KR200448283Y1 - The precious metals recovery apparatus of rotating disc type to be equipped double electrodes - Google Patents

Abstract

The present invention relates to a precious metal recovery device equipped with a double electrode, the power supply for supplying power of the positive and negative poles to the positive and negative lines, respectively, the upper and the openable cap is fastened, and the precious metal is respectively attached to the lower side and the upper side The precious metal recovery tube is formed with a supply pipe and a discharge pipe into which the contained solution flows in and out, and is rotated by a reduction motor through the bottom of the precious metal recovery cylinder, and the brush is connected to the cathode ray to supply power to the cathode. The rotating shaft is mounted bearing, the rotating shaft is supplied with the power of the cathode and the insulating member surrounding the rotating shaft so that the solution containing the noble metal is not in contact with each other, the anode wire is connected to supply the power of the positive electrode, respectively A cylindrical cylindrical body made of metal mounted on an inner wall of the barrel and an outer wall of the insulating member, and the ear Located between the rapid recovery container and the anode body mounted on the insulating member, and connected to the rotating shaft is supplied with the power of the negative electrode, provided with a penetrating means through which the rotating shaft is penetrated and fixed to the penetrating means to fix the rotating shaft. A double-cylindrical cylindrical anode body covered with a metal plate provided with a member and connected to each other, a support means mounted on the rotating shaft to support the anode body, a solution tank containing a solution containing a precious metal, It is composed of a circulation pump for introducing the solution from the solution tank and circulated back to the solution tank via the noble metal recovery container.

Therefore, it is possible to recover the precious metal from both sides of the rotating anode body as well as the double electrode, and the recovery rate of the precious metal is high, and the anode body and the rotatable cathode body of porous net mesh structure have low concentration of precious metal. It is possible to recover precious metals with a high recovery rate up to not only solutions but also high concentration solutions. Especially, it is possible to easily recover platinum group elements or base metals such as copper, nickel, and cobalt in addition to gold or silver. It can also be used to prevent contamination by the cylindrical electrode, and furthermore, due to the rotating cylindrical negative electrode, the mass transfer speed is increased due to the increase of the coefficient of friction in the precious metal recovery container, and the precious metal recovery rate and recovery speed can be increased. You can check the status of precious metals recovered directly, It is a very useful design that the anode can be used for a long time without being easily oxidized even at high voltage and strong current.

Anode, cathode, power supply, anode, cathode, cylinder, circulation pump, titanium, iridium, insulation, PVC, acrylic

Description

The precious metals recovery apparatus of rotating disc type to be equipped double electrodes}

The present invention relates to a rotary precious metal recovery device equipped with a double electrode, and more specifically, it is possible to recover precious metals with a high recovery rate from a low concentration of precious metal-containing solution to a high concentration solution, and to speed up the recovery of precious metals. The present invention relates to a rotary precious metal recovery device capable of directly checking a state in which precious metals are recovered.

Since the washing water generated in the process such as plating contains a large amount of precious metals depending on the process, the recovery of such precious metals is very valuable in terms of saving resources or preventing contamination by heavy metal-containing waste water. Ion exchange resin method, metal substitution method, electrolysis method and the like have been proposed as a method for this purpose.

The ion exchange resin method recovers precious metals by adsorption of resin, and recovers precious metals by post-treatment by repeating the process of incineration of noble metals, incineration of ion resins, and then incineration. In order to increase the recovery rate of the precious metal in the recovery device, the inflow and discharge of the treated water containing the precious metal ion is smoothly performed, and the surface area of the precious metal adsorption resin is required to be activated. However, at low concentrations, precious metals are effectively adsorbed, but at high concentrations, breakthrough points are quickly brought down, and the recovery rate is lowered.In order to recover precious metals adsorbed on the resin, the incineration step has to be repeated several times. Odor and pollution occurs in the operation and the hassle to manage the operation from time to time has the disadvantage of expensive maintenance.

In addition, the metal substitution method is a method of recovering precious metals by using a substituent, and the process is labor intensive and has a disadvantage of changing the recovery rate according to the conditions of the workplace, the composition of the noble metal-containing solution, and the skill of the worker. It is not easy to recover precious metals.

