KR100741417B1 - Loading machines for ion exchange resin - Google Patents

Abstract

The present invention relates to an ion exchange resin charger, and more particularly, a resin storage and supply tank for storing and supplying a resin to be supplied to an ion exchange tower; A transport pump providing a power source to enable continuous filling of the resin; And a transport water storage tank for storing water required for the transport pump, or recovering the resin storage and supply tank and excess water in the ion exchange tower, wherein the ion exchange resin of the present invention is provided. Filling the ion exchange resin in the ion exchange column with a charger minimizes the breakage of the ion exchange resin and prevents bubbles from flowing between the resins, thus making the ion exchange resin in the slurry state to maximize the performance of the charged ion exchange tower. It can provide a useful effect of continuously charging the exchange tower.

Ion Exchange Resin, Ion Exchange Tower, Resin Charger

Description

Ion exchange resin charger {Loading machines for ion exchange resin}

1 shows a structural diagram of an ion exchange resin continuous charger of the present invention,

Figure 2 shows an ion exchange column connected to the ion exchange resin continuous charger of the present invention.

<Explanation of symbols for the main parts of the drawings>

100: Resin Storage & Supply Tank

110: transportation water injection pipe 120: resin inlet

130: resin ruler 140: observation window

150: resin supply pipe 160: vent

170: bypass tube

200: transportation pump

300: transportation water storage tank 310: excess water collection pipe

320: filter 330: vent

401, 402, 403, 404: valve

500: ion exchange tower

510: vent 520: resin injection tube

The present invention relates to an ion exchange resin charger, and more particularly, a resin storage and supply tank for storing and supplying a resin to be supplied to an ion exchange tower; A transport pump providing a power source to enable continuous filling of the resin; And a transport water storage tank for storing water required for the transport pump or recovering excess resin in the resin storage and supply tank and the ion exchange tower.

Ion exchange resins are used to remove or separate ions in water by contacting water with ions in the resin and ions in the water. Ion exchange resins are not only used to purify water at home, but also widely used for industrial purposes such as water purification and wastewater treatment. In particular, since nuclear power plants and research reactors require very high purity water for the reactor primary cooling water system and spent fuel storage tanks, ion exchange resins are very important. It is also very useful for the removal of ionic radioactive materials from radioactive wastewater from nuclear power plants, research reactors, and other nuclear facilities.

However, when filling the ion exchange resin in an ion exchange column, especially in a downflow type ion exchange column in which the most widely used fluid (water) flows down, it is very important to prevent bubbles from flowing between the ion exchange resins. Be careful. If a large amount of bubbles are introduced between the resins, it is extremely difficult to remove them and a channeling phenomenon occurs in which the fluid does not flow uniformly, thereby degrading the performance of the ion exchange tower and greatly shortening the life of the ion exchange resin.

Water degradation due to this phenomenon is a major problem in all ion exchange towers installed in homes, general industrial facilities, and nuclear industry facilities. However, when such a problem occurs in the home or general industry, it is not cumbersome to operate the ion exchange tower because the resin can be taken out, refilled, and then regenerated and used again. However, in the nuclear industry, it is necessary to pay particular attention because the resin once charged in the ion exchange tower is not recycled and used, so that the amount of waste ion exchange resins generated is increased because of the impossibility of regeneration.

Therefore, in some cases, a backwashing facility is installed in the ion exchange tower to fill the ion exchange resin in the tower during charging, and then blow water into the upper portion from the bottom of the ion exchange tower to remove air bubbles introduced between the resins. However, many ion exchange towers are not equipped with a backwashing facility for removing the air bubbles introduced in this way, and it is difficult to confirm whether the bubble removal is satisfactory even if such a facility is operated.

Therefore, it is best to prevent bubbles from flowing between the resins when the resin is first charged to the ion exchange column.

The most basic charging method involved is to fill the ion exchange column with a certain amount of distilled or demineralized water and to spread the ion exchange resin from the top of the tower. As the ion exchange resin sinks into the water, air bubbles between the resin float up and are removed. However, in general, the ion exchange resin injection tube installed in the ion exchange tower is not so wide as about 1 inch, so the ion exchange resin is not smoothly injected due to the clogging phenomenon, which requires a lot of labor and time.

