RU2296622C1 - Gold-bearing sands washing method with use of acoustic waves - Google Patents

Abstract

FIELD: physics, possibly production of minerals, extraction of minerals from old industrial wastes and so on, rational usage of nature, reagent-free cleaning of sewage water by removing suspended matter from them for providing good ecology, for preparing drinking water for population.

SUBSTANCE: method for washing out gold bearing sands with use of acoustic waves comprises steps of preparing primary and secondary pulps at processes of primary and secondary classification by sifting. Primary classification is realized after disintegration; secondary classification is realized after main sluice at outlet of which natural agitation of pulp is performed. In main sluice of washing out apparatus primary pulp is subjected to action of acoustic waves by means of acoustic irradiators of sound and ultrasound frequency range. Said acoustic irradiators are arranged along length of main sluice and oriented from upwards to downwards opposite to flow of primary pulp. In addition beds of main and additional sluices are subjected to cyclic impulse loosening by acoustic waves of sound and ultrasound ranges. Acoustic irradiators are arranged in air medium with possibility of penetration of acoustic waves to aqueous medium along the whole surface area of main and additional sluices of washing out apparatus.

EFFECT: improved efficiency of extraction of minerals, including extraction of fine particles being main technological losses when clayey and frozen fractions are present in rock.

7 dwg, 1 ex

Description

The invention relates to the field of physics and can be used in the extraction of minerals (PI): gold, etc. to reduce technological losses during the beneficiation of PI on sluice washing devices (PP), especially when washing clay and frozen gold-containing sands, if present in gold-containing sands plate metal, for extracting PI from industrial dumps of past years, etc. in the interests of rational nature management, for the purification of recycled and wastewater from suspended solids in the interests of ecologists, as well as for the preliminary water treatment of drinking water in the interests of public health.

There is a method of washing gold sands using a screen with a dynamic connection of the screening surface and electromagnetic type exciter, consisting in mechanical mixing of the rock during continuous irrigation with water, formation of pulp, the direction of the pulp on a sieve oscillating in a direction perpendicular to its plane. / Acoustic technology in mineral processing // Edited by B.C. Yamschikov. - M .: Subsoil. 1987, p. 109 /.

The disadvantages of this method include:

1. Small volume of processed breed.

2. Low efficiency of the method due to the low speed of the sifting of particles.

3. Inadequate capture efficiency of fine particles (MDF) PI.

4. Low efficiency of disintegration, especially when washing clay and frozen rocks, etc.

A known method of washing gold sands, based on the principle of "reverse screening", which consists in mechanical mixing of the rock with continuous irrigation with water, the formation of pulp, the direction of the pulp in a special apparatus under the surface of the sieve. In this case, a thin fraction is carried out through a sieve by an ascending flow of the medium. / Acoustic technology in mineral processing // Edited by B.C. Yamschikov. - M .: Subsoil. 1987, p. 109, 110 /.

The disadvantages of this method include:

1. Small volume of processed breed.

2. Low efficiency of the method due to the low speed of the sifting of particles.

3. Inadequate capture efficiency MDC PI.

4. Inadequate capture efficiency of low-rolled metal, i.e. having a lamellar or scaly form.

5. Low efficiency of disintegration, especially when washing clay and frozen rocks, etc.

A known method of washing gold sands using waves of various physical nature, which consists in mechanically mixing the rock in the drum during continuous irrigation with water, the formation of primary pulp, disintegration of the primary pulp in a given class using a sieve installed inside the drum, the direction of the pulp in the gateway PP containing stencil with constant parameters, deposition by hydrodynamic and gravitational waves of large and medium gold on a stencil / Acoustic technology in the enrichment of eznyh minerals // Edited B.C.Yamschikova. - A .: Subsoil. 1987, p. 111-115 /.

