KR20070001511A - Apparatus for withdrawing gold - Google Patents

Abstract

A gold recovering equipment that improves recovery efficiency of gold by using a first filter, a second filter and a third pipe and prevents backflowing of the solution within the container through a first pipe by opening or closing a second pipe according to a level of a plating solution contained in a container is provided. An equipment for recovering gold comprises: a container(110) having a first pipe(112) connected to an upper portion thereof and a second pipe(114) connected to a lower portion thereof; a first filter(130) which is installed within the container at a first elevation identical to an elevation to which the second pipe is connected so as to cut out the second pipe, and which adsorb gold contained in a solution supplied through the first pipe; a level sensor(180) for measuring a level of the solution contained in the container; and a drive part(160) for moving the first filter to open the second pipe if an elevation of the solution is a preset elevation or higher as measurement results of the level sensor, and moving the first filter to cut off the second pipe if the elevation of the solution is lower than the preset elevation.

Description

Apparatus for withdrawing gold

1 is a schematic cross-sectional view for explaining a gold recovery apparatus according to an embodiment of the present invention.

FIG. 2 is a cross-sectional view for describing a state in which a filter is moved in the gold recovery device shown in FIG. 1.

Explanation of symbols on the main parts of the drawings

110: container 112: first pipe

114: second pipe 116: third pipe

120: cap 130: first filter

140: second filter 150: guide

160: drive unit 170: shaft

180: level sensor

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gold recovery apparatus, and more particularly, to a gold recovery apparatus for recovering gold contained in aqua regia or a plating solution used in a semiconductor device manufacturing process.

In general, a semiconductor device includes a Fab process for forming an electrical circuit including electrical elements on a silicon wafer used as a semiconductor wafer, and an EDS (electrical) for inspecting electrical characteristics of the semiconductor devices formed in the fab process. die sorting) and a package assembly process for encapsulating and individualizing the semiconductor devices with an epoxy resin.

The processes include more granular processes. The subdivided processes may include plating gold on a semiconductor substrate or etching gold formed on the semiconductor substrate. Gold grains remain in the solution that is used in the plating process or the gold etching process and then treated with wastewater.

As described above, when a large amount of gold-containing plating solution or aqua regia used as a gold etching solution is treated with waste liquid, a great loss occurs. Therefore, the gold contained in the plating solution or aqua regia is recovered and reused.

In the related art, gold is adsorbed on a plating solution or aqua regia containing gold using a strong basic anion exchange resin, and then the gold is recovered by incineration of the ion exchange resin.

The conventional gold recovery method as described above has a configuration in which a gold component is adsorbed to the filter by simply flowing a plating solution or aqua regia containing gold on top of a filter such as the anion exchange resin. Therefore, when a large amount of gold is adsorbed on the filter, the flow rate of the solution is reduced by the filter or the solution cannot be flowed and blocked. This lowers the recovery efficiency of the gold and requires management of the operator. In addition, since the plating solution and aqua regia have the property of strong acid, there is a problem inherent in the danger of the worker's work. In other words, the cost is increased because automation is not performed and management of the worker is required.

 Meanwhile, in order to solve the above problem, a method of recovering gold by electrolyzing the plating solution or aqua regia was used. However, the electrolysis method has a disadvantage in that the working conditions are difficult and the recovery efficiency is not good.

In addition, the solenoid valve is installed so that it can be sent forward and reverse to increase the recovery rate of the gold, and a pressure gauge is installed at the upper end of the recovery pipe so that the solution flows forward and backward due to the pressure value of the recovery pipe, thereby clogging the recovery pipe. There are things that can be prevented, but there are disadvantages in that the installation method is complicated and the initial installation cost is high.

An object of the present invention for solving the above problems is to provide a gold recovery apparatus that can improve the recovery efficiency of gold contained in the plating solution or aqua regia.

According to a preferred embodiment of the present invention for achieving the object of the present invention, the gold recovery device is provided with a container in which the first pipe is connected to the top, the second pipe is connected to the bottom. The first filter is provided to block the second pipe at the same first height as the height of the second pipe connected to the inside of the container, and adsorbs gold contained in the solution supplied through the first pipe. The level sensor measures the level of solution in the vessel. The driving unit moves the first filter to open the second pipe when the height of the solution is greater than or equal to a preset height, and blocks the second pipe when the height of the solution is less than a preset height. Move the first filter.

The gold recovery apparatus may be provided at a second height lower than the first height inside the container, and may further include a second filter for adsorbing the gold when the level of the solution is lower than the first height. . In addition, it may further include a cap for opening the container when the first filter and the second filter is replaced.

In the gold recovery apparatus according to the present invention configured as described above, when the flow of the solution discharged through the second pipe by the gold adsorbed to the filter is deteriorated, the level of the solution inside the container is increased. The second pipe that was blocked off is opened. Therefore, the backflow of the solution can be prevented.

Hereinafter, a gold recovery apparatus according to a preferred embodiment of the present invention with reference to the accompanying drawings will be described in detail.