The principle of the electrolysis method is to recover the noble metal by electrolyzing the solution containing the noble metal, the electron is supplied from the power source in the cathode, the cation is diffused to the electrode surface in the solution, the cation is received by the electron in the electrochemical reduction reaction To recover the precious metal by attaching it to the cathode. However, in the conventional electrolysis method, since electrolysis is performed in an electrolytic cell each having one cylindrical cathode and one anode, the surface area of the cathode decreases relatively toward the inside of the cylinder. It was difficult to adjust the change of operating conditions because it was difficult to adjust the distance between them.

In addition, since the anode and the cathode are cylindrical, it is difficult to improve the recovery efficiency of the precious metal according to the collection rate of the precious metal per unit surface area of the cathode, and the current efficiency also decreases with time.

In addition, the mass transfer rate in the precious metal recovery container depends only on the amount of inflow and discharge of precious metal wastewater, and the precious metal recovery speed is slow because the precious metal wastewater does not spread evenly in the precious metal recovery container. The anode becomes oxidized without being able to withstand high voltage and strong current.

The present invention has been devised to overcome the disadvantages of the prior art as described above, to recover the precious metal with a high recovery rate from a low concentration of noble metal solution as well as a high concentration of noble metal containing solution, in particular, in addition to gold or silver platinum group element or copper It is possible to easily recover base metals such as nickel, cobalt, etc., which can be used to prevent contamination by heavy metal-containing wastewater, and to speed up the material transfer in the precious metal recovery container, and to speed up the recovery of precious metals. The purpose of the present invention is to provide a rotary precious metal recovery device equipped with a double electrode having a positive electrode that can be used for a long time without being oxidized even in a high voltage and a strong current.

In order to achieve the above object, the rotary precious metal recovery device equipped with a double electrode of the present invention is a power supply for supplying power of the positive and negative poles to the anode line and the cathode line, respectively, the upper and the openable cap is fastened, the side wall It is provided with a noble metal recovery tank for supplying and discharging the inlet and outlet of the solution containing the precious metal in the lower part and the upper side of the side wall, and rotated by the reduction motor through the bottom of the precious metal recovery cylinder, the brush is connected to the cathode ray The cathode is supplied with power, and the rotating member on which the plurality of bearings are mounted and the insulating member surrounding the rotating shaft are prevented from contacting each other with the solution containing the precious metal, and the anode wire is connected to supply the power of the positive electrode. A cylindrical cylindrical body made of metal mounted on an inner wall and an outer wall of the insulating member, and the precious metal recovery Located between the positive electrode mounted on the through-insulating member, is connected to the rotating shaft is supplied with the power of the negative electrode, provided with a penetrating means through which the rotating shaft is penetrated, and a fixing member mounted to the penetrating means to fix the rotating shaft A double-cylindrical cylindrical anode body covered with a metal disk and connected to each other, a support means mounted on the rotating shaft to support the anode body, a solution tank containing a solution containing a precious metal, and the solution It is composed of a circulation pump for introducing a solution from the tank to circulate back to the solution tank via the precious metal recovery container.

As described above, the rotary noble metal recovery device equipped with the double electrode according to the present invention is not only equipped with a double cylindrical electrode, but also recovers the noble metal from both sides of the rotating cathode, and thus has a high recovery rate of the precious metal.

In addition, it is possible to recover precious metals with a high recovery rate not only from low concentrations of noble metal-containing solutions but also from high concentrations of solutions by using a porous mesh anode and a rotating cathode. Especially, in addition to gold or silver, platinum group elements or copper It is possible to easily recover base metals such as nickel and cobalt, which can be utilized to prevent contamination by heavy metal-containing wastewater.

Furthermore, due to the rotating cylindrical negative electrode, the mass transfer rate is increased due to the increase of the coefficient of friction in the precious metal recovery container, and the recovery rate and recovery speed of the precious metal can be increased. The anode is made of platinum or iridium-coated titanium metal plate, so it can be used for a long time without being easily oxidized even at high voltage and strong current.

