RU75953U1 - EXTRACTOR-CENTRIFUGA - Google Patents

Abstract

Extractor centrifuge. The invention relates to the construction of mass and heat exchangers and can be used in the field of extraction and concentration of impurities. The objective of the utility model is to increase the efficiency of mass transfer processes, improve operating conditions, expand the field of use, simplify the design and reduce the size. The problem is solved in that the extractor-centrifuge containing the housing with the input and output tubes of the contacting mixtures fixed to it, the rotor is made in the form of coaxially arranged extraction, separation and filter cups, the extraction cup is equipped with a stirrer and a removable lid, in which the extraction, separation and filter cups are made with the possibility of giving them angular rotational speeds that are not connected to each other, the elements in contact with the processing mixtures are made light osemnymi and provided with interchangeable nozzles. The predominant implementation of the "extractor-centrifuge", when the extraction cup is equipped with a separation ring with filter elements, and the output tube is mounted movably on a rotating separation and filter cups. The proposed design allows optimized processing of both liquid and solid substances, with different physicochemical properties and different volumes of processed mixtures.

Description

The invention relates to the field of extraction and concentration of impurities and relates to the design of centrifugal mass and heat exchangers used in sample preparation for determining the content of pollutants in environmental objects, can be used in industry for separation and concentration by liquid and solid phase extraction, centrifugal liquid chromatography, as well as for microbiological processes and heterogeneous reactions.

The prototype is an extractor-centrifuge, (book: Concentration of traces of organic compounds. Problems of analytical chemistry, T.X. - M .: Nauka. 1990. p.110, Fig.9), containing a housing, inside of which, at the bottom, there is a drive , on the axis of which a rotor with a cover is mounted, a replaceable bucks with an extraction cup are placed inside the rotor; suction tubes with a clamp are installed on the rotor cover.

The disadvantage is the low efficiency of mass transfer processes and operating conditions, a narrow area of use, design complexity, large dimensions.

The objective of the utility model is to increase the efficiency of mass transfer processes, improve operating conditions, expand the field of use, simplify the design and reduce the size.

The task is achieved in that the extractor-centrifuge, containing a housing with tubes for input and output of contacting mixtures fixed to it, a rotor made in the form of coaxially arranged extraction, separation and filter glasses, the extraction cup is equipped with a stirrer and a removable lid, according to the utility model extraction, separation and

the filter cups are configured to give them angular rotational speeds that are not connected to each other and in contact with the processing mixtures, the extraction cup being equipped with a separation ring with filter elements, and the output tubes are mounted movably on the rotating separation and filter cups.

The solution of the technical problem allows for highly efficient interaction of the processed mixtures, optimization of extraction, centrifugation and separation processes, the use of the apparatus for both liquid and solid samples, both for individual and for sample flow.

The use of an individual adjustable drive for glasses, filter and separation, provides the ability to control centrifugal pressure forces along the radius of the rotor and the placement of the filter element on the periphery of the rotor. This allows the selection of liquid phases by pump tubes at a lower pressure than the existing extractor, which in turn allows to reduce the solvent spray and emulsification of mixtures. This creates a more favorable soft mode of extraction of the rotor of the liquid due to the significantly smaller difference in the speeds of rotation of the glasses compared with the selection of the tube mounted on a non-rotating cover of the apparatus, which is very important for the separation of easily emulsified systems.

In Fig.1 shows the basic design of a uniaxial extractor, in Fig.2 and 3 - biaxial arrangement of contacting elements. Figure 4 provides assembly options for the contact and packing elements placed in the filter and separation rings:

IV - 1 - filter ring with perforation and filter element;

IV - 2 - filter ring with a suction tube fixed to it and a filter element;

IV - 3 - separation ring with shoulder;

IV - 4 - separation ring with a drain pipe;

IV - 5 - the filter ring is equipped with a solid sorbent;

IV - 6 - the filter ring is equipped with a conical filter tube;

IV - 7 - the separation ring is made two-chamber,

The extractor-centrifuge (Fig. 1) consists of a rotor made in the form of coaxially arranged: interchangeable extraction cup 1 with a tray 2, and a separation ring 3, filter and separation cups 19 and 20 with rings 4 and 5, respectively, the apparatus body 6, covers 7, movably fixed tubes of the input 9, output 8 on it and the drives 11, 12 and 13 of the mixer 10, filter and separation glasses, respectively. The rotation is transmitted from the drives to the contact elements of the apparatus by means of detachable "bayonet" type connectors or detachable couplings. Bearing 15 consists of coaxially mounted bearings. For spraying the incoming liquids into the extraction cup 1, the shaft 18 of the drive 11 of the mixer 17 is made hollow.

Figure 2 and 3 presents the basic design of a biaxial extractor-centrifuge, in which the extraction cavity 21 is equipped with contact elements 20 and is made in the form of a centrifuge, and the separation and filter rings are equipped with an extraction cavity 22.