The main disadvantages of the method are:

1. Inadequate capture efficiency MDC PI.

2. The lack of efficiency of the extraction of lamellar coarse particles (CDF) and medium dispersed (CFC) particles.

3. The lack of efficiency of trapping weakly rounded metal, ie having a lamellar or scaly form.

4. Low efficiency of extraction of MDC, SDC, and even CDC in the presence of clay and frozen fractions in the rock, etc.

Closest to the technical nature of the claimed method includes a method selected as a prototype method, washing gold sands using acoustic waves, including primary disintegration with artificial mixing of the rock and irrigation with water, the formation of primary pulp and its direction to the entrance of the main gateway, which has a constant angle of inclination θ ₁ , extraction of CDF, MFD and MDF PI from the rock at the main gateway of the flushing device (PP) in the flow of the primary pulp having a flow rate of V ₁ and a flow height H ₁ , the natural mixing of the primary pulp, the formation of the secondary pulp and its direction to the input of the additional gateway having an angle of inclination θ ₂ <θ ₁ , removing the MPS and MDC PI on the additional gateway in the secondary pulp stream having a flow rate of V ₂ <V ₁ and the height of the stream H ₂ <H ₁ , the impact on the secondary pulp with acoustic waves of the sound (ZD) and ultrasonic (SPL) frequency ranges using the frequency ranges placed along the length of the additional gateway of the radiators ZD and SPL / Bakharev S.A. - RF patent No. 2214866 by application No. 2002105319, 02.26.02, /.

The main disadvantages of the prototype method are:

1. The lack of efficiency of extraction of MFD PI.

2. Low extraction efficiency MDC PI.

3. Incomplete extraction of KDCH, MF and MFD PI, which are technological losses of the main gateway PP, because from its output to an additional gateway, only part of the primary pulp is directed.

4. The low reliability of the method due to the failure of the emitters located at the bottom of the additional gateway PP in the flow of the moving pulp.

5. The lack of efficiency in the extraction of CDF, SDC and MDC PI during washing of rocks containing clay and frozen fractions.

The problem that is solved by the invention is to develop a method free from the above disadvantage.

The technical result of the proposed method is the effective extraction of PI, including MDC, which are the main technological losses, including the presence of clay and frozen fractions in the rock.

This goal is achieved by the fact that in the known method of washing gold sands using acoustic waves, including primary disintegration with artificial mixing of the rock and irrigating it with water, forming a primary pulp and directing it to the entrance of the main gateway with a constant angle of inclination θ ₁ , extracting the CDF , SDCH and MDCH PI from the formation on the primary gateway PP in the stream of primary pulp having a flow velocity V ₁ and a height H ₁ stream, the primary mixing natural pulp, forming secondary bullets s and forwarding it to the input of the additional gateway having the angle of its inclination θ ₂ <θ _1, extracting SDCH and MDCH PI on the additional gateway in a stream of secondary sludge having a flow velocity V ₂ <V ₁ and the height of stream H ₂ <H _1, the impact to the secondary pulp by the acoustic waves of the ZD and UZD frequency ranges using the frequency ranges located along the length of the additional gateway of the radiators of the ZD and UZD frequency ranges, the formation of the primary and secondary pulp is carried out in the process of primary and secondary classifications by sieving, and the primary classification They are carried out after disintegration, and the secondary after the main gateway, at the output of which the primary pulp is naturally mixed, while the main gateway of the PP performs acoustic waves on the primary pulp using acoustic waves placed along the length of the main gateway and oriented from top to down towards the moving flow of the primary pulp of acoustic emitters ZD and UZD frequency ranges, and additionally carry out periodic, pulsed acoustic loosening of the main and additional locks in the ZD and SPL waves of frequency ranges, and acoustic emitters are placed in the air with the possibility of penetration of acoustic waves into the water medium over the entire area of the main and additional locks of the washing device.

Figure 1 and figure 2 presents a structural diagram of a device that implements the developed method of washing gold sands using acoustic waves.

