RU159455U1 - GAS-LIQUID EXTRACTOR FOR VEGETABLE RAW MATERIALS - Google Patents

Abstract

1. A gas-liquid extractor for plant materials, comprising a cylindrical body with an upper self-sealing hatch, a nozzle for the upper supply of liquid solvent, a nozzle for the upper solvent outlet and a siphon tube for possible step-by-step miscellaneous discharge, characterized in that the extractor body is equipped with an external jacket for supplying a heating agent and has a conical bottom with a lower nozzle for miscella removal and a perforated cartridge with a filter cartridge. 2. The extractor according to claim 1, characterized in that the ratio of the height of the extractor to its diameter is five. 3. The extractor according to claim 1, characterized in that the ratio of the working height of the extractor to its total height is 0.75.4. The extractor according to claim 1, characterized in that the cell diameter of the perforated cartridge is 15-20 mm

Description

The utility model relates to the field of complex processing of plant materials and can be used to obtain vitamin-containing complexes and food additives.

The known design of the installation for producing CO ₂ extracts (patent RU 2041254), containing a condenser, storage-pressure tank, extractor, miscella distiller, extract collector, cylinder with liquid carbon dioxide, supply of gaseous carbon dioxide to the lower part of the extractor, liquid dioxide supply carbon to the lower and upper parts of the extractor, pipelines of liquid carbon dioxide and gaseous carbon dioxide, pipelines of miscella, pipelines of the extract, inspection lamp, valve connecting the pipeline to the top it is part of the extractor, a valve that must be closed when cleaning the filter in the extractor, a valve, by opening of which the pressure in the extractor is released on the gas holder, the heat jacket. All devices are connected by pipelines in the gas and liquid phases, respectively, and are cascaded in both the gas and liquid phases.

The disadvantage of this design is the extraction without filtering miscella. The removal of solid particles is carried out by filtering the finished extract, which complicates the process, increases the loss of the finished product and reduces the yield.

The known design of the installation for gas-liquid extraction (patent RU 2205866, 06/10/2003), containing a condenser, storage tank, extractor, miscella storage evaporator, tipping mechanism of the extractor with a control panel, carbon dioxide supply pipe, safety device, pressure gauges, gaseous pipe carbon dioxide, liquid carbon dioxide pipelines, high pressure flexible hoses, vaporized carbon dioxide piping, inspection lamp, piping for discharge into the gas holder and atmosphere, self-sealing hatch of the extractor, valve separating liquid and gaseous carbon dioxide.

The disadvantage is the lack of filtration of miscella, which leads to increased loss of the finished product, and since the extraction process is carried out using a flowing solvent, the duration of the extraction process increases due to the low driving force.

Closest to the claimed design of the extractor is the design of the extractor, (Tarasov V.E. Technology of essential oils and herbal remedies: a study guide / Kuban. State technological university. - Krasnodar: Publishing house of FSBEI HPE "KubSTU", 2013. - 404 p. (P. 363)), which is a cylindrical container with upper and lower self-sealing hatches, nozzles for the upper and lower liquid solvent supply, nozzles for the upper and lower solvent outlet, and a siphon tube for possible miscellaneous discharge. This design allows extraction, both by immersion of the raw material in the solvent, and by irrigation, and to carry out step change of the solvent, which ensures maximum moving force of extraction. The disadvantage of this model is the lack of filtration of solid particles from miscella.

The objective of the utility model is to improve the gas-liquid extractor for plant materials, which allows to improve its operational characteristics and increase the degree of extraction of biologically active substances from plant materials.

The technical result of the utility model is to reduce solvent consumption, reduce losses of the finished product and increase its yield.

The technical result is achieved in that a gas-liquid extractor for plant materials, comprising a cylindrical body with an upper self-sealing hatch, a nozzle for the upper supply of liquid solvent, a nozzle for the upper solvent outlet and a siphon tube for possible step-by-step discharge of the miscella, while the extractor case is equipped with an external supply jacket heating agent and has a conical bottom with a bottom fitting for miscellaneous drainage and a perforated cartridge with a filter cartridge. The ratio of the height of the extractor to its diameter is five. The ratio of the working height of the extractor to its total height is 0.75. The diameter of the cells of the perforated cartridge is 15-20 mm.

Reducing losses and increasing the yield of the finished product is due to a more complete extraction of the extractives, which is ensured by the organization of the extraction process with a pure solvent at each degree of extraction, as well as the elimination of losses during filtration of the finished extract, replaced by filtration of miscella during the extraction process.

Reducing the consumption of solvent occurs due to the transfer of its part from one extractor to another at the stage before unloading the extracted material and heating the raw material in the extractor to an initial pressure, which ensures evaporation of a part of the solvent and its subsequent condensation.

