RU2634153C1 - Method of cavitation-hydrodynamic microdisintegration of hydraulic mixture mineral component - Google Patents

Abstract

FIELD: mining engineering.

SUBSTANCE: method includes velocity delivery of a jet to a hydrodynamic generator, treatment of the hydraulic mixture under the conditions of active hydrodynamic effects by means of the influence of a body placed therein and successively installed stationary elements, including plate cavitation elements, with provision of deep disintegration of the mineral component of the hydraulic mixture to micro-level by converting the kinetic energy of liquid flow into the energy of acoustic vibrations in the hydrodynamic generator. In order to create stability conditions of the system, taking into account electrostatic interaction of the diffusion layers of ions of mineral component particles of the hydraulic mixture, the velocity jet is fed to a spider with cassettes rigidly fixed along the axis of the hydrodynamic generator, through flow stabiliser with splitters for subsequent distribution of flow in gaps along flat surfaces of cassettes installed on two sides of the spider guides with gaps in parallel relative to each other, with a shift in vertical direction due to reduction of flat surfaces area of mineral component, and a shift in horizontal direction-from the spider connection center to the body walls and fixed in the grooves of angular and radius inserts. The additional jet separation with the intensification of the cavitation-acoustic effect on the hydraulic mixture mineral component to obtain given average value of the volumetric density of the hydrodynamic effect on the microparticles is carried out at the outlet by means of accumulation of the flow in confuser zone with stationary cavitators longitudinally installed along the flow direction.

EFFECT: increased efficiency of microdisintegration process.

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Description

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

A known method of gas-jet disintegration of a material and a device for its implementation on the basis of 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 ultrasonic vibrations of the ultrasonic range in a fluid medium by means of excitation of rods, plates, membranes by a fluid stream or as a result of modulation of a liquid jet [2-4].

The main disadvantage of these devices is that the relationship between the geometric dimensions of the elements of the hydrodynamic oscillation generators and the hydrodynamic parameters of the pumped dispersion medium narrows the density range of the pumped slurry. This will not allow to efficiently process the mineral component of hydraulic mixtures of clay sands of placers with inclusions of solid particles with a size of 10 mm or more. This circumstance determines the limitation on technological indicators, maximum developed power and system performance.

There are various systems of rotor type using 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 capacity of the medium being processed, the dispersion of the solid fraction, and is not suitable for the disintegration of hydraulic mixtures with a high clay content.

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

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

The closest in technical essence is the method of jet-acoustic disintegration of the mineral component of the hydraulic mixture, including high-speed feed of the jet into the hydrodynamic generator, processing of the material under conditions of active hydrodynamic effects through the influence of stationary elements located inside the housing and sequentially installed, including plate cavitation elements, with deep disintegration of the mineral component of the slurry to the micro level through the conversion anija fluid flow kinetic energy into acoustic oscillations in the hydrodynamic generator to create a high-speed input of which a stream [9].

This method is based on the creation of resonant acoustic phenomena in a hydroflow through a system of cavitation elements, however, the control of the process of directional changes in the properties of sandy clay rocks is based on the task of forming a more stable state of highly dispersed deterministic systems containing mineral particles, therefore, this factor is necessary to ensure stability during disintegration of the system to be improved.

The technical result of the proposed method is to increase the efficiency of the microdisintegration process by creating conditions for the stability of the system, taking into account the electrostatic interaction of the diffuse layers of ions of particles of the mineral component of the clay slurry slurry of the placer based on the separation of the slurry during its flow in the inter-surface space of stationary cavitation elements in the form of cartridges.

The technical result is achieved due to the fact that in the method of cavitation-hydrodynamic microdisintegration of the mineral component of the hydraulic mixture, including high-speed flow of the jet into the hydrodynamic generator, processing the hydraulic mixture under conditions of active hydrodynamic effects through the influence of stationary elements located inside the housing and sequentially installed, including plate cavitation elements , ensuring deep disintegration of the mineral component of the hydraulic mixture to the microlevel p by means of converting the kinetic energy of the fluid flow into the energy of acoustic vibrations in a hydrodynamic generator, to create conditions for the stability of the system, taking into account the electrostatic interaction of the diffuse layers of ions of particles of the mineral component of the hydraulic mixture, the high-speed jet is fed to the crosspiece with cartridges fixed rigidly along the axis of the hydrodynamic generator through a flow stabilizer with dividers for subsequent distribution of the flow in the gaps along the flat surfaces of the cassettes, installed x on both sides of the guide cross with gaps, parallel to each other, with a shift in the vertical direction, due to the reduction of the area of flat surfaces, and a shift in the horizontal direction - from the center of the junction to the walls of the body - and corner and radius inserts fixed in the grooves, wherein additional jet separation with increased cavitation-acoustic effects on the mineral component of the slurry to obtain a given average value of the bulk density of the hydrodynamic Impacts on microparticles are carried out at the outlet by flow accumulation in the confuser zone with stationary cavitators longitudinally installed along the flow direction.

The possibility of forming the required sequence of actions by the proposed means allows us to solve the problem, determines the novelty, industrial applicability and inventive step of development.

In FIG. 1 is a general view of a hydrodynamic generator; in FIG. 2 is a section AA in FIG. 1, flow stabilizer with dividers; in FIG. 3 is a section BB in FIG. 1, a crosspiece with cartridges; in FIG. 4 is a top view of the spider without cassettes.