The device comprises a flushing device (1) with a receiving hopper (2), into which a rock (3) is supplied, containing KDCH (4) with a size of “+1.0” mm, an SDC (5) with a size of “-1.0 + 0.25 "Mm and MDC (6) mineral particles (gold, etc.) with a size of" -0.25 "mm, a sprinkler (7) through which water (8) is supplied to the receiving hopper (2) and primary disintegrator (9), connected in series with a primary disintegrator (9) and a primary classifier (10), a primary pulp (11) having a flow rate V ₁ and a flow height H ₁ , the main gateway (12) having a constant angle of inclination θ ₁ , as well as holding at the bottom higher stencils (13) and a higher bed (14).

In addition, the device contains a first multichannel (at least 4 channels) generator (15) _RF frequencies F _healthy1 , the first multichannel (at least 4 channels) power amplifier (16) RF frequencies connected by its first input to the first output of the generator (15), and the second input - to the second output of the generator (15), etc., the first (17) and second (18) acoustic radiators of ЗД frequencies connected to the corresponding outputs: the first emitter - to the first output, the second - second, etc. power amplifier (20) installed in a certain way on the main gateway (12) of the software (1); the second multichannel (at least 4 channels) generator (23) _RF frequencies F _healthy2 , the second multichannel (at least 4 channels) power amplifier (24) RF frequencies connected by its first input to the first output of the generator (23), and its second input - to the second output of the generator (23), etc., the first (25) and second (26) acoustic radiators of ЗД frequencies connected to the corresponding outputs: the first radiator to the first output, the second - to the second, etc. . multichannel power amplifier (24) and installed in a certain way on the main gateway (12) of the software (1); the second multichannel (at least 4 channels) generator (27) SPL F _uzd2 , the second multichannel (at least 4 channels) power amplifier (28) SPL frequencies connected by its first input to the first output of the generator (27), and its the second input - to the second output of the generator (27), etc., the first (29) and second (30) acoustic emitters of ultrasonic ultrasonic frequencies, connected to the corresponding outputs: the first emitter to the first output, the second to the second, etc. multichannel power amplifier (28) and installed in a certain way on the main gateway (12) of the software (1).

In addition, the device contains a secondary classifier (31), a secondary pulp (32) having a flow rate of V ₂ (V ₂ <V ₁ ) and a flow height of H ₂ (H ₂ <H ₁ ), an additional gateway (33) having a constant the angle of its inclination θ ₂ (θ ₂ <θ ₁ ), as well as containing at its bottom less deep stencils (34) and a less deep bed (35); the third (36) and fourth (37) acoustic emitters of ZD frequencies connected to the corresponding outputs: the third emitter to the third output, the fourth to the fourth, etc. power amplifier (16) and installed in a certain way on the additional gateway (33) of the software; the third (38) and fourth (39) ultrasonic ultrasonic emitters connected to the respective outputs: the third emitter to the third output, the fourth to the fourth, etc. power amplifier (20) and installed in a certain way on the additional gateway (33) of the software (1); the third (40) and fourth (41) acoustic emitters of ZD frequencies connected to the corresponding outputs: the third emitter to the third output, the fourth to the fourth, etc. power amplifier (24) and installed in a certain way on the additional gateway (33) of the software (1); third (42) and fourth (43) acoustic ultrasonic radiators of frequencies connected to the respective outputs: the third emitter to the third output, the fourth to the fourth, etc. power amplifier (28) and installed in a certain way on the additional gateway (33) of the software (1).

The method is implemented as follows (figure 1, figure 2, 3).

In the receiving hopper (2) of the PP (1), a rock (3) is supplied containing KDCH (4), SDK (5) and MDC (6) PI, and water (8) from the sprinkler (7). In the primary disintegrator (9), primary separation of the CDC, MFD, and MDC PI from the rock is carried out by artificially mixing and irrigation with water (8), and in the primary classifier (10) primary rock classification is performed (for example, according to the “-40” mm class) by sifting it. In this case, a primary pulp (11) is formed, having a flow rate V ₁ and a flow height H ₁ , which is directed to the input of the main gateway (12), which has a constant angle of inclination θ ₁ and also contains higher stencils (13) and a higher bed (14) - settled fine fractions of the rock located between the stencils (13).