Figure 4 presents options for various contact elements in both the filter and separation rings, depending on the type of processed systems and sample preparation techniques.

Extractor · centrifuge (figure 1) works as follows.

Depending on the type of sample being processed, appropriate rotor replacement kits are installed: for processing a solid sample - solvent - a kit for separating a solid sample and solvent, for

liquid-liquid systems — a kit for separating and removing both phases and the rotor; for multiple extraction, a kit is used to irrigate a sample, mix or recycle one of the phases. Variants of assembly kits and the corresponding organization of flows are presented in figure 4.

1. Processing of a solid phase and a small volume of solvent.

The prepared sample with solvent is placed in the extraction cup 1, closed with a separation ring 13 and installed in the pan 2, closed with a lid 7 and the drive 11 of the mixer 10 is turned on. At the end of the mixing process, the drive 11 is turned off and the drives of the extraction cup of the separation and filter cups 11, 13 and 14, respectively. Under the action of centrifugal force, the solid phase moves in the direction of the radius, forms an annular layer, the inner surface of which is established in the form of a parabolic shape. The liquid phase is removed through the radial holes of the separation ring 3 into the subsequent filter and separation nozzles of the respective glasses, passing sequentially in the radius direction through the contact elements. The purified solvent is discharged from the apparatus through the corresponding outlet tubes 8. At the end of the operation of the extractor-centrifuge, the drives 12, 13 and 14 are turned off, the lid 7 is folded out, the cup 1 is removed, the next one is installed, the lid 7 is closed and the device is ready for operation.

2. Processing of solid samples with a large amount of solvent.

The operation process is similar, and the liquid phase flows with a certain flow rate from the pressure vessel through flexible tubes through the tube 9 to the extraction cup 1. When fed through the shafts 18 and 17 of the mixer, the solvent is sprayed into the cup while the entire mixture is mixed. If it is necessary to reduce the entrainment of the solid phase by the liquid, the extraction cup is rotated, then the solid phase is evenly distributed along the walls of the glass, liquid

the mobile phase in the form of a film or jets washes the solid phase, then the process is similar to the previous one.

3. Phase recirculation.

For the process of recirculating one or both liquid phases, the outlet suction tubes are respectively connected to the inlet tube of the extraction cup, then the liquids will again flow into the extraction cup.

4. Processing a large volume of liquid mixtures.

The work is carried out by feeding phases with a certain flow rate from the pressure vessels to the extraction cup 1. Stirring (extraction) is carried out both with a rotating extraction cup and stationary. In the latter case, the phases are mixed with a stirrer and, as the cup 1 is filled, are poured into the filter cup 4 by gravity or under the action of centrifugal forces. In filter bowl 4, the mixture is separated by a membrane or porous septum. After separation, the liquid phases are removed from the apparatus using the output tubes 9. At the end of the process, the working surfaces, if necessary, are washed with distilled water or solvent with the apparatus operating; without disassembling it.

5. Processing a small volume of liquid mixtures.

The process is similar to processing a solid sample with a small amount of solvent, and the liquid phases are automatically removed by suction tubes.

6. Multiple extraction.

The process is similar to processing a sample with a large volume of solvent. A liquid sample is continuously withdrawn as it arrives from the pressure vessel at a certain flow rate, and a solid or liquid sample is removed at the end of the process.

Thus, by varying interchangeable elements and adjusting to a given operating mode of the extractor-centrifuge, it is possible to process samples of a wide range of physico-chemical

parameters, types and volumes of samples, both single and stream of individual or homogeneous samples.

All of the above modes were tested on experimental samples of a centrifuge extractor in methods for analyzing environmental pollution (soil, water, vegetation, food, bioobjects) for environmental monitoring purposes.

According to the results of processing the object revealed the following advantages of the centrifuge extractor compared with the prototype.

an increase in the efficiency of mass transfer processes due to the uniform loading of contact devices;

- improvement of operating conditions;

- expanding the scope of use for liquid, solid individual samples, and for the flow of homogeneous and heterogeneous samples;

- simplification of the design and reduction of dimensions, which allows it to be used in mobile analytical laboratories.

Claims (3)

1. An extractor-centrifuge containing a housing with tubes for input and output of contacting mixtures fixed to it, a rotor made in the form of coaxially arranged extraction, separation and filter glasses, the extraction glass is equipped with a stirrer and a removable lid, characterized in that the extraction, separation and filter glasses made with the possibility of giving them unrelated angular speeds of rotation in contact with the processing mixtures. 2. The extractor centrifuge according to claim 1, characterized in that the extraction cup is equipped with a separation ring with filter elements. 3. The centrifuge extractor according to claim 1, characterized in that the output tubes are mounted movably on rotating separation and filter cups.