In addition, the precious metal recovery device of the present invention has a simple structure and is easy to mount and dismantle the negative electrode to which the precious metal is attached by simply opening and closing the cap, so that the failure rate is low, and the usefulness of the precious metal attached in real time can be confirmed. to be.

Hereinafter, described with reference to the accompanying drawings a preferred embodiment according to the present invention.

1 is a cross-sectional view showing a rotary precious metal recovery device equipped with a double electrode according to an embodiment of the present invention.

Referring to FIG. 1, a precious metal recovery device in which a cathode equipped with a double electrode of the present invention rotates is provided from a power supply unit 100 and a precious metal wastewater supplying power to the anode line 110 and the cathode line 120, respectively. In the precious metal recovery container 200 for recovering the precious metal and the rotating shaft 290 mounted to the precious metal recovery container 200 and the insulating member 260 surrounding the rotating shaft 290 and the precious metal recovery container 200. Solution tank 300 for accommodating a solution containing a positive electrode 500 and a negative electrode 600, a support means 295 mounted on the rotating shaft 290 to support the negative electrode 600 and a precious metal ) And a circulation pump 400 for introducing the solution from the solution tank 300 and circulating the solution back to the solution tank 300 via the noble metal recovery container 200.

The power supply unit 100 includes a rectifier for obtaining DC power from AC power.

In particular, the precious metal recovery container 200 uses a cylindrical cylinder of acrylic material that can check the state of the inside, the opening and closing cap 210 is fastened to the upper side, the solution containing the precious metal in the lower sidewall and the upper sidewall respectively. The supply pipe 220 and the discharge pipe 230 discharged are formed.

In addition, the brush 280 is rotated by the speed reduction motor 270 which is adjustable in speed through the bottom surface of the precious metal recovery container 200 and the cathode wire 120 is connected to supply the cathode power, and the insulation member. A plurality of bearings 240 are mounted between the 260 and the rotating shaft 290 is provided.

In particular, the bearing 240 is preferably made of stainless so as not to rust, and is fastened to the upper and lower portions of the rotary shaft 290.

In addition, the rotating shaft 290 is the power supply of the negative electrode so that the precious metal component does not stick to the rotating shaft 290, the insulating member 260 of the polymer material is wrapped around the rotating shaft 290, the material of the insulating member 260 PVC is preferable.

The insulating member 260 is configured such that the rotating shaft 290 can be rotated by fixing the rotating shaft 290 and mounting a bearing 240 between the rotating shaft 290.

The anode body 500 is a cylindrical plate body, the anode wire 110 is connected to supply the power of the anode, and is mounted on the inner wall of the precious metal recovery container 200 and the outer wall of the insulating member 260, respectively.

In addition, the cathode body 600 is a cylindrical plate like the anode body 500, and is positioned between the precious metal recovery container 200 and the anode body 500 mounted to the insulating member 260, and the rotation shaft It is connected to the 290 is coupled to the metal plate 610 of the negative electrode is supplied with power.

In addition, the support means 295 is mounted on the rotating shaft 290 serves to support the cathode body 600.

Therefore, the precious metal-containing solution is supplied from the solution tank 300 to the precious metal recovery tank 200 by the circulation pump 400 and the precious metal is a negative electrode in the precious metal recovery container 200 by the power supplied from the power supply unit 100. Attached to the negative electrode body 600, the noble metal-containing solution is discharged through the discharge pipe 230 formed on the side wall of the noble metal recovery container 200 to enter the solution tank 300 and again through the circulation pump 400. It is circulated while flowing into the precious metal recovery tank (200).

Figure 2 is a cross-sectional view showing a rotary precious metal recovery device equipped with a double electrode according to a preferred embodiment of the present invention, the anode body 500 and the cathode body 600 shown in Figure 1 is composed of a cylindrical plate body The anode body 500 and the cathode body 600 shown in FIG. 2 show a difference that is composed of a cylindrical mesh of a mesh structure having a plurality of pores.

Therefore, as shown in FIG. 2, the anode 500 and the cathode 600 composed of a cylindrical mesh having a plurality of pores are particularly attached to and recovered from a noble metal. There is an advantage that the recovery efficiency of precious metal according to the precious metal collection rate per unit surface area than the cylindrical plate body.