Using the first multichannel (at least 4 channels) generator (15) ZD frequencies, a signal is generated at a frequency F _Zd1 . In the first multi-channel (at least 4 channels) power amplifier (16) of the RF frequency, connected by its first input to the first output of the generator (15), and by its second input to the second output of the generator (15), etc., amplification this signal to the desired level. With the help of the first (17) and second (18) acoustic radiators of ЗД frequencies connected to the corresponding outputs: the first radiator to the first output, the second to the second, etc. of a multi-channel power amplifier (16) of the RF frequencies and installed in a certain way on the main gateway (12) of the PP (1), a continuous emission of acoustic waves is directed towards the moving primary pulp (11) at a frequency of _Fx1 .

At the same time, with the help of the first multichannel (at least 4 channels) generator (19) of the ultrasonic ultrasound frequency, a signal is generated at a frequency F _brid1 . In the first multichannel (at least 4 channels) power amplifier (20), the ultrasonic frequency amplifier, connected by its first input to the first output of the generator (19), and the second input to the second output of the generator (19), etc., is amplified this signal to the desired level. By means of the first (21) and second (22) acoustic emitters of the ultrasonic ultrasonic frequency, connected to the corresponding outputs: the first emitter to the first output, the second to the second, etc., a multi-channel power amplifier (20) ultrasonic frequency and installed in a certain way on the main gateway (12) of the PP (1), the radiation is continuous and directed, as well as towards and from top to down the moving pulp (11), the emission of acoustic waves at a frequency F _brid1 .

At the same time, with the help of a second multichannel (at least 4 channels) generator (23) ZD frequencies, a pulse signal is generated at a frequency F _zd2 . In the second multi-channel (at least 4 channels) power amplifier (24) of the RF frequency, connected with its first input to the first output of the generator (23), and with its second input to the second output of the generator (23), etc., amplification this signal to the desired level. With the help of the first (25) and second (26) acoustic radiators of ЗД frequencies connected to the corresponding outputs: the first radiator to the first output, the second to the second, etc. multichannel power amplifier (24) and installed in a certain way on the main gateway (12) of the PP (1), pulsed radiation from the air into the aquatic environment is carried out over the entire area of the main gateway (12) of acoustic waves at a frequency of _F2 .

At the same time, using the second multichannel (at least 4 channels) generator (27) of the ultrasonic ultrasound frequency, a pulse signal is generated at a frequency F _brid2 . In the second multichannel (at least 4 channels) power amplifier (28), the ultrasonic frequency coupler is connected with its first input to the first output of the generator (27), and with its second input to the second output of the generator (27), etc., amplification this signal to the desired level. By means of the first (29) and second (30) acoustic emitters of the ultrasonic ultrasonic frequency, connected to the corresponding outputs: the first emitter to the first output, the second to the second, etc. multichannel power amplifier (28) and installed in a certain way on the main gateway (12) of the PP (1), pulsed radiation from the air into the aquatic environment is carried out over the entire area of the main gateway (12) of acoustic waves at a frequency F _brid2 .

In a moving pulp (11) having a flow velocity V ₁ and a flow height H ₁ , under the influence of the hydrodynamic force U and gravity G ₁ for KDP, SDK and MHD (G _kdch , G _sdch , and G _mdch ), as well as acoustic waves During the continuous and pulsed regimes of their radiation, ZD and SPL accumulate settled fine fractions of the rock (3) in the recesses of the stencils (13) of the main gateway (12) and find them under the influence of turbulent flows, as well as acoustic waves of ZD and SPL frequencies with their pulsed radiation in a state of loosening. Thus, the bed (14) of the main gateway (12) of the PP (1) is formed and maintained in optimal condition.

