KR101948527B1 - Reactor for extracting precious metals - Google Patents

Abstract

The present invention relates to a reactor for extracting precious metals, which mixes ore powder and a reaction solution in a reaction tank, and irradiates ultrasonic wave, ultraviolet (UV) ray, high frequency, microwave, and the like in order to extract precious metals, such as gold, silver, platinum, palladium, and the like, from alluvial gold or powder (hereinafter, referred to as ore powder) formed by pulverizing placer, so as to separate sulfur and iron components from the ore powder. According to the present invention, the reactor for extracting precious metals comprises: a plurality of UV lamps (20) mounted on the circumference of a cylindrical part of the reaction tank (10) to irradiate UV ray into the reaction tank (10); an ultrasonic vibration device (30) mounted on a lower inclined part (11) of the reaction tank (10); an upper inlet (12) formed on the upper surface of the reaction tank (10) to input the ore powder into the reaction tank (10) therethrough; and an agitator (40) disposed in the reaction tank (10) to be rotated by a motor (M) in order to agitate the ore powder supplied into the reaction tank (10). The reaction solution of a reaction solution tank (50) is supplied to the reaction tank (10) through a first supply pipe (L1) and water of a water tank (60) is supplied to the reaction tank (10) through a second supply pipe (L2).

Description

[0001] REACTOR FOR EXTRACTING PRECIOUS METALS [0002]

In the present invention, in order to extract noble metals such as gold, silver, platinum, palladium and the like from powders obtained by pulverizing quartz or diffuse light (hereinafter referred to as "ore powders"), the ore powders and the reaction liquid are mixed in a reaction tank, Silver, platinum, palladium or the like by irradiating a molten metal or a molybdenum, a microwave, a UV, or the like to the ore powder and separating the sulfur component and the iron component from the ore powder.

Korean Patent Application Publication No. 10-2000-0073145 (published on December 5, 2000) discloses "a precious metal extraction apparatus and a precious metal extraction method ".

The noble metal extracting apparatus includes a cylindrical reaction tank having a large long end ratio, a reactant input port for inputting the slurry into the reaction tank, a rotating means for rotating the cylindrical reaction tank, a plurality of heating wires for maintaining the inside of the reaction tank at a predetermined temperature A lifting means for lifting one end of the reaction tank after the reaction; and a lifting means for lifting the one end of the reaction tank by the lifting means, A pump for injecting the solution in the storage tank through the washing nozzle into the reaction tank for washing the inside of the reaction tank after the reaction, a filter for filtering the reaction product in the slurry discharged through the outlet, Then, the filtrate separated from the filter is refined and the solution after refining is stored in a storage tank Include refining means for conveying a.

However, in the above-described precious metal extraction device, an electric heater of a hot-wire winding type is mounted around the reaction tank, and merely the electric heater functions to maintain the temperature in the reaction tank at a predetermined temperature.

Accordingly, an object of the present invention is to provide a method of mixing a ore powder and a reaction liquid in a reaction tank to extract noble metals such as gold, silver, platinum, and palladium from powder (ore powder) obtained by pulverizing quartz or diffuse light, Wave, UV, or the like to promote the separation of sulfur and iron components in the ore powder, thereby maximizing the reaction rate of the reaction liquid and reducing the reaction time.

In order to accomplish the above object, the present invention provides a reactor for extracting noble metal, wherein a plurality of UV lamps are installed around a cylindrical portion of a reaction vessel so as to irradiate UV into the reaction vessel, The apparatus is equipped with an upper input port formed on the upper surface of the reaction tank, an ore powder is introduced into the reaction tank through the upper input port, and a stirrer rotated by a motor is provided so as to stir the ore powder supplied into the reaction tank. The reaction liquid in the reaction liquid tank is supplied to the reaction tank through the first supply pipe and the water in the water tank is supplied to the reaction tank through the second supply pipe.

The reactor for extracting noble metal according to the present invention is characterized in that a high-frequency device or a microwave device is additionally installed in the reaction tank.

Alternatively, the reactor for extracting precious metals according to the present invention is characterized in that a high-frequency device or a microwave device is mounted in the reaction tank instead of the ultrasonic vibrator.

The reactor for extracting the noble metal according to the present invention further comprises electromagnet means mounted in the reaction tank at a position that does not interfere with the operation of the stirrer, wherein sulfur and iron components are decomposed after the ore powder and the reaction liquid are reacted in the reaction vessel The noble metal in the ore powder contained together with iron is discharged to the electromagnet to increase the recovery rate of the noble metal.

