RU2804649C1 - Method for activating microdisintegration of polymineral component in slurry - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: proposed invention relates to the mining industry and can be used in the development of natural and man-made high-clay placer mineral deposits with an increased content of fine and fine gold. The method of cavitation-hydrodynamic microdesintegration of the polymineral component of the hydraulic mixture includes high-speed pumping of a jet onto the flat surface of the divider into a hydrodynamic generator made with a diffuser and a confuser housing, processing of the flow of the hydraulic mixture under conditions of active hydrodynamic influences by means of the influence of dividers sequentially installed in the center of the confuser housing to ensure deep disintegration of the polymineralthe component of the hydraulic mixture to the micro level by converting the kinetic energy of the fluid flow in a hydrodynamic generator. Zones are formed that contribute to the strengthening of hydrodynamic oscillations by performing dividers in the form of a monolithic system of interconnected hydrodynamic single-cavity hyperboloids. To give the hydrodynamic generator additional structural rigidity, the confuser housing is provided with cross-shaped support rods. Additional turbulence of the hydraulic mixture flow is carried out by installing additional elements in the sectors of the confuser body between the cruciform support rods.

EFFECT: technical result is an increase in the technological and operational efficiency of the process of deep disintegration of the polymineral component of the hydraulic mixture.

1 cl, 2 dwg

Description

The invention relates to the mining industry and can be used in the development of natural and man-made high-clay alluvial mineral deposits with a high content of fine and fine gold.

There is a known method of gas-jet disintegration of a material and a device for its implementation based on the principle of jet-acoustic impact on the material [1].

The disadvantage of this method is the use of energy-consuming systems for supplying a gas jet and adjusting the movement of the jet-acoustic generator.

Methods and devices have also been established that generate acoustic vibrations in the ultrasonic range in fluid media by excitation of rods, plates, membranes by a liquid flow or as a result of modulation of a liquid jet [2-4].

The main disadvantages of these devices are limitations in technological indicators, maximum developed power and system performance.

Various rotor-type systems are known that use the principle of jet generation of acoustic flows [5, 6] and various systems of cavitation-jet dispersion [7].

The use of these devices is limited by the throughput of the treated medium (productivity by mass), the dispersion of the solid fraction and is not suitable for the disintegration of slurry containing clay inclusions.

A hydrodynamic generator of acoustic vibrations in the ultrasonic range and a method for creating acoustic vibrations in the ultrasonic range are known, including a housing in the form of a conical-cylindrical pipe with inlet and outlet openings and an obstacle to fluid flow placed inside it, which is a system consisting of a series-connected poorly streamlined body , rod and disk installed coaxially with the pipe [8].

This method is based on the creation of resonant acoustic phenomena in a hydraulic flow through a system of stationary cavitation elements, however, the design of the stationary emitters will not withstand the pressure of the flow of sand-clay hydraulic mixtures and will not ensure the disintegration of the mineral components in the pulp.

There are known methods of jet-acoustic disintegration of the mineral component of the slurry, including high-speed supply of a jet to a hydrodynamic generator, processing of the material under conditions of active hydrodynamic influences through the influence of stationary elements located inside the housing and sequentially installed stationary elements, ensuring deep disintegration of the mineral component of the slurry to the micro level through the conversion of kinetic energy fluid flow into the energy of acoustic vibrations in a hydrodynamic generator, at the input of which a high-speed jet is created [9-13].

These methods are based on the creation of resonant acoustic phenomena in a hydraulic flow through a system of cavitation elements and ensure wear resistance of elements under conditions of increased hydrodynamic loads, however, additional costs will be required to increase the required service life of generators.

The closest in technical essence is a method for activating the microdisintegration of the polymineral component of a hydraulic mixture, including high-speed supply of a jet to a hydrodynamic generator on a cone-shaped divider with blades, processing the hydraulic fluid flow under conditions of active hydrodynamic influences through influences located inside the housing and sequentially installed on different sides along the flow direction hydraulic mixture of inclined surfaces with cavitation thresholds, ensuring deep disintegration of the polymineral component of the hydraulic mixture to the micro level by converting the kinetic energy of the liquid flow into the energy of acoustic vibrations in a hydrodynamic generator. A high-speed jet from the diffuser is sequentially fed to cone-shaped dividers with blades installed stepwise in the center of the hydrodynamic generator, mounted on an axis with a reverse taper along the flow of the hydraulic mixture, to stratify the flow and enhance oscillation, while strengthening the fields of the primary hydrodynamic and creating secondary acoustic cavitation along Along the perimeter of the hydrodynamic generator housing, a cascade flow of hydraulic mixture occurs, interacting with inclined surfaces of the helical type, made with a displacement along the direction of the fluid flow and equipped with cavitation thresholds made along the inclined surfaces of the helical type, and also equipped with support rods to increase the rigidity of the structure, while the gap between the cone-shaped dividers along the axis is set depending on the ratio of solid to liquid in the hydraulic mixture to obtain a given average value of the volumetric density of hydrodynamic disturbance to ensure a pressure gradient exceeding the tensile strength of microparticles [14].