In this case, accumulation of heavy minerals (concentrates) in the recesses of the stencils (13) is not allowed, increasing the effective density of the bed (14) and preventing the penetration of MDC (6), MFD (5) and KDF (4) PI, and seal is also eliminated bed (14) in case of temporary stops of the enrichment process;

- a decrease in the speed of movement of the CDF (4), MFD (5) and MDC (6) in the pulp stream (11), as well as their pressing against the loosened bed (14) of the main gateway (12) of the PP (1) under the influence of acoustic waves of ZD and SPL of frequencies during their continuous emission from top to bottom and towards the moving pulp stream (11). In this case, even thin (lamellar) PI particles effectively penetrate the bed (14) and are not carried out of it by ascending flows.

Thus, at the main gateway (12) of the BCP (1), full - 100% recovery of the CDF (4) is carried out, almost complete - more than 95% recovery of the MFC (5) and a significant 25 - 50% recovery of the MDC (6), including in the presence of clay and frozen rock fractions (3).

At the output of the main gateway (12), the primary pulp (11) mixes naturally (by reducing the flow width and increasing flow height, elevation difference between the gateways, etc.) and enters the secondary classifier (31), in which the secondary classification rocks (for example, in the "-10" mm class) by sieving it. In this case, a secondary pulp (32) is formed, having a flow rate of V ₂ (V ₂ <V ₁ ) and a flow height of H ₂ (H ₂ <H ₁ ), which is directed to the input of the additional gateway (33), which has a constant angle of inclination θ ₂ (θ ₂ <θ ₁ ), as well as those containing on its bottom less deep stencils (34) and a less deep bed (35) - settled fine fractions of the rock (3) located between the stencils (13).

With the help of the third (36) and fourth (37) acoustic radiators of ЗД frequencies connected to the corresponding outputs: the third radiator to the third output, the fourth to the fourth, etc. of a multichannel power amplifier of the RF frequencies (16) and installed in a certain way on the additional gateway (33) of the PP (1), the acoustic waves are continuously and directed from top to bottom and towards the moving secondary pulp (32) at a frequency F _zd1 .

At the same time, with the help of the third (38) and fourth (39) acoustic emitters of ultrasonic ultrasound frequencies connected to the corresponding outputs: the third emitter to the third output, the fourth to the fourth, etc. of a multi-channel power amplifier of ultrasonic ultrasonic frequency (20) and installed in a certain way on the additional (33) PP (1), the acoustic waves are continuously and directed from top to bottom and towards the moving secondary pulp (32) at a frequency F _brid1 .

At the same time, with the help of the third (40) and fourth (41) acoustic radiators of ЗД frequencies connected to the corresponding outputs: the third radiator to the third output, the fourth to the fourth, etc. multichannel power amplifier (24) and installed in a certain way on the additional gateway (33) of the instrument panel (1), pulsed radiation is carried out from the air into the aquatic environment over the entire area of the additional gateway (33) of acoustic waves at a frequency F _health2 .

At the same time, with the help of the third (42) and fourth (43) acoustic emitters of ultrasonic ultrasonic frequencies, connected to the corresponding outputs: the third emitter to the third output, the fourth to the fourth, etc. multichannel power amplifier (28) and installed in a certain way on the additional gateway (33) of the PP (1), pulsed radiation from the air medium into the aquatic environment is carried out over the entire area of the additional gateway (33) of acoustic waves at a frequency F _brid2 .

In a moving secondary pulp (32) having a flow rate of V ₂ (V ₂ <V ₁ ) and a flow height of H ₂ (H ₂ <H ₁ ), under the influence of hydrodynamic - a secondary classification of the pulp is carried out;

- periodic acoustic loosening of the beds of the main and additional gateways of the PP is carried out.

2. Improving the efficiency of the extraction of MDC is achieved due to the fact that:

- the entire primary pulp enters the additional gateway;

- secondary pulp classification is carried out;

- acoustic waves of airborne and ultrasonic frequencies are used, which penetrate from the air into the aquatic environment over the entire area of the main and additional PP gateways, inhibit and press the MDC PI gateways to the beds;

- periodic acoustic loosening of the beds of the main and additional gateways of the PP is carried out.