The reactor for extracting noble metals according to the present invention comprises a pH measuring sensor mounted on a reaction tank for measuring the PH concentration in the reaction tank, a contamination measuring sensor for measuring the contamination degree of the reaction solution in the reaction tank, And a return tank for receiving and storing a drainage pipe and a reusable reaction solution mixture after the concentrating process from the reaction tank to discharge the contaminated reaction solution mixture when the reaction solution is contaminated to a degree that can not be achieved.

The noble metal extraction reactor according to the present invention further comprises a screw feeder device for receiving the ore powder sludge discharged through the sludge discharge gate of the reaction tank and concentrating the ore powder sludge again.

The screw feeder device is provided with a feed screw and a downstream outlet formed in a cylindrical case surrounding the feeding screw, a plurality of UV lamps are mounted around the cylindrical case, and the downstream side of the cylindrical case An air injection port is formed, and high temperature air is supplied to the cylindrical case through the air injection port.

Thus, the reactor for extracting the noble metal according to the present invention maximizes the reaction rate of the reaction solution and reduces the reaction time, thereby effectively separating the sulfur component and the iron component, and shortening the operation time .

1 is a schematic view showing a reactor for extracting a noble metal according to the present invention
Fig. 2 is an enlarged detail view showing the reaction vessel of Fig. 1

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

1 and 2, a reactor for extracting a noble metal according to the present invention includes a plurality of UV lamps 20 mounted around a cylindrical portion of a reaction tank 10 so as to irradiate UV into the reaction tank 10 An ultrasonic vibration device 30 is mounted on the lower inclined portion 11 of the reaction tank 10 and an upper input port 12 is formed on the upper surface of the reaction tank 10 to form an ore powder (Not shown) is introduced into the reaction tank 10 and an agitator 40 rotated by a motor M is placed in the reaction tank 10 so that the ore powder supplied into the reaction tank 10 can be stirred. The reaction liquid in the reaction liquid tank 50 is supplied to the reaction tank 10 through the first supply pipe L1 and the water in the water tank 60 is supplied to the reaction tank 10).

The reactor for extracting noble metal according to the present invention having the above-described structure is characterized in that the ore powder is introduced into the reaction tank 10 through the upper inlet port 12 and the reaction liquid is supplied through the first supply pipe L1 and the second supply pipe L2 And water are supplied to the reaction tank 10 while the UV lamp 20 is turned on to irradiate UV light while stirring with the stirrer 40 so that the ultrasonic vibrator 30 operates.

As a result, the ore powder is mixed with the reaction liquid and water to be sludge, and the sulfur component and the iron component are decomposed and dissolved in the ore powder by the reaction liquid, and thus precious metals such as gold, silver, platinum and palladium are easily extracted It becomes a sludge-like mineral.

At this time, the stirrer 40 slowly rotates slowly at low speed, and the ore powder is mixed well with the reaction liquid and water, and UV is irradiated from the UV lamp 20 to raise the internal temperature of the reaction tank 10 As the photodegradation effect, the chemical action of the reaction liquid is accelerated so that the sulfur component and the iron component can be decomposed in the ore powder, and the ultrasonic wave of the ultrasonic vibrator 30 causes a strong collision between the particles, Not only promotes the decomposition of the components, but also prevents the separated sulfur and iron components from re-adhering to the ore powders. In addition, when UV and ultrasonic waves are irradiated in parallel, the selectivity and elimination efficiency of the elimination material, which are limitations of ultrasound and UV respectively, are complemented, and the overall treatment efficiency is increased, Components and other interfering substances can be more effectively separated.

The reactor for extracting noble metal according to the present invention may further include a high frequency device (not shown) or a microwave device (not shown) in addition to the reaction tank 10 or a high frequency device or a microwave The device can be mounted.

The high-frequency device and the microwave device not only increase the temperature of the reaction solution but also promote the chemical reaction between the reaction solution and the ore powder.

The reactor for extracting noble metal according to the present invention further includes an electromagnet means 70 mounted on the reaction tank 10 so as not to interfere with the operation of the stirrer 40.

The electromagnet means 70 is well known and will not be described in detail here.

Accordingly, when power is applied to the electromagnet means 70, the ore powder containing the iron component is attached to the electromagnet means 70 without decomposing the iron component by the reaction liquid, and the concentrating process by the reaction liquid is performed The ore powder attached to the electromagnet means 70 can be separated by disconnecting the electric power supplied to the electromagnet means 70 after the electromagnet means 70 is taken out of the reaction tank 10 after completion. Thereafter, the ore powder separated by the electromagnet means 70 is subjected again to a separate concentrating process.