This method does not ensure long-term operational efficiency of the process of deep disintegration of the polymineral component of the slurry based on the use of design features of the system, including ensuring rigidity and wear resistance.

The technical result of the proposed method is to increase the technological and operational efficiency of the process of deep disintegration of the polymineral component of the slurry based on the use of design features of the system, including ensuring rigidity and wear resistance during the formation of hydrodynamic effects.

The technical result is achieved due to the fact that in the method of cavitation-hydrodynamic microdisintegration of the polymineral component of the slurry, which includes high-speed supply of a jet by a pump to the flat surface of the divider into a hydrodynamic generator made with a diffuser and a confuser body, the processing of the slurry flow under conditions of active hydrodynamic influences through the influence of sequentially disintegrators installed in the center of the confuser body to ensure deep disintegration of the polymineral component of the hydraulic mixture to the micro level by converting the kinetic energy of the fluid flow in a hydrodynamic generator, form zones that contribute to the enhancement of hydrodynamic oscillations due to the implementation of the dividers in the form of a monolithic system of interconnected hydrodynamic single-sheet hyperboloids, and To give the hydrodynamic generator additional structural rigidity, the confuser body is equipped with cross-shaped support rods, while additional turbulization of the hydraulic mixture flow is carried out by installing additional elements in the sectors of the confuser body between the cross-shaped support rods.

The ability to form the required sequence of actions performed using the proposed means allows us to solve the problem, determines novelty, industrial applicability and the inventive level of development.

In fig. 1 - general view of the hydrodynamic generator; in fig. 2 - section A-A in Fig. 1 shows a top view of the confuser body with dividers, additional hyperboloid-like elements and cross-shaped support rods.

The method is performed using a hydrodynamic generator 1, to which a pump 2 is connected. The nozzle 3 is mated with the diffuser 4 of the hydrodynamic generator 1. The diffuser 4 is connected to the confuser body 5. In the center 6 of the confuser body 5 and the diffuser 4 of the hydrodynamic generator 1, dividers 7 are installed, 8, 9,10. By making the dividers 7, 8, 9, 10 in the form of a monolithic system, zones 11 are formed from interconnected hydrodynamic single-sheet hyperboloids, which contribute to the intensification of hydrodynamic oscillations. To give the hydrodynamic generator 1 additional structural rigidity, the confuser body 5 is equipped with cross-shaped support rods 12, 13, 14, 15. For additional turbulization of the fluid flow, additional elements 16, 17, 18 are installed in sectors 19 of the confuser body 5 between the cross-shaped support rods 12, 13, 14, 15. The divider 7 is equipped with a flat surface 20.

The method of cavitation-hydrodynamic microdisintegration of the polymineral component of the hydraulic mixture is carried out as follows.

The initial stage of microdisintegration of the polymineral component of the hydraulic mixture includes high-speed supply of a jet by pump 2 from the nozzle 3 of the diffuser 4 onto the flat surface 20 of the divider 7 of the hydrodynamic generator 1, made with a diffuser 4 and a confuser body 5. The hydraulic mixture flow is processed under conditions of active hydrodynamic influences through the influence of sequentially installed in the center 6 of the diffuser 4 and the confuser body 5 of the dividers 7, 8, 9, 10, ensuring deep disintegration of the polymineral component of the hydraulic mixture to the micro level by converting the kinetic energy of the liquid flow. Zones 11 are formed that enhance hydrodynamic oscillations by making dividers 7, 8, 9, 10 in the form of a monolithic system of interconnected hydrodynamic single-sheet hyperboloids. Additional turbulization of the hydraulic mixture flow is carried out by installing additional elements 16, 17, 18 in sectors 19 of the confuser body 5 between the cross-shaped support rods 12, 13, 14, 15, installed to give the confuser body 5 of the hydrodynamic generator 1 additional structural rigidity.