The improved method is to add a large amount of distilled or demineralized water to the ion exchange resin to make a slurry and then inject the slurry into the ion exchange tower through a pump. This method is simple to charge and short in filling time, but the damage of the ion exchange resin by the pump is great and very much water (distilled or demineralized water) is required for the transfer. If there is not enough water in the slurry injected into the pump, the pump may be clogged, which may interfere with the operation.

Accordingly, the present inventors have reduced the need for a device that can continuously fill the resin without introducing air bubbles between the resin while minimizing the damage of the resin to the ion exchange column, ion exchange is more convenient and very effective filling effect The resin filling apparatus was developed and the present invention was completed.

Accordingly, an object of the present invention is to provide an ion exchange resin continuous charger for continuously filling the ion exchange resin into the ion exchange column while preventing the flow of bubbles between the resins and minimizing the breakage of the ion exchange resin. .

In order to achieve the above technical problem, the present invention, the resin storage and supply tank for storing and supplying the resin to be supplied to the ion exchange tower;

A transport pump for supplying power to push the resin stored in the resin storage and supply tank to the ion exchange tower by supplying water to the resin storage and supply tank or for supplying water directly to the ion exchange tower; ; And

Provides an ion exchange resin continuous charger comprising a; water storage tank for storing the water required for the transport pump, or to recover the excess water in the resin storage and supply tank and the ion exchange tower.

Hereinafter, the configuration and the operation of the preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a structural diagram of the ion exchange resin charger of the present invention, Figure 2 is an ion exchange tower connected to the ion exchange resin charger of the present invention, the configuration of the present invention is shown in Figure 1 , the ion exchange tower ( A resin storage and supply tank 100 for storing and supplying a resin to be supplied to 500;

Supplying water to the resin storage and supply tank 100 provides power to push the resin stored in the resin storage and supply tank 100 to the ion exchange tower 500 or to the ion exchange tower 500. A transport pump 200 which provides power for supplying water directly;

It comprises a transport water storage tank 300 for storing the water required for the transport pump, or to recover excess water in the resin storage and supply tank 100 and the ion exchange tower (500).

As shown in FIG . 1 , the resin storage and supply tank 100 has a tubular funnel shape, and includes a transportation water injection pipe 110, a resin inlet 120, a resin ruler 130, a vent 160, and a resin. The supply pipe 150, the observation window 140, the bypass pipe 170, and the like are provided.

In the resin storage and supply tank (100), a transport water injection pipe (110) and a resin inlet (120) for injecting a resin to be supplied to the ion exchange tower (500) are provided at an upper portion of the tubular shape;

Resin ruler 130 for measuring the level of the injected resin on one side of the tubular outer side, and the other side of the outer edge of the tubular connected to the transport water storage tank 300, the excess in the resin storage and supply tank 100 Vent 160 for recovering the water of the installation is installed;

The bottom of the funnel shape is provided with a resin supply pipe 150 formed with a resin drop hole coupled to the resin injection pipe 520 of the ion exchange tower, the observation window for observing the resin falling on the resin supply pipe 150 140 is installed, the predetermined side portion of the resin supply pipe 150 is connected to the transport pump 200, the bypass pipe 170 for drawing water directly into the ion exchange tower 500; includes; It is configured by.

The transport pump 200 is a general circulation pump formed on one side of the transport water storage tank 300, and transport water injection pipe 110 of the resin storage and supply tank 100 to the resin storage and supply tank 100. By supplying water through the resin storage and supply tank provides the power for pushing the resin stored in the ion exchange tower 500 connected to the lower portion. In addition, the transport pump 200 directly ionizes the water in the transport water storage tank 300 through the bypass pipe 170 of the resin storage and supply tank 100 before the resin is charged in the ion exchange tower 500. It provides power to draw into the exchange tower 500.

The transport water reservoir 300 is a tubular shape for storing transport water, and collects excess water in the on-exchange tower 500 or stores excess water in the resin storage and supply tank 100. In order to collect, an excess water collecting tube 310 and a vent 160 are formed through the upper portion thereof, respectively, and the excess water collecting tube 310 is contained in the water returned from the ion exchange tower 500 and flowed through. A sieve or filter 320 for filtering the used resin is mounted.