1 is a schematic cross-sectional view for explaining a gold recovery device according to an embodiment of the present invention, Figure 2 is a cross-sectional view for explaining a state in which the filter is moved in the gold recovery device shown in FIG.

1 and 2, the gold recovery apparatus 100 includes a container 110, a cap 120, a first filter 130, a second filter 140, a guide 150, a driving unit 160, Axis 170, and level sensor 180.

The container 110 provides a space for filtering a solution such as a plating solution or aqua regia containing gold. The container 110 may be provided in various forms such as cylindrical or rectangular parallelepiped. The first pipe 112 having a first height is connected to the upper side of the container 110. The first pipe 112 is a passage for supplying the solution to the container 110.

A second pipe 114 having a height lower than the first height is connected to the lower side of the container 110. The second pipe 114 is a passage for discharging the solution, which has been adsorbed, to the outside of the container 110.

A third pipe 116 branched from the second pipe 114 and connected to the container 110 at a third height lower than the second height is provided at a lower side of the container 110. The third pipe 116 recovers the solution discharged through the second pipe 114 to increase the recovery efficiency of the gold contained in the solution. The portion connected to the second pipe 114 in the third pipe 116 may have a funnel shape to facilitate the recovery of the solution.

The third pipe 116 is provided to be inclined relative to a horizontal plane to recover the solution discharged through the second pipe 114 into the container 110. For example, the inclination of the third pipe 116 is about 1 to 30 degrees.

On the other hand, the amount of the solution supplied through the first pipe 112 is preferably smaller than the amount of the solution discharged through the second pipe (114). Therefore, the diameter of the first pipe 112 is formed to be smaller than the diameter of the second pipe 114.

When the diameter of the first pipe 112 is larger than the diameter of the second pipe 114, the solution discharged through the second pipe 114 than the amount of the solution supplied through the first pipe 112. The second pipe 114 is provided with at least two so that the amount of. At least two second pipes 114 are provided in one pipe at a point spaced apart from the container 110 by a predetermined interval.

The cap 120 is provided on an upper portion of the container 110 and opens the container 110.

The first filter 130 adsorbs the gold contained in the solution. An ion exchange resin may be used as the first filter 130. The ion exchange resins include cation exchange resins, anion exchange resins and amphoteric ion exchange resins. Since the solution has a strong acidity, an anion exchange resin having a strong basicity is used for the first filter 130.

The first filter 130 is provided at the same height as the second height. The first filter 130 has the same cross-sectional shape as that of the second pipe 114. Therefore, the second pipe 114 may be opened and closed using the first filter 130. When the first filter 130 closes the second pipe 114, the solution in the container 110 is discharged through the second pipe 114 while being filtered by the first filter 130. do. When the first filter 130 opens the second pipe 114, the solution in the container 110 passes through the second pipe 114 without being filtered by the first filter 130. Discharged.

When the plurality of second pipes 114 are provided, the first filter 130 is also provided with the same number as the second pipes 114.

The second filter 140 also adsorbs the gold contained in the solution. Like the first filter 130, the first filter 140 is an anion exchange resin having a strong basicity.

The second filter 140 is provided at a height equal to or lower than the third height. Accordingly, the second filter 140 filters the solution when the solution level in the container 110 is lower than the second height. In addition, the second filter 140 may be positioned to be adjacent to the connection portion between the third pipe 116 and the container 110 to filter the solution recovered by the third pipe 116.

Thus, if the level of the solution is lower than the second height, the solution is filtered by the second filter 140. That is, gold is adsorbed to the second filter 140. If the level of the solution is equal to or higher than the third height, the solution is filtered by both the first filter 130 and the second filter 140. That is, gold is adsorbed to both the first filter 130 and the second filter 140.

Although not shown, the first filter 130 and the second filter 140 are inserted into the filter frame.

The guide 150 is provided across the side wall on the inner top of the container (110). The guide 150 is preferably located higher than the first height.

The driving unit 160 is provided in the guide 150 to perform a linear reciprocating motion along the guide 150. The driving unit 160 is connected to the first filter 130 by the shaft 170. Precisely the shaft 170 is connected to the filter frame into which the first filter 130 is inserted. Therefore, the first filter 130 also linearly reciprocates according to the linear reciprocating motion of the driving unit 160. Therefore, the first filter 130 may close and open the second pipe 114. The shaft 170 is also preferably connected to the second filter 140.

The level sensor 180 measures the solution level in the container 110 while moving up and down along the axis 170.

When the level of the solution measured by the level sensor 180 is lower than the preset height, the driving unit 160 is driven to maintain the state in which the first filter 130 blocks the second pipe 114. (See FIG. 1) The predetermined height is preferably a height level slightly lower than the first height. When the level of the solution measured by the level sensor 180 is higher than the predetermined height, the driving unit 160 is driven so that the first filter 130 opens the second pipe 114. Reference)

When the second pipe 114 is opened, a warning unit (not shown) may be provided to issue a warning.