The method is performed using a hydrodynamic generator 1, in the housing 2 of which stationary elements 3 are placed, including plate cavitation elements 4. Along the axis 5 of the housing 2 of the hydrodynamic generator 1, a crosspiece 6 with cassettes 7 is fixed rigidly. A stabilizer 8 is mounted above the crosspiece 6 with cassettes 7 flow with dividers 9 for subsequent distribution of the flow in the spaces 10 along 11 flat surfaces 12 of the cassettes 7 mounted on two sides 13, 14 of the guide 15 of the spider 6 with gaps 16, parallel to 17 relative to each other Ruga. The flat surfaces 12 of the cassettes 7 are installed with a shift of 18 in the vertical direction 19 by reducing the area 20 of the flat surfaces 12, as well as by a shift of 21 in the horizontal direction 22 from the center of the connection 23 of the spider 6 to the walls 24 of the housing 2. The flat surfaces 12 are fixed in the grooves 25 angular inserts 26 and radius inserts 27. At the exit 28 of the hydrodynamic generator 1 in the zone of the confuser 29 longitudinally 30 stationary cavitators 32 are installed along the direction of flow 31.

The method of cavitation-hydrodynamic microdisintegration of the mineral component of the hydraulic mixture is as follows.

Disintegration of high-clay sand of placers includes high-speed feed of the jet into the hydrodynamic generator 1 and subsequent processing of the hydraulic mixture under conditions of active hydrodynamic influences through the influence of stationary elements 3 installed inside the housing 2 and successively installed, including plate cavitation elements 4. A deep disintegration of the mineral component of the hydraulic mixture to the micro level is ensured. by converting the kinetic energy of a fluid stream into acoustic energy natural oscillations. To create conditions for the stability of the system, taking into account the electrostatic interaction of the diffuse layers of ions of particles of the mineral component of the hydraulic mixture, the high-speed jet is fed to the crosspiece 6 with cassettes 7, fixed rigidly along the axis 5 of the hydrodynamic generator 1, through the flow stabilizer 8 with dividers 9 for subsequent distribution of the flow in gaps 10 along 11 flat surfaces 12 of cassettes 7, mounted on two sides 13, 14 of the guides 15 of the cross 6 with gaps 16, parallel to 17 relative to each other and fixed in the groove 25 angular inserts 26 and radius inserts 27. A shift 18 in the vertical direction 19, due to a decrease in the area 20 of flat surfaces 12, and a shift 21 in the horizontal direction 22 - from the center of the connection 23 of the spider 6 to the walls 24 of the housing 2, - provides the necessary flow stability the slurry flow through the gaps of 16 flat surfaces 12 of the cassettes 7. Additional jet separation with increased cavitation-acoustic effects on the mineral component of the slurry to obtain a given average value of bulk density gy rodinamicheskogo impact on the microparticles is carried out at the outlet 28 via flow converger accumulation area 29 to 30 set longitudinally along the direction of flow 31 cavitators 32 stationary.

The proposed method for the disintegration of the mineral component of the hydraulic mixture using cavitation effects and a mechanism for regulating the structural and mechanical parameters of the processed sands will increase the technological level of mining, reduce energy consumption, improve operational performance for the maintenance of the complex, increase production profitability and environmental safety by eliminating the use of reagents from the technological cycle .

Information sources

1. Patent No. 2425719 RU, IPC V03V 5/02. The method of gas-jet disintegration of the material and a device for its implementation. - Publ. 08/10/2011. Bull. Number 22.

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

3. Patent No. 20155749 RU, IPC B06B 1/20, F15B 21/12. Hydrodynamic oscillator. - Publ. 07/15/1994.

4. Patent No. 2229947 RU, IPC В06В 1/20. The method of deep processing of liquid and gaseous media and a resonant oscillation generator for its implementation. - Publ. 06/10/2004.

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

6. Balabyshko A.M., Yudaev V.F. Flow modulating rotary apparatus 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. - Kiev: Vishcha school, Kiev publishing house. Univ., 1984, - 68 p., P. 52, fig. 22.

8. Patent No. 2225959 RU, IPC В06В 1/18. Hydrodynamic generator of acoustic vibrations of the ultrasonic range and a method for creating acoustic vibrations of the ultrasonic range. - Publ. 06/10/2008. Bull. No. 16.

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

Claims (1)

The method of cavitation-hydrodynamic microdisintegration of the mineral component of the hydraulic mixture, comprising the high-speed flow of the jet into the hydrodynamic generator, processing the hydraulic mixture under the conditions of active hydrodynamic effects by the influence of stationary and sequentially installed stationary elements, including plate cavitation elements, ensuring deep disintegration of the mineral component to the hydro microlevel by converting kinetic energy of the flow fluid into the energy of acoustic vibrations in a hydrodynamic generator, characterized in that to create the stability of the system, taking into account the electrostatic interaction of diffuse layers of ions of particles of the mineral component of the hydraulic mixture, the high-speed jet is fed to the crosspiece with cartridges fixed rigidly along the axis of the hydrodynamic generator through a flow stabilizer with dividers for subsequent distribution of the flow in the gaps along the flat surfaces of the cassettes mounted on both sides of the guide seats goods with gaps parallel to each other, with a shift in the vertical direction, due to a decrease in the area of flat surfaces, and a shift in the horizontal direction - from the center of the junction of the cross to the walls of the body - and angular and radius inserts fixed in the grooves, with additional jet separation with increasing cavitation-acoustic effects on the mineral component of the slurry to obtain a given average value of the bulk density of the hydrodynamic effects on the microparticles exit at the outlet by flow accumulation in the confuser zone with stationary cavitators longitudinally mounted along the direction of flow.

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