2 is a structural diagram showing an ion exchange tower 500 coupled to the resin supply pipe 150 and the excess water collection tube 310 of the ion exchange resin continuous charger of the present invention, the ion exchange tower 500 is known In the ion exchange tower, a vent 510 for collecting excess water in the ion exchange tower 500 and recovering the excess water to the transportation water storage tank 300; and the resin storage and supply tank ( It is configured to include a resin inlet pipe 520 for injecting the resin into the ion exchange tower 500 by connecting to the resin supply pipe 150 of the 100.

The resin injection pipe 520 is fastened with the resin supply pipe 150 of the resin storage and supply tank 100, and the vent 510 is fastened with the excess water collection pipe 310 of the transport water storage tank 300. do. When the resin is supplied, the water overflowed from the ion exchange tower 500 is collected again through the excess water collection pipe 310 and transported to the transport water storage tank 300 to be circulated again.

In this case, the ion exchange resin injected into the ion exchange tower 500 is mixed with water at a ratio of 60 to 70:40 to 30 (resin: water) and flows into the ion exchange tower 500. At this time, when the addition ratio of the resin is more than 70 or the addition ratio of water is less than 30, the flow of the mixture is not smooth. On the other hand, when the addition ratio of the resin is less than 60 or the addition ratio of the water is more than 40, the supply of the resin is relatively small. It is not preferable because there is a problem that the charging efficiency is lowered.

The action of the ion exchange resin continuous charger of the present invention having the configuration as described above is as follows.

In order to supply the resin to the ion exchange tower 500, the resin storage and supply tank 100 must first be filled with resin. Resin is filled in the resin storage and supply tank 100 as follows. First, the 401 and 403 valves installed in the transport water injection pipe 110 are opened and the 402 valves installed in the resin supply pipe 150 are closed, and then a predetermined amount of water is stored in the resin storage and supply tank 100 using the transport pump 200. After filling, the resin inlet 120 is opened and the resin to be supplied to the ion exchange tower 500 is introduced.

The resin inlet 120 may be introduced into the wet resin commercially available in a size of 20 to 30 cm in diameter without difficulty. The injected resin sinks into the water that has already been filled in the resin storage and supply tank 100 and bubbles between the resins are removed, and a resin layer is formed below the resin storage and supply tank 100, and a water layer is formed on the resin layer. do. At this time, the height and volume of the resin introduced through the resin ruler 130 can be measured.

The resin ruler 130 is the same as the water gauge attached to the general tank, but the resin is added to the resin storage and supply tank 100 when the water level when the water is initially filled in the resin storage and supply tank 100 as a reference point. If the water level is increased as it corresponds to the volume of the resin, the height and volume of the resin are measured by subtracting the height of the reference point from the height at that time. If, initially, the resin storage and supply tank 100 is filled with too much water, excess water due to the resin input is recovered to the transportation water storage tank 300 through the vent 160. After the resin has been added, the 403 valve and the resin inlet 120 are closed.

After the resin injection, the resin stored and the supply reservoir 100, a resin supply pipe (150) and a ion exchange column (500) connected to the resin injection tube 520 of the upper, and to transport the storage tank 300 shown in Figure 2 of The excess water collection tube 310 is connected to a vent 510 or an extra tube (not shown) on top of the ion exchange tower 500. Most ion exchange towers have vents and extra tubes at the top. The excess water collection pipe 310 of the transport water storage tank 300 is provided with a sieve or filter 320 having a smaller hole than the resin particles.

After the connection is completed, confirm that the water in the water storage tank 300 is sufficiently filled for transportation, and then close the 401 valve, 402 valve, and 403 valve of the resin storage and supply tank 100, open the 404 valve, and then transport pump The 200 is operated to supply a predetermined amount of water to the ion exchange tower 500 through the bypass pipe 170. At this time, the valves 401, 402, and 403 of the pipes leading to the resin storage and supply tank 100 are all closed, and water supplied to the ion exchange tower 500 is blocked from being supplied to the resin storage and supply tank 100. .

