SU1754142A1 - Extractor for solid-liquid system - Google Patents

Abstract

Use: in food, microbiological, pharmaceutical, chemical and other industries for the extraction of substances from solids with liquids, in particular from plant raw materials and its grains or seeds, containing medicated oil preparations. SUMMARY OF THE INVENTION: The extractor is provided with a forced circulation circuit of liquid gas containing a vertical central pipe and a pump. The pump inlet is connected to the extractor volume and the outlet is connected to a central pipe. The unloading device includes nozzles for supplying an evacuating liquid and withdrawing the evacuated mixture. The central tube is provided with longitudinal flow dividers with through windows. 1 hp ff, 2 slug, y

Description

The invention relates to mass transfer devices and can be used in food, microbiological, pharmaceutical, chemical and other industries for the extraction of substances from solids with liquids, in particular From plant raw materials and its grains or seeds containing medicinal oil preparations. .

A known apparatus for carrying out mass-exchange processes in a solid-liquid system contains a vertical body with loading and unloading devices, pipes for supplying and discharging liquid, a vertical rod with a crank drive vibration actuator, transverse perforated partitions with a cut forming gaps , and between partitions and the body, mounted on a rod with alternating inclination to each other.

The closest in technical essence and the achieved result is a column extractor containing a vertical cylindrical body divided into zones of mixing and exfoliation of the interacting phases and provided with a lid and a conical bottom. Asymmetrically to the axis of the housing in the mixing zone, a shaft with disk agitators is installed, and the delamination zone is provided with a nozzle of strips located at the disk at an angle of 90-120 °, and the magnitude of this angle has a significant effect on the entrainment of the solid phase with miscella.

The extractor works as follows.

The source material is fed to the upper part of the housing in the mixing zone, in which the shaft with agitators is located. In the lower part of the body (the same zone) countercurrent

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an extractant is fed to the starting material through the nozzle, which ascends through the nozzles to reduce the flow turbulization and, therefore, the entrainment of solid particles.

The shaft with disk agitators ensures an even distribution of the solid phase over the cross section of the housing. The solid phase is moved from top to bottom under the influence of the force of gravity, and the extractant, saturated with the target substances, moves from bottom to top. The solid phase condensation occurs in a phase separation zone, each of which is discharged through the corresponding nozzles. Vapors and gases formed in the process are removed through a nozzle in the top of the extractor.

The disadvantages of the known column extractor are high metal intensity, design complexity, low productivity, primarily due to incomplete extraction of the target components, as well as entrainment of part of the fine solid phase. In addition, the extractor is not suitable for a process in which the density of the extractor is higher than the density of the solid phase, and the presence of mixing devices and nozzles in it creates certain difficulties in operation, maintenance and repair, selection of optimal flows of interacting media.

The purpose of the invention is to increase the productivity and degree of extraction of the target components by conducting the process in the suspended layer, reducing operating costs.

This is achieved by the fact that the extractor containing a vertical cylindrical body with a cover and a bottom, inside which the mixing and exfoliation zones are located, fittings for input and output of reagents, a device for unloading waste raw material, is equipped with a forced circulation circuit for liquid gas containing a vertical central pipe installed coaxially and with a gap to the housing cover, and the pump, the inlet of which is connected to the volume of the extractor, and the outlet to the central tube. In this case, the device for discharging waste material includes pipes for supplying the evacuating liquid and withdrawal of the evacuated mixture, installed respectively in the lower and upper parts of the apparatus, and the central pipe is provided with longitudinal flow splitters with through holes.

FIG. Figure 1 shows an extractor for a solid-liquid system (longitudinal section) with a circulation loop; in fig. 2 is a section A-A in FIG. one.

The extractor includes a body consisting of a spherical cover 1, a cone 2, a cylindrical shell 3, a conical adapter 4, a dilator 5 and a bottom 6. Through

5, the center of the body is passed through the pipe 7 with the cutters 8, installed with a clearance relative to the spherical cap 1, and the lower part of the pipe 7 is connected by a pipe 9 with a pump 10, the suction nozzle of which is connected by a pipe 11 with a fitting 12 on the bottom 6, and pipe 11 is connected to line 13 for supplying fresh extractant. The expander 5 is equipped with a manhole 14, and the bottom 6 with a fitting 15 for supplying the evacuating liquid and washing the extractor, and a conical adapter L with a fitting 16 for feeding the initial solid phase. The spherical cap 1 is provided with fittings 17.18 and 19 with a valve for withdrawing waste

0 mixture for removal of the evacuated mixture and for connection with a vacuum line, respectively. A spare fitting 20 is installed on the bottom 6. The extractor is equipped with a jacket 21 for supplying coolant to it through

5 fitting 22 and withdrawing it through fitting 23. On line 13 a valve 24 is installed, and on the cone 4 and the expander 5 - one spare fitting 25 each. Line 26 denotes the boundary of the phase separation, which separates the mixing and delamination zone, and The vertical position depends on the speed (volumetric flow rate) of the downstream liquefied gas stream. The dividers 8 are provided with holes 27.

5 The extractor is a multipurpose device capable of carrying out the process of extraction in a solid-liquid system at various ratios of their thermophysical properties, in particular

0 of the density of the interacting phases, which allows us to consider the limiting variants of the operation of the extractor, namely:

- the moment of starting, operating and stopping the extractor when carrying out the extractor from

5 previously prepared (cleaned and crushed) raw material (meal), the density of which (1000 kg / m3) is lower than the density of the extractant, for example, freon - 22. constituting 1300 kg / m3;

0 - the same, but provided that the density of the extractant is less than the density of the meal.

Option number 1 (the density of the extractant is greater than the density of the meal).