The proposed method of disintegration of the mineral component of the hydraulic mixture using active hydrodynamic influences will increase the technological level of mineral extraction, reduce energy costs, improve operational performance of the complex, increase production profitability and environmental safety by reducing or completely eliminating the use of reagents for the destruction of clays and polyelectrolytes from the technological cycle complexes for leaching valuable components.

Information sources

1. Patent No. 2425719 RU, IPC V03V 5/02. Method of gas-jet disintegration of material and device for its implementation. - publ. 08/10/2011. Bull. No. 22.

2. Agranat B.A. Fundamentals of physics and ultrasound technology / B.A. Agranat, M.N. Dubrovin, N.N. Khavsky, G.I. Eskin. - M.: Higher. school, 1987. - 352 p.

3. Patent No. 2015749 RU, IPC B06B 1/20, F15B 21/12. Hydrodynamic vibration generator. - publ. 07/15/1994.

4. Patent No. 2229947 RU, IPC V06V 1/20. A method for deep processing of liquid and gaseous media and a generator of resonant oscillations for its implementation. - publ. 06/10/2004.

5. Promtov M.A. Rotary-type pulsation devices: theory and practice: Monograph. M.: Mechanical Engineering - 1, 2001. - 260 p. ISBN 5-99275-006-8.

6. Balabyshko A.M., Yudaev V.F. Rotary devices with flow modulation and their application in industry. - M.: Nedra, 1992. - p.: 176 ill. ISBN 5-247-02380-3.

7. Fedotkin I.M., Nemchin A.F. The use of cavitation in technological processes. - Kyiv: Vishcha school. Publishing house Kyiv. Univ., 1984, - 68 p. p.52, fig. 22

8. Patent No. 2325959 RU, IPC V06V 1/18. Hydrodynamic generator of acoustic vibrations in the ultrasonic range and a method for creating acoustic vibrations in the ultrasonic range. - publ. 06/10/2008. Bull. No. 16.

9. Khrunina N.P. Patent No. 2506127 RU, IPC V03V 5/00. Method of jet-acoustic disintegration of the mineral component of the slurry and hydrodynamic generator of acoustic vibrations. - Publ. 02/10/2014. Bull. No. 4.

Yu. Khrunina N.P. Patent No. 2506128 RU, IPC V03V 5/00. A method for disintegrating the mineral component of a hydraulic mixture under conditions of resonant acoustic phenomena in a hydraulic flow and a geotechnological complex for its implementation. - Publ. 02/10/2014. Bull. No. 4.

11. Khrunina N.P. Patent No. 2652517 RU, IPC V03V 5/00, V02S 19/18. A method for activating cavitation-hydrodynamic microdisintegration of the mineral component of a slurry. - Publ. 04/26/2018. Bull. No. 12.

12. Khrunina N.P. Patent No. 2687680 RU, IPC V03V 5/02. A method for activating cavitation-hydrodynamic microdisintegration of the mineral component of a slurry. - Publ. 05/15/2019. Bull. No. 14.

13. Khrunina N.P. Patent No. 2634148 RU, IPC V03V 5/00. Method of cavitation-hydrodynamic disintegration of the mineral component of the slurry. - Publ. 10/24/2017. Bull. No. 30.

14. Khrunina N.P. Patent No. 2744059 RU, IPC V03V 5/00. A method for activating microdisintegration of the polymineral component of a slurry. - Publ. 03/02/2021, Bulletin. No. 7.

Claims (1)

A method of cavitation-hydrodynamic microdisintegration of the polymineral component of a slurry, including high-speed supply of a jet by a pump onto the flat surface of a divider into a hydrodynamic generator made with a diffuser and a confuser body, processing the flow of a slurry under conditions of active hydrodynamic influences through the influence of dividers sequentially installed in the center of the confuser body with the provision deep disintegration of the polymineral component of the slurry to the micro level by converting the kinetic energy of the fluid flow in a hydrodynamic generator, characterized in that they form zones that contribute to the intensification of hydrodynamic oscillations by making the dividers in the form of a monolithic system of interconnected hydrodynamic single-cavity hyperboloids, and to give the hydrodynamic generator additional to ensure structural rigidity, the confuser body is equipped with cross-shaped support rods, while additional turbulization of the hydraulic mixture flow is carried out by installing additional elements in the sectors of the confuser body between the cross-shaped support rods.