In addition, the precious metal recovery container 200 shown in FIG. 2 is equipped with a weigh scale 620 so as to check the deposition amount of the precious metal in real time, and preferably a digital weigh scale is mounted and the weigh scale 620 is installed in a computer. It is also possible to implement a device that is connected to record the weight of the precious metal recovery in real time.

On the other hand, in the rotary precious metal recovery device equipped with a double electrode of the present invention can be realized by further mounting an ozone generator (not shown) in the precious metal recovery bottle 200 so that the waste liquid containing the precious metal does not rot.

Figure 3a is a perspective view showing a negative electrode body of the rotary precious metal recovery device equipped with a double electrode shown in Figure 2, Figure 3b is a negative electrode body mounted to a rotating shaft in the rotary precious metal recovery device equipped with a double electrode shown in Figure 2 It is a cross section showing.

3A to 3B, a metal plate 610 is connected to the rotating shaft 290 to supply a negative power, and has a through means 255 through which the rotating shaft 290 penetrates. It is mounted to the 255 is provided with a fixing member 250 for fixing the rotating shaft 290.

In addition, the negative electrode body 600 is coupled to the disc 610, and is a double structure of a metallic material, a cylindrical diameter small diameter negative electrode body 600 is inserted into a larger diameter negative electrode body 600 is connected to each other In addition, the precious metal recovery container 200 is positioned between the anode 500 mounted on the insulating member 260.

That is, the negative electrode body 600 is a shape in which a wide cylindrical plate body surrounds a cylindrical plate body that is connected to each other and has a smaller width, and the disc 610 covers the negative electrode body 600. The disc 610 coupled to the sieve 600 is connected to the rotating shaft 290 to supply the negative power, and thus to supply the negative electrode 600 to the dual structure negative electrode 600.

In particular, the cathode body 600 is provided with a connecting portion 605 made of soft iron on the upper portion of the cylindrical plate body of the mesh.

The connection part 605 is configured to fix the negative electrode body 600 to the disc 610, and is located at a position higher than the mounting position of the positive electrode body 500 than the discharge pipe 230 through which waste liquid containing precious metal is discharged. By being located at a high position, the noble metal is not attached and only the cathode power is transmitted to the cylindrical plate body of the mesh.

4 is a cross-sectional view showing a positive electrode of the rotary precious metal recovery device equipped with a double electrode shown in FIG. 2, referring to FIG. 4, the positive electrode 500 having a cylindrical shape as a metal material is connected to the anode line 110. Power is supplied to the anode and is mounted on the inner wall of the precious metal recovery container 200 and the outer wall of the insulating member 260, respectively.

In particular, the anode 500 is preferably made of a metal plate of platinum (Pt) or iridium (Iridium, Ir) coated titanium, which is not easily oxidized even at high voltages and strong currents. It can be used for a long time without oxidation even under high voltage and strong current.

5 is a cross sectional view showing a rotary precious metal recovery device equipped with a double electrode according to an embodiment of the present invention, referring to FIG. 5, a rotation shaft 290 is located at the center and a bearing 240 at the rotation shaft 290. It is mounted and the insulating member 260 is provided around it. In addition, an anode 500 is mounted on an outer wall of the insulating member 260 and a cylindrical cathode 600 is disposed between the anode 500 and the cathode 600. Again, the anode body 500 is mounted on the inner wall of the precious metal recovery container 200.

6 is a cross-sectional view illustrating a rotating shaft of a rotary noble metal recovery device equipped with a double electrode according to an embodiment of the present invention. Referring to FIG. 6, the rotating shaft 290 penetrates the bottom surface of the noble metal recovery container 200. The brush 280 is rotated by the reduction motor 270 and the cathode wire 120 is connected to the cathode to supply power to the cathode.

Therefore, a method of recovering the precious metal from the rotary precious metal recovery device equipped with the double electrode of the present invention is as follows.

Opening and closing the cap 210 is fastened to the upper portion of the precious metal recovery container 200, and removes the fixing means 250 fixed to the penetrating means 255 of the disc 610.