An increase in the degree of extraction of substances from plant materials occurs through the use of a perforated cassette with a cell diameter of 15-20 mm, since it is precisely such a cell diameter that allows more complete washing of the particles of the feed with carbon dioxide in the extraction process.

The figure 1 shows a gas-liquid extractor for plant materials.

The gas-liquid extractor for plant materials consists of a cylindrical body 1, an outer jacket 2 with a nozzle 3 for supplying a heating agent to the outer jacket and a nozzle 4 for draining the heating agent, a perforated cartridge with a filter cartridge 5, the diameter of the cells is 15-20 mm, the lower nozzle 6 for discharging miscella, a three-way valve 7 for direct discharge of miscella and discharge through a siphon tube 8 of pipe 9 connecting the extractor to the evaporator, pipe 10 for the upper supply of liquid solvent, pipe 11 for the upper pipe the gas phase of the solvent and the atmosphere, a self-sealing hatch 12 of the extractor, a solvent distributor 13, and a pipe 14 for connecting the upper free space of the extractor with the evaporator.

To ensure longer contact of the solvent with the extracted material when filling the extractor with solvent, the ratio of the height of the extractor to its diameter is five.

The ratio of the height of the working zone of the extractor to its total height is 0.75. This is explained by the need for free gas space in the upper part of the extractor for the operation of miscella siphon overflow.

The extractor works as follows: the raw material prepared for extraction (croup or petal) is placed in a perforated cartridge with a filter cartridge 5 with a mesh diameter of 15-20 mm in a continuous bag of belting filter fabric, which is loaded into the cylindrical case of the extractor 1 and the self-sealing hatch 12 is closed Next, through the pipe 14 to connect the upper free space of the extractor with the evaporator, the gas phase of carbon dioxide is supplied to the extractor to displace air, which is removed through the pipe 11 for the upper twater gas phase solvent. A three-way valve 7 is installed on the miscella outlet through a siphon tube 8 and through the nozzle 10 for the upper supply of liquid solvent to the extractor, the supply of solvent begins. In this case, the extraction process is carried out by irrigation with filling the extractor to the height of the siphon tube 8. When the solvent fills the space of the extractor to the level of the siphon tube 8, the extraction process begins by immersion. As soon as the solvent reaches the height of the siphon tube 8, the miscella is automatically poured through the siphon tube 8 into the evaporator. The free flow of the miscella from the extractor to the evaporator is ensured by the connection of the gas zone of the extractor with the evaporator using a pipe 14 for connecting the upper free space of the extractor with the evaporator.

The extraction process is carried out stepwise with the change of miscella at each stage, which ensures the maximum difference in the concentrations of extractives in the material and miscella, and therefore ensuring the maximum extraction rate.

After the extraction, the remaining miscella is poured into the evaporator from the lower pipe. 6 to drain miscella using a three-way valve 7 and a pipe 9 connecting the extractor and the evaporator. The three-way valve 7 is closed. The pressure in the extractor is discharged by half to a parallel extractor of the installation through the pipe 11 for the upper outlet of the gas phase of the solvent.

A heating agent is supplied to the outer jacket 3 and the temperature rises in the extractor, while the pressure rises to the initial value and the gaseous solvent passes through the pipe 14 to connect the upper free space of the extractor with the evaporator to the condenser. This process avoids loss of solvent during unloading. Removing the solvent from the extractor, through the pipe 11 for the upper outlet of the gas phase of the solvent, the pressure in the extractor is relieved by communication with the atmosphere. The self-sealing hatch 12 is opened and the perforated cartridge with the filter cartridge 5 with extracted raw material is removed and replaced with a new one, the process continues.

Thus, the proposed design of a gas-liquid extractor for plant materials allows the extraction of raw materials by irrigation and immersion with a cross flow of solvent providing the maximum driving force of the extraction process, combine the extraction and filtration process, achieve the most complete extraction of biologically active substances from the raw materials, reduce the extraction time, reduce loss of solvent due to the possibility of raising the temperature in the extractor before unloading it.

Claims (4)

1. A gas-liquid extractor for plant materials, comprising a cylindrical body with an upper self-sealing hatch, a nozzle for the upper supply of liquid solvent, a nozzle for the upper solvent outlet and a siphon tube for possible step-by-step miscellaneous discharge, characterized in that the extractor body is equipped with an external jacket for supplying a heating agent and has a conical bottom with a lower nozzle for miscella removal and a perforated cartridge with a filter cartridge. 2. The extractor according to claim 1, characterized in that the ratio of the height of the extractor to its diameter is five. 3. The extractor according to claim 1, characterized in that the ratio of the working height of the extractor to its total height is 0.75. 4. The extractor according to claim 1, characterized in that the cell diameter of the perforated cartridge is 15-20 mm

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