3. The full extraction of KDCH, MF and MFD PI, which are technological losses of the main gateway PP, is achieved due to the fact that:

- more efficiently retrieving KDCH, NDF and MHD already at the main gateway;

- the entire primary pulp enters the additional gateway;

- secondary pulp classification is carried out;

- acoustic waves of airborne and ultrasonic frequencies are used, which penetrate from the air into the aquatic environment over the entire area of the main and additional gateways of the software, slow down and press to the beds of the gateways of the KDCH, SDCh and MDCh PI;

- periodic acoustic loosening of the beds of the main and additional gateways of the PP is carried out.

4. Improving the reliability of the method is achieved due to the fact that acoustic emitters ZD and UZD frequencies are used, located in the air layer, and not at the bottom of the additional gateway PP in the flow of the moving pulp.

5. Improving the efficiency of extracting CDF, MFD, and MDF PI during washing of rocks containing clay and frozen fractions is achieved due to the fact that: U forces and gravity G ₁ for MFD and VDF (G _MFR and G _MFD ), as well as acoustic waves ZD and SPL with continuous and pulsed modes of their radiation, occurs:

- the accumulation of settled fine fractions of the rock in the recesses of the smaller stencils (34) of the additional lock (33) and their presence under the influence of turbulent flows, as well as acoustic waves of the ZD and SPL frequencies when they are pulsed radiation in the state of loosening. Thus, the bed (35) of the additional gateway (33) of the PP (1) is formed and maintained in optimal condition. In this case, accumulation of heavy minerals (concentrates) in the recesses of the stencils (34) is not allowed, increasing the effective density of the bed (35) and not allowing the MDC and MFR to penetrate into it, and bed compaction is also excluded (35) in case of temporary stops of the enrichment process;

- a decrease in the speed of movement of the MFD and MFD in the secondary pulp stream (32), as well as their pressing against the loosened bed (35) of the additional gateway (33) of the PP (1) under the influence of acoustic waves of the ZD and SPL frequencies when they are continuously emitted from the top down and towards a moving stream of secondary pulp (32). In this case, even thin (scaly, lamellar) UHF and MDF PI effectively penetrate through the primary concentration layer into the bed (35) and are not carried out by upward flows.

Thus, at the additional gateway (33) of the PP (1), the full MFD is extracted (6) and the almost complete MHD is extracted (6), including in the presence of clay and frozen rock fractions (3).

1. The increase in the efficiency of extracting the VAS is achieved due to the fact that:

- the entire primary pulp enters the additional gateway;

- acoustic waves of airborne and ultrasonic frequencies are used, which penetrate from the air into the aquatic environment over the entire area of the main and additional gateways of the software, slow down and press it to the beds of the locks of the airborne radiation protection systems;

- acoustic waves of airborne and ultrasonic frequencies are used, which penetrate from the air into the aquatic environment over the entire area of the main and additional gateways of the detector, disintegrate the detectors from the rock, inhibit and press to the beds of the gateway KDCH, SDCH and MDCH PI;

- secondary pulp classification is carried out;

- periodic acoustic loosening of the beds of the main and additional gateways of the PP is carried out.

Distinctive features of the proposed method

1. As the waves are used acoustic waves ZD and SPL frequencies. In this case, acoustic waves penetrate from the air into the aquatic environment over the entire area of the main and additional gateways of the PP, inhibit and press KDCH, SDCh and MDCh PI to the gateway beds.

2. Instead of the almost complete extraction of CDF, insufficiently complete extraction of MFD and insignificant extraction of MCD at the main gateway of the PP, the full extraction of MFB, almost complete extraction of MFB, and significant extraction of MFD are carried out.

3. Instead of the almost complete extraction of the MFD and the significant extraction of the MFC at the additional gateway of the PP, the full extraction of the MFD and the almost complete extraction of the MFD are carried out.

4. Additionally, a periodic, determined by the period of the pulses, acoustic loosening of the beds of the main and additional gateways PP.

The presence of distinctive features from the prototype features allows us to conclude that the proposed method meets the criterion of "novelty."

An analysis of the known technical solutions in order to detect the indicated distinctive features in them showed the following.