Then, after dismantling the negative electrode body 600 coupled with the disc 610 from the rotating shaft 290, the cylindrical negative electrode body 600 with the precious metal attached to the upper portion of the precious metal recovery container 200, and then the precious metal It will be recovered.

The present invention is applicable to wastewater treatment facilities that recover and recycle precious metals from solutions containing precious metals or treat wastewaters containing heavy metals.

1 is a cross-sectional view showing a rotary precious metal recovery device equipped with a double electrode according to an embodiment of the present invention

Figure 2 is a cross-sectional view showing a rotary precious metal recovery device equipped with a double electrode according to an embodiment of the present invention

Figure 3a is a perspective view showing the cathode body of the rotary precious metal recovery device equipped with a double electrode shown in FIG.

Figure 3b is a cross-sectional view showing a negative electrode body mounted on a rotating shaft in the rotary precious metal recovery device equipped with a double electrode shown in FIG.

4 is a cross-sectional view showing a positive electrode of the rotary precious metal recovery device equipped with a double electrode shown in FIG.

5 is a cross-sectional view showing a rotary precious metal recovery device equipped with a double electrode according to an embodiment of the present invention

6 is a cross-sectional view showing a rotating shaft of a rotary noble metal recovery device equipped with a double electrode according to an embodiment of the present invention

             ※ Description of the main parts of the drawing ※

100: power supply 110: anode wire

120: cathode ray 200: precious metal recovery container

210: cap 220: supply pipe

230: discharge pipe 240: bearing

250: fixing means 255: penetrating means

260: insulating member 270: reduction motor

280: brush 290: rotation axis

295: support means 300: solution tank

400: circulation pump 500: rotating disk

600: cathode 605: connection

610: disc 620: weight scale

Claims (4)

A power supply unit 100 for supplying power of the anode and the cathode to the anode line 110 and the cathode line 120, respectively; and The noble metal collection container 200 is fastened to the open and close cap 210, the supply pipe 220 and the discharge pipe 230 is formed, the inlet and outlet of the solution containing the noble metal in the lower sidewall and the upper sidewall, respectively; The brush 280 is rotated by the reduction motor 270 passing through the bottom surface of the precious metal recovery container 200, and the cathode wire 120 is connected to supply the cathode power, and the plurality of bearings 240 are provided. Rotating shaft 290 is mounted; And An insulating member 260 surrounding the rotating shaft 290 such that the rotating shaft 290 to which the cathode power is supplied and the solution containing the noble metal do not come into contact with each other; and The anode wire 110 is connected to supply the power of the anode and each of the cylindrical cylindrical body of metal material 500 is mounted on the inner wall of the precious metal recovery container 200 and the outer wall of the insulating member 260; and Located between the noble metal recovery container 200 and the anode body 500 mounted on the insulating member 260, connected to the rotating shaft 290 is supplied with a negative electrode power and penetrated through the rotating shaft 290 Is coupled to the metal plate 610 is provided with a means 255 and is mounted to the penetrating means 255 is provided with a fixing member 250 for fixing the rotating shaft 290 to a dual structure Cylindrical anode body 600 made of metal; and Support means (295) mounted to the rotating shaft 290 to support the cathode 600; And Solution tank 300 for receiving a solution containing a noble metal; And A rotary electrode equipped with a dual electrode, characterized in that consisting of; circulating pump 400 for introducing the solution from the solution tank 300 to circulate back to the solution tank 300 via the precious metal recovery container 200 Precious Metal Recovery Device The method of claim 1, The anode 500 and the cathode 600 is a rotary precious metal recovery device equipped with a double electrode, characterized in that consisting of a cylindrical mesh of the network structure having a plurality of pores The method of claim 1, The anode 500 is a rotary precious metal recovery device equipped with a dual electrode, characterized in that the metal material of titanium (Ti) coated with platinum (Pt) or iridium (Iridium, Ir). The method of claim 1, The precious metal recovery container 200 is equipped with a dual-electrode rotatable precious metal recovery device, characterized in that the weight scale 620 is installed to check the adhesion amount of the precious metal

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