. After washing and spinning, the liquid is discharged through the nozzle 27 into the collecting tank 16 and, after filtration, is fed to the impregnation of raw materials in the loading zone, namely, the dosing horizontal screw 4, where it is impregnated with the liquid supplied through the nozzle 5 for preliminary impregnation of the raw materials and to the nozzle 13 into the extraction column 11. The meal is taken through the nozzle 28. After pressing, the liquid enters the ba K-collector 16. The tank-collector 16 is made with a heating jacket 29, which has fittings for supplying and discharging the coolant 23 and 24. Also, a technological fitting 30 is provided in the tank 16.

The washed raw material is taken through pipe 28.

On the proposed device, the process of extraction of licorice root, immortelle sand, herb marshmallow, hops, buckwheat husks, larch bark, amaranth, pine bark, chaga was carried out.

Comparative indicators of extraction are given in table 1.

As can be seen from table 1, the claimed device provides a high degree of extraction (above 90%) in less time (2 times) than in the closest analogue, which corresponds to the claimed technical result.

On the claimed device also carried out the process of extraction of chaga.

Chaga is a herbal medicinal product with a wide range of pharmacological effects. The main active ingredient in chaga water extracts is chaga polyphenols (polyphenoloxycarboxylic complex), the presence of which ensures the therapeutic efficacy of chaga water extracts.

Known methods for producing aqueous extracts of chaga:

- application RU 2007113965/15 of 04/02/2007, publ. 01/20/2009;

- application RU 2004107950/15 of March 19, 2004, publ. 09/10/2005.

All these known methods are multi-stage and include the extraction of raw materials in stages, with the extract of the first stage of extraction, then the second stage of extraction. Extraction is carried out at a temperature of 60-70 ° C for a long time. Extraction of the first stage for 4-6 hours, the second stage 4-6 hours.

The total extraction time for chaga is from 8 to 12 hours.

In the claimed technical solution, the extraction of chaga is carried out in the new claimed design of a device for extracting plant materials, the extraction process is carried out in a flowing and pulsating mode, the raw materials are supplied in countercurrent to the extractant in one stage, and at the same time they are affected by pulsation with a frequency in the range of 5-70 pulsations in minute (0.83-1.17 Hz) and power (pulse) in the range from 3 to 100 MJ / mol. Thus, the extraction time and the number of stages is reduced by 2 or more times.

Comparative results of the extraction processes in terms of temperature and process time are given in table 2.

As can be seen from the data of table 2, the claimed device provides a good degree of extraction of chaga (above 80%) and in less time (from 2 to 4-6 times) than in the known methods of extraction of chaga used in industry, which corresponds to the claimed technical result.

Thus, the processed raw materials from the moment they enter the loading zone are subjected to influences that characterize the essential features of the claimed method of operation of the device, necessary and sufficient for the implementation of the claimed method in the claimed device.

The basic block diagram of the process of extraction of plant materials is shown in figure 2.

The design advantages of the claimed technical solution are:

1) the design of the device is “V” -shaped with an angle of inclination of 45 °, which eliminates the formation of a dense layer of the supplied raw materials into the extraction column located in the inclined housing. The dense layer violates the hydrodynamics of the process;

2) loading of raw materials through a system of screws transferring raw materials from the loading hopper directly to the lower part of the extraction chamber, which allows, under the influence of pulses supplied by the pulsator, to form a layer of extracted raw materials only in the extraction chamber, which does not interfere with the impulse in the form of "traffic jams" from floating materials;

3) the location of the extract extraction zone is significantly higher than the feed supply zone and the installation of a self-cleaning filter eliminates the entrainment of particles of the loaded feed through the loading zone to the extract selection zone, which eliminates clogging of the extract extraction unit;

4) the extracted material from the extraction chamber is transferred to the squeezing screw, and the final extraction together with washing carried out in the squeezing screw helps to reduce the resistance of the meal during unloading, thereby increasing the efficiency the claimed technical solution.

High extraction efficiency in the device is achieved due to the fact that it implements:

- countercurrent movement of phases,

- overlay on the general flow of pulsations,

- one-stage continuous supply of raw materials in a pre-moistened form directly into the extraction column,

- lack of stagnant zones,

- lack of high resistance during unloading,

- the absence of the need for mechanical mixing of the raw material in the extraction process provides an increase in the quality of the extract,

- carrying out the final extraction in the squeezing screw,

- washing the meal before unloading provides an increase in efficiency extraction process

- reuse of waste liquid for wetting the raw materials and extraction leads to a decrease in material and energy costs.

Thus, the proposed device allows 2-4 times to reduce the extraction time, reduce the consumption of extractant, increase the yield of extraction products (efficiency of a technical solution while reducing its material consumption and energy intensity).

The claimed technical solution meets the criterion of "novelty" presented to the invention, since the claimed combination of features is not known from the analyzed prior art.

The claimed technical solution meets the criterion of "inventive step" for inventions, since the claimed technical solution is not obvious to a specialist in the selected field of technology, since the implementation of mutually exclusive factors is ensured, namely, with a significant reduction in material, energy, time costs, a significant increase of controlled indicators characterizing the claimed technical solution.

The claimed technical solution meets the criterion of "industrial applicability" presented to the invention, since the claimed technical solution is implemented in a pilot sample using known materials and technologies.

Claims (4)

1. A device for the extraction of plant materials, containing a housing, a pulsator, a loading and unloading zone of raw materials, an extractant supply zone, an extract selection zone, a housing made in a V-shape, consisting of a vertical and inclined housing, in which the interaction of plant raw materials with the countercurrent extractant and when exposed to pulsations, characterized in that the vertical casing is made in the form of a pipe-in-pipe construction, comprising a conveyor screw in the inner pipe connected to the hopper from above supplying raw materials through a horizontal metering screw with a fluid supply unit made in the form of a nozzle, and from below the pipe is made open with the possibility of supplying raw materials to an extraction column located in an inclined housing containing an extractant supply zone and a raw material discharge zone made in the form of a squeezing screw, and the waste fluid collector is connected to the loading zone and the extractant supply zone located on the extraction column, while the extract selection zone is located above the feed zone to the extraction column. 2. The device according to claim 1, characterized in that a self-cleaning filter is installed in the extract selection zone. 3. The device according to claim 1, characterized in that the turns of the squeezing screw are made with perforation. 4. The method of operation of the device for the extraction of plant materials, which consists in the interaction of plant materials with the extractant countercurrent and under the influence of pulsations, characterized in that the feed process is pre-impregnated and fed directly to the extractor, extraction is carried out at a given temperature and subjected to pulsation with a frequency in the range of 5-70 pulsations per minute, 0.83-1.17 Hz and power (pulse) in the range from 10 ^-3 to 10 ^-2 MJ / mol in zone B, then the extract is taken in the extraction zone (zone A), but the spent raw materials are pressed and washed in the discharge zone, while the spent liquid after filtration is again fed to recirculation to wet the feed raw material into the loading zone and in parallel to the extractor for extraction.

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