Meanwhile, the amount of gold discharged through the second pipe 114 is reduced by adsorbing a lot of gold to the filters 130 and 140. As a result, the solution level of the container 110 is increased, and the second pipe 114 is opened according to the operation of the driving unit 160. Therefore, the opening of the second pipe 114 may also be used as an exchange signal of the filters 130 and 140.

For example, when the level of the solution is low and the distance between the level sensor 180 and the driving unit 160 is wide, the driving unit 160 allows the first filter 130 to connect the second pipe 114. It is driven to maintain the blocked state. When the level of the solution is increased so that the distance between the level sensor 180 and the drive unit 160 is less than the reference, the drive unit 160, the first filter 130 opens the second pipe 114. Is driven to. When the second pipe 114 is opened and the level of the solution is lowered again, the distance between the level sensor 180 and the driving unit 160 is widened, so that the driving unit 160 has the first filter 130. It is driven to block the second pipe 114.

The second pipe 114 is opened by the driving unit 160 even if the solution level of the container 110 rises due to the reduction of the discharge of the solution through the second pipe 114. Therefore, the phenomenon in which the solution in the container 110 flows back along the first pipe 112 can be prevented.

Hereinafter, the operation of the gold recovery device 100 will be described.

In the state in which the first filter 130 blocks the second pipe 114, a solution including gold is supplied to the container 110 through the first pipe 112. When the level of the solution is lower than the second height, which is the height of the second pipe 114, the solution is filtered by the second filter 140. That is, gold included in the solution is adsorbed on the second filter 140.

If the solution continues to be supplied through the first pipe 112, the level of the solution rises. When the level of the solution rises to the second height, the solution is filtered by the first filter 130 as well as the second filter 140. That is, the gold contained in the solution is adsorbed to the first filter 130 as well. The solution is filtered by the first filter 130 and then discharged to the outside through the second pipe 114.

Some of the solution discharged to the outside through the second pipe 114 is supplied back to the container 110 through the third pipe 116. The solution recovered into the container 110 is filtered again by the first filter 130 and the second filter 140. Therefore, the recovery efficiency of gold from the solution can be improved.

As gold is adsorbed to the first filter 130, the amount of the solution discharged through the second pipe 116 is smaller than the amount of the solution supplied through the first pipe 114. Thus, the level of the solution gradually rises.

When the level of the solution reaches a predetermined level, the driving unit 160 moves along the guide 150. Therefore, the first filter 130, which is connected to the driving unit 160 and blocks the second pipe 114, also moves in a direction away from the second pipe 114. The second pipe 114 is opened.

Therefore, the solution inside the container 110 may be prevented from flowing back through the first pipe 112.

The amount of the solution discharged through the second pipe 116 is greater than the amount of the solution supplied through the first pipe 114 is opened. Therefore, the level of the solution gradually decreases.

When the level of the solution is lowered, the driving unit 160 moves again along the guide 150. Therefore, the first filter 130 also moves to block the second pipe 114 again.

Thereafter, the operation of opening and blocking the second pipe 114 by the first filter 130 is repeated according to the solution level in the container 110.

Meanwhile, whenever the first filter 130 opens the second pipe 114, the cap 120 may be opened to replace the first filter 130 and the second filter 140. Gold may be recovered by burning the filters 130 and 140 removed from the container 110.

As described above, the gold recovery apparatus according to the preferred embodiment of the present invention can improve the recovery efficiency of the gold using the first filter, the second filter and the third pipe. In addition, opening and closing the second pipe according to the level of the solution can prevent the solution in the container from flowing back through the first pipe.

On the other hand, since the management of the operator is unnecessary other than the replacement of the filters can reduce the risk of the operator.

While the foregoing has been described with reference to preferred embodiments of the present invention, those skilled in the art will be able to variously modify and change the present invention without departing from the spirit and scope of the invention as set forth in the claims below. It will be appreciated.

Claims (6)

A container having a first pipe connected to the upper portion and a second pipe connected to the lower portion; A first filter provided to block the second pipe at a first height equal to a height at which the second pipe is connected to the inside of the container, and for adsorbing gold contained in the solution supplied through the first pipe; A level sensor for measuring a solution level in the vessel; And The first filter is moved to open the second pipe when the height of the solution is greater than or equal to a preset height, and the second pipe is blocked to block the second pipe when the height of the solution is less than a preset height. The gold recovery device further comprises a drive unit for moving the filter. The method of claim 1, further comprising a second filter provided inside the vessel at a second height lower than the first height and for adsorbing the gold when the level of the solution is lower than the first height. Gold recovery apparatus characterized by the above-mentioned. 3. The gold recovery apparatus of claim 2, further comprising a cap for opening the container when the first filter and the second filter are replaced. The gold recovery device according to claim 2, wherein the first filter and the second filter are ion exchange resin filters. The gold recovery apparatus of claim 1, further comprising a third pipe branched from the second pipe and connected to the container at a third height lower than the second height. The gold recovery apparatus of claim 5, wherein the third pipe has an inclination with respect to a horizontal plane to recover the solution discharged through the second pipe into the container.

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