After filling the extractor with meal

5 through fitting 16 and vacuuming through fitting 19 through line 13 and 11 with pump 10 through line 9 and pipe 7 fill the volume of the extractor with liquefied gas, after complete filling of which the circulation of liquefied gas begins to circulate through the circulation loop. Due to the fact that the meal has a lower density than liquefied gas, it tends to collect in the upper area of the extractor: a mixing zone that is limited by the volume of the spherical cover 1, cone 2, cylindrical shell 3 and conical adapter 4. Regulating the speed (volume flow) of the liquefied gas gas, it sets the optimum flow rate, which provide stretching the layer of meal along the mixing zone and obtaining a suspended layer. It is the suspended layer of meal in the volume of the extractor that guarantees the uniform washing off of each solid particle by the extractant, which significantly intensifies the process of extracting the target components. In the separation zone, which can conditionally be at the level of line 26 (Fig. 1), due to the sharp increase in the cross-sectional area of the expander 5, there is a significant decrease in the speed of the downward flow of liquefied gas, which ensures separation of the interacting phases.

As a result, the solid phase is not carried out in the delamination zone, which ensures only the circulation of the liquefied gas without trapping the solid phase.

In order to prevent excessive turbulization of the streams and the occurrence of its twisting along the longitudinal axis, the tube 7 is equipped with stabilizers 8, which are connected with the elements of the extractor body 2,3, and the holes 27 provide for the interconnection of the sectors of the extractor in the mixing zone.

Monitoring the intensity of the extraction process can be carried out (based on empirical data) by time or by determining the content of the target components in the extractant, or by a density meter or other methods, which can serve as a signal to start unloading the mixture of meal with the liquid phase, which is carried out through fitting 17 and it is sent for further separation into its components: meal, gas, target components. The start of the discharge is a signal for feeding the meal through the fitting 16 and feeding the system with fresh liquefied gas through line 13 through valve 24, line 11 and further through pump 10, line 9 and pipe 7 to the extractor.

The highest mass transfer efficiency depends not only on the relative speed of interaction (movement) of the solid and liquid phases, but also on the concentration of the already extracted components in the liquefied gas. Therefore, maintaining (regulating) the necessary conditions for maximum efficiency of the process,

those. the volume flow rate of the circulating gas (hence, the flow rate of the particle) and the concentration of the target components in the liquid phase (by increasing or decreasing the system feed with liquid gas) achieve the maximum extraction performance.

If necessary, stop the extractor off the pump 10 and through the nozzle 20

0, the liquid phase is drained, which is directed to the separation of the gas-target component. The solid phase remaining in the extractor can be evacuated after the extractor is heated by feeding the jacket 21 through the core 22 and discharging the heat carrier through the nozzle 23 to distill the remaining gas by feeding through fitting 15 evacuating fluid (eg water) and removal of a mixture of water and solids through

0 fitting 18, which is more rational and contains a novelty and usefulness of the method /, which significantly speeds up this process and, consequently, increases the useful fund of the extractor’s working time, and also in an environmentally friendly way that allows the use of waste meal in As a feed additive in animal husbandry, Periodic shutdowns of the extractor must also provide for the complete regeneration of the internal surfaces of the regenerating fluid, which can be done or simply filled I eat it extractor through socket 15, and when

5 is necessary by switching on the circulation circuit with subsequent discharge of the regenerating liquid through the nozzle 20.

Option number 2 (extra gravity density below the density of meal).

0 When implementing the extraction process in a solid-liquid system, provided that the density of the solid phase is higher than the density of the extractant shown in FIG. It is enough for 1 extractor design to return by 180 °, i.e. the spherical cover 1 with the housing 2 should become the lower zone of the apparatus, and the conical adapter 4 with the expander 5 the upper zone. In this case, the upward flow of liquefied gas fed through pipe 7 raises the solid phase that tends to precipitate along the entire mixing zone, which ensures that the extraction process is also carried out in a suspended layer with all the consequences

5 of this positive results. In this case, the roles of the extractor nozzles change: the nozzle 20 should be connected to the vacuum line, and one of the nozzles 25 on the expander 5 or cone 4 should be used (depending on the height of the suspended layer) to drain the spent meal mixture with the liquid phase, in the case of heating, the extractor, if it is stopped, should be supplied via flushing 23 for flushing and regeneration, and discharged through choke 22.

The advantage of the extractor is the complete extraction of the target components from the raw material, along with an increase in the working time and productivity of the apparatus due to the process in the suspended layer, which allows to obtain the yield of the target components from 90 to 95% of the maximum possible, the simplicity of the extractor design (a typical tank with a circulating circuit and a pump, which allows refusing inefficient nozzles, rotating brown and curved-connecting rod mixers), i.e. lower capital, energy and operating costs for obtaining a unit of target components.

Claims (2)

Claim 1. An extractor for a solid-liquid system containing a vertical cy- Lindrical housing with a lid and a bottom, inside of which there are mixing and delamination zones, reagent inlet and outlet nozzles, a device for unloading waste raw material, characterized in that, in order to increase productivity and degree of extraction of target components by carrying out the process in a suspended layer, reducing operating costs, the extractor is equipped with a circuit for the forced circulation of liquid gas containing a vertical central tube installed coaxially and with a gap to the housing cover, and a pump, an inlet otorrhea volume is connected to the extractor, and the output - to the central tube. 2. Extractor pop. 1, excluding the batch so that the device for unloading the waste raw material includes nozzles for supplying the evacuating liquid and outputting the evacuated mixture installed respectively in the lower and upper parts of the apparatus, and the central pipe is provided with longitudinal flow splitters with through windows . e $ an (/ aci mixture " 23 W 1 17 О тра тра Н от от Aa 21 Fig 2