When a certain amount of water is filled in the ion exchange tower 500, the 404 valve installed in the bypass pipe 170 is closed, the 401 valve and the 402 valve are opened, and the water of the transport pump 200 is transferred to the transport water injection pipe 110. Inject. At this time, the 403 valve is closed like the 404 valve. When water is injected from the pump 200 into the resin storage and supply tank 100, the ion exchange resin, which is immersed in the water of the resin storage and supply tank 100 by the pressure, is supplied to the ion exchange tower through the resin supply pipe 150. Slip to 500). At this time, the resin is in a state of 60 ~ 70: 40 ~ 30 (resin: water) mixed with water, and when supplied to the ion exchange tower 500 is mixed with water in the ion exchange tower 500 again, the resin is ion exchange It sinks to the bottom of the tower 500, bubbles generated in the collision with the water is removed out of the water. This is done very quickly. If the excess water is supplied to the ion exchange tower 500, the excess water is recovered and circulated in the transport water storage tank 300 through the ion exchange tower vent 510 and the excess water collection pipe 310 connected thereto. . Resin that may be contained in the recovered water is filtered through the filter 320 installed in the excess water collection pipe 310, the filtered resin can be used again if necessary.

The resin supply from the resin storage and supply tank 100 to the ion exchange tower 500 can be observed through the observation window 140 made of glass or transparent plastic. When it is confirmed through the observation window 140 that all of the resin in the resin storage and supply tank 100 has been supplied to the ion exchange tower 500, the pump 200 is stopped and the ion exchange tower 500 and the charging device 100 are operated. The charging operation is completed by disconnecting 200, 300.

The ion exchange resin continuous charger of the present invention configured as described above can prevent the flow of bubbles between the resins while filling the ion exchange resin into the ion exchange tower and at the same time minimize the breakage of the ion exchange resin quickly It can be very useful to continuously charge the ion exchange column in the slurry state to maximize the performance of the ion exchange column.

Claims (5)

A resin storage and supply tank 100 for storing and supplying resin to be supplied to the ion exchange tower 500; Supplying water to the resin storage and supply tank 100 provides power to push the resin stored in the resin storage and supply tank 100 to the ion exchange tower 500 or to the ion exchange tower 500. A transport pump 200 which provides power for supplying water directly; And Ion exchange resin comprising a; water storage tank 300 for storing the water required for the transport pump, or to recover excess water in the resin storage and supply tank 100 and the ion exchange tower (500) charger. According to claim 1, wherein the resin storage and supply tank 100 is a tubular funnel shape, the resin for injecting the resin to be supplied to the transport water injection pipe 110 and the ion exchange tower 500 in the upper portion of the tubular. Inlet 120 is provided; Resin ruler 130 for measuring the level of the injected resin on one side of the tubular outer edge, and the excess water in the resin storage and supply tank 100 is connected to the transport water storage tank 100 on the other side of the tubular outer edge Vent 160 for recovering the water of the installation is installed; The bottom of the funnel shape is provided with a resin supply pipe 150 formed with a resin drop hole coupled to the resin injection pipe 520 of the ion exchange tower, the observation window for observing the resin falling on the resin supply pipe 150 140 is installed, the predetermined side portion of the resin supply pipe 150 is connected to the transport pump 200, the bypass pipe 170 for drawing water directly into the ion exchange tower 500; includes; An ion exchange resin charger, characterized in that configured by. According to claim 1, wherein the transport tank 300 is a tubular shape, the excess water in the upper portion to collect excess water in the ion exchange tower 500 and the resin storage and supply tank 100, respectively. A collecting tube 310 and a vent 160 are formed to penetrate downwards, and the excess water collecting tube 310 has a sieve or a filter for filtering resin contained in water that is returned from the ion exchange tower 500 and flows through the tube. Ion exchange resin charger, characterized in that the 320) is mounted. The ion exchange resin charger according to any one of claims 1 to 3, wherein the ion exchange resin is mixed with water at a ratio of 60 to 70: 40 to 30 (resin: water). delete

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