Signs 1 and 2 are new and their use for the effective extraction of PI (including MDC), which are the main technological losses of PP, including in the presence of clay and frozen rock fractions, is unknown.

Signs 3 and 4 are known, but their use for the effective extraction of PIs, which are the main technological losses of PPs, including in the presence of clay and frozen rock fractions, is unknown.

Thus, the presence of new significant features, together with the known ones, ensures that the proposed solution has a new property that does not coincide with the properties of the known technical solutions — effectively extract PIs, including MDCs, which are the main technological losses of PPs, including in the presence of clay ones and frozen rock fractions.

In this case, we have a new set of features and their new relationship, moreover, it’s not a simple combination of new features and already known ones, but the execution of operations in the proposed sequence leads to a qualitatively new effect.

This circumstance allows us to conclude that the developed method meets the criterion of "significant differences".

An example implementation of the method.

Industrial tests of the developed method were carried out in 2004, 2004. at one of the sites of Koryakgeoldobycha CJSC (Kamchatka Peninsula) during the extraction of alluvial platinum, including from man-made dumps of past years. As the basic model, “PBSh-40” type of software with a 2-section gateway and a primary classifier of “-40” mm was used, as well as a specially made gateway prefix based on a 3-section PCBSh-100 type gateway with a secondary classifier of “-10 "Mm. Parameters of the main gateway PP: width 1.4 m, height 0.6 m, length 9 m. Parameters of the additional gateway: length 6 m, width 2.1 m, height 0.4 m.

Figure 4 illustrates the physical processes occurring in the main gateway (12) of the PP (1) only under the influence of gravitational and hydrodynamic forces (prototype method). Figure 5 illustrates the physical processes occurring in the main gateway of the PP under the influence of gravitational and hydrodynamic forces, as well as under the influence of acoustic waves ZD and SPL of frequencies F _Z1 and F _brid1 (the developed method).

As can be seen from figure 4, the hydrodynamic force U and gravity G ₁ for KDH, MFD and MFD (G _cdh , G _sdh and G _mdch ) is not enough for the above PI particles to effectively penetrate the bed (14) of the main gateway ( 12) PP (1) and part of PI, including even KDCH (4) in the form of technological losses is carried to the dump.

While the implementation of the developed method (Fig. 5) under the influence of acoustic waves of HF and SPL frequencies of KDCH, MFD and MDC PI are inhibited in the moving pulp stream (11), they are pressed to the bed (14) of the main gateway (12) of the PP (1 ) and are held in it. Thus, the share of PI particles removed from the main gateway to the dump of PI particles is significantly reduced.

Figure 6 presents the average results of industrial tests of the developed method (histograms with a black top) and the prototype method (histograms with a white top) for daily extracts of CDF (a series of histograms with index "a"), SDM (a series of histograms with index "b" ) and MDC (a series of histograms with an index “c”) of PI from medium-washed sand (the absence of clay and frozen lumps of the rock in them).

As can be seen from Fig.6, when implementing the developed method, the average daily gain in extracting PI was 790 g, or 43.4% of the total mass of extracted PI. At the same time, the main contribution to the above gain was made by the MPS (410 g) and MDC (320 g) PI. The proportion of additionally recovered CDF was small: 60 g (7.6%), which is in good agreement with theory and does not contradict the practice of gold mining.

Figure 7 presents the averaged data on the technological losses of the CDF, MFD, and MDF PI of the developed method (black top histogram) and prototype method (white top histogram) when washing rocks containing clay and frozen fractions (a series of histograms with index a ”), Clay fractions (a series of histograms with an index“ c ”) and not containing clay and frozen fractions (a series of histograms with an index“ c ”).

As can be seen from Fig.7, when implementing the developed method, the level of losses is reduced in comparison with the prototype method by ~ 3 times (from 52% to 17%) when washing rocks containing clay and frozen fractions by ~ 2 times (from 25% up to 12%) when washing a rock containing clay fractions and ~ 2 times (from 7% to 3%) when washing a rock that does not contain clay and frozen fractions.