The reactor for extracting noble metal according to the present invention constituted as described above is provided with a pH measurement sensor 72 mounted on the reaction tank 10 for measuring the PH concentration in the reaction tank and a pH measurement sensor 72 for measuring the degree of contamination of the reaction solution in the reaction tank 10 A contamination measuring sensor 74 and a drain pipe 76 for discharging the contaminated reaction mixture when the reaction solution mixed with the water filled in the reaction tank 10 is contaminated to such an extent that it can not be reused, And a return tank (80) for receiving and storing a possible reaction mixture from the reaction tank (10).

As a result, when the pH measurement sensor 72 measures the PH concentration in the reaction tank 10 and the PH concentration in the reaction tank is higher than the set value, the reaction solution is automatically added by the automatic quantitative feeder, Is less than the set value, water is automatically added by the constant amount feeding device to maintain the PH concentration in the reaction tank at the set value. After the concentrating process is completed, the contamination measuring sensor 74 measures the degree of contamination of the reaction solution mixture, and when the reaction solution mixture can not be reused, the reaction solution mixture is discharged to the outside through the drain pipe 76, If the mixture can be reused, the reaction liquid mixture is supplied to the return tank 80. Then, the reaction liquid mixture supplied to the return tank 80 is reused in the next concentrating process.

The noble metal extracting reactor according to the present invention further includes a screw feeder device 90 for receiving the ore powder sludge discharged through the sludge discharge gate 15 of the reaction tank 10 and concentrating the ore powder sludge again .

The feed screw 92 is operated by the motor 91 and the upstream inlet 94 and the downstream outlet 95 are formed in the cylindrical case 93 surrounding the feeding screw 92 A plurality of UV lamps 96 are mounted on the circumference of the cylindrical case 93 and an air inlet 97 is formed on the downstream side of the cylindrical case 93 so that high temperature air is supplied through the air inlet 97 And is supplied to the cylindrical case 93.

In the screw feeder apparatus 90 configured as described above, the feeding screw 92 is operated by the motor 91 so that the ore powder sludge supplied to the upstream inlet 94 passes through the cylindrical case 93 and flows into the downstream outlet 95). At this time, the internal temperature of the cylindrical case 93 increases the temperature of the reaction liquid contained in the ore powder sludge by the high-temperature air supplied through the air inlet 97, so that the chemical action of the reaction liquid and the ore powder is promoted, The UV of the UV lamp 96 is irradiated with ore powder sludge to accelerate the reaction of the reaction liquid.

10: Reactor 20: UV lamp
30: ultrasonic vibration device 40: stirrer
50: Reaction liquid tank 60: Water tank

Claims (7)

A plurality of UV lamps 20 are mounted around the cylindrical portion of the reaction tank 10 so that UV can be irradiated into the reaction tank 10 and an ultrasonic vibration device And the upper orifice 12 is formed in the upper surface of the reaction tank 10 so that the ore powder is introduced into the reaction tank 10 through the upper inlet port 12, An agitator 40 rotated by a motor M is disposed inside the reaction tank 10 so that the reacted liquid of the reaction liquid tank 50 is supplied to the first supply pipe L1 The water in the water tank 60 is supplied to the reaction tank 10 through the second supply pipe L2,
A pH measuring sensor 72 mounted on the reaction tank 10 for measuring the PH concentration in the reaction tank 10; a contamination measuring sensor 74 for measuring the contamination degree of the reaction solution in the reaction tank 10; A drain tank 76 for discharging the contaminated reaction liquid mixture and a return tank 76 for supplying and storing a reusable reaction liquid mixture after the concentrating process from the reaction tank 10 80). ≪ / RTI >
The method according to claim 1,
Characterized in that a high-frequency device or a microwave device is additionally installed in the reaction tank (10).
The method according to claim 1,
Characterized in that a high-frequency device or a microwave device is mounted in the reaction tank (10) instead of the ultrasonic vibrator (30).
The method according to claim 1,
Further comprising electromagnet means (70) mounted in the reaction tank (10) so as not to interfere with the operation of the stirrer (40).
delete The method according to claim 1,
Further comprising a screw feeder device (90) for receiving the ore powder sludge discharged through the sludge discharge gate (15) of the reaction tank (10) and re-concentrating the ore powder sludge.
The method according to claim 6,
The feed screw 92 is operated by the motor 91 and the upstream inlet 94 and the downstream outlet 95 are formed in the cylindrical case 93 surrounding the feeding screw 92 A plurality of UV lamps 96 are mounted on the circumference of the cylindrical case 93 and an air inlet 97 is formed on the downstream side of the cylindrical case 93 so that high temperature air is supplied through the air inlet 97 And is supplied to the cylindrical case (93).

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