1. The increase in the efficiency of extracting the VAS is achieved due to the fact that:

- the entire primary pulp was supplied to the additional gateway, and not only its lower part, as in the prototype method;

- acoustic waves of airborne and ultrasonic frequencies were used, which penetrated from the air into the aquatic environment over the entire area of the main and additional gateways of the FS, braked and pressed to the beds of the gateways of the SDH PI;

- carried out secondary classification of pulp;

- carried out periodic acoustic loosening of the beds of the main and additional gateways PP.

2. Improving the efficiency of the extraction of MDC achieved due to the fact that:

- the entire primary pulp entered the additional gateway;

- carried out secondary classification of pulp;

- acoustic waves of the airborne and ultrasonic frequencies were used, which penetrated from the air into the aquatic environment over the entire area of the primary and secondary gateways, braked and pressed to the beds of the gateways MDCH PI;

- carried out periodic acoustic loosening of the beds of the main and additional gateways PP.

3. The full extraction of KDCH, MF and MFD PI, which are technological losses of the main gateway PP, is achieved due to the fact that:

- more efficiently retrieved KDCH, NDF and MHD already at the main gateway;

- the entire primary pulp entered the additional gateway;

- carried out secondary classification of pulp;

- acoustic waves of airborne and ultrasonic frequencies were used, which penetrated from the air into the aquatic environment over the entire area of the main and additional gateways of the software, slowed down and pressed to the beds of the gateways of the KDCH, SDCh and MDCh PI;

- carried out periodic acoustic loosening of the beds of the main and additional gateways PP.

4. Improving the reliability of the method is achieved due to the fact that acoustic emitters of ZD and SPL frequencies were used, located in the air layer, and not at the bottom of the additional gateway PP in the flow of the moving pulp, as in the prototype method.

5. Improving the efficiency of extraction of CDF, MAP and MDC PI during washing of rocks containing clay and frozen fractions, achieved due to the fact that:

- acoustic waves of airborne and ultrasonic frequencies were used, which penetrated from the air into the aquatic environment over the entire area of the main and additional PP gateways, disintegrated the PI from the rock, braked and pressed KDCH, MFD and MDC PI gateways to the beds;

- secondary pulp classification was carried out;

- carried out periodic acoustic loosening of the beds of the main and additional gateways PP.

Claims (1)

The method of washing gold sands using acoustic waves, including primary disintegration with artificial mixing of the rock and irrigation with water, the formation of the primary pulp and its direction to the entrance of the main gateway with a constant angle of inclination θ ₁ , the extraction of coarse, medium and fine particles of mineral from the rock on the main gateway of the washing device in the primary pulp stream having a flow rate V ₁ and a flow height H ₁ , natural mixing of the primary pulp, the formation of a secondary pulp and its direction to the entrance of an additional gateway having its angle of inclination θ ₂ <θ ₁ , the extraction of finely dispersed and finely dispersed mineral particles at an additional gateway in the secondary pulp stream having a flow rate of V ₂ <V ₁ and a flow height of H ₂ < ₁ H, the impact on the secondary pulp acoustic waves of sonic and ultrasonic frequency ranges by means arranged along the length of the additional gateway sound emitters and ultrasonic frequency ranges, characterized in that the education The primary and secondary pulps are carried out in the process of primary and secondary classifications by sieving, the primary classification being carried out after disintegration, and the secondary after the main gateway, at the outlet of which the primary pulp is naturally mixed, while the primary gateway of the washing device carries out continuous exposure to the primary pulp acoustic waves with the help of primary bullets placed along the length of the main gateway and oriented from top to down towards the moving stream ps of acoustic emitters of sound and ultrasonic frequency ranges, in addition, periodic pulsed acoustic loosening of the beds of the main and additional locks is carried out by waves of sound and ultrasonic ranges, and acoustic emitters are placed in air with the possibility of acoustic waves penetrating into the water environment over the entire area of the main and additional flushing locks instrument.

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