KR0161346B1 - Carrying, separating and regenerating, method and apparatus of ion exchange resin - Google Patents

Abstract

The present invention relates to an ion exchange resin feed separation regeneration method and apparatus of an out-of-column regeneration type multiphase desalination plant. The ion exchange resin transfer separation and regeneration method of the out-of-column regeneration type multiphase desalination plant according to the present invention is to transfer the mixed phase resin of the multiphase ion exchange resin tower which has lost the desalting function to the separation tower and the cation exchange resin regeneration tower (1). step; Transferring the intermediate resin 14 stored in the intermediate resin storage tower 2 to the separation tower and the cation regeneration tower 1; By using the circulating water of the circulating water storage container (4), the mixed resins (12, 13) and the intermediate resin (14) of the separation column and the cation regeneration tower (1) are backwashed to obtain the anion exchange resin (12) and the cation exchange resin. Separating into (13); In order to transfer the resin separated in the above step to the top of the separation tower and the cationic regeneration tower 1 while maintaining the separated state, the resin is backwashed at a flow rate of 20 m / H or more, and the top of the separation tower and the cationic regeneration tower 1 is separated. And backwash water at a flow rate of 5 m / H or more to maintain the separation resin from the lower part of the separation column and the cationic regeneration tower (1) using the circulation water of the circulation water storage container (4). Circulating by the pump 5; Transferring the anion exchange resin 12 to the anion regeneration tower 3 through a resin transfer path at the top of the separation column and the cation regeneration tower 1; Transferring the intermediate medium resin 14 to the intermediate medium resin storage tower 2 through the resin transfer path at the top of the separation tower and the cationic regeneration tower 1; And regenerating the cation exchange resin 13 of the separation column and the cation regeneration tower 1 and the anion exchange resin 12 of the anion regeneration tower 3 using the regenerant.

Description

Method and device for transport separation regeneration of ion exchange resin in regeneration type multiphase desalination plant

FIG. 1 is a schematic process diagram showing a state waiting to be transferred to a separation tower and a cation regeneration tower in order to regenerate a mixed phase ion exchange resin tower resin which has lost its desalting function.

2 is a schematic process chart showing a state in which the intermediate resin for resin separation is transferred.

3 is a schematic process chart showing a state where the mixed resin is separated by a backwashing process.

Figure 4 is a schematic process diagram showing the state sent to the top of the tower by a backwashing process to transfer the separation resin.

5 is a schematic process diagram showing a state in which anion exchange resin is transferred for regeneration.

6 is a schematic process chart showing a state in which the intermediate resin for resin separation is transferred.

7 is a schematic process diagram showing a state in which the resin is regenerated by the regenerant.

* Explanation of symbols for the main parts of the drawings

1: Separation tower and cation regeneration tower 2: Intermediate media resin storage tower

3: anion regeneration tower 4: circulating water storage container

5: circulating water circulation pump 6: cation regenerator inlet pipe

7 mixed bed resin inlet tube 8: compressed air inlet tube

9: anion regeneration agent inlet tube 10: resin transfer tube

11: regeneration water inlet pipe 12: anion exchange resin

13: cation exchange resin 14: intermediate media resin

The present invention relates to an ion exchange resin transfer separation regeneration method and apparatus for a regeneration type multiphase desalination plant of a tower. More specifically, the present invention minimizes the amount of sodium-type (Na ⁺ ) cation exchange resin to be incorporated into the multiple demineralization water system by transporting and regenerating the ion exchange resin of the regeneration-type multiphase desalination plant outside the tower at the top of the separation tower. The present invention relates to an ion exchange resin transport separation regeneration method and apparatus capable of obtaining highly purified water and effectively separating and regenerating ion exchange resins.

In general, water is widely used for steam generation or other purposes in steam turbine facilities or other industrial facilities. In particular, the water to be supplied to the steam generator of the steam turbine power generation equipment should be used pure water and solid ionic substances that cause corrosion and corrosion on the surface of the turbine blades, tubes, etc. thoroughly.

Although plural cycles are closed, components that cause surface corrosion or corrosion accumulate in the plural due to inflow of supplemental water or leakage of cooling water system. ^_ ) And the hydrogen ion (H ⁺ ) degree of the strongly acidic resin are formed by substitution reaction with ammonium ion (NH ₄ ⁺ ), and it is known that the best results can be obtained when the mixed ion exchange resin tower is used. have.

When the plurality is passed through the mixed phase ion exchange resin tower, most of the heavy metal oxides or ionic substances contained in the plurality are removed by the ion exchange resin, and thus the ion exchange resin gradually loses the ion exchange function. Therefore, the cation exchange resin which has lost the desalting function is regenerated by a strong acid such as sulfuric acid or hydrochloric acid, and the anion exchange resin is regenerated by a strong alkali such as caustic soda.

However, after the regeneration of the ion exchange resin was completed according to the above process, the biggest problem that emerged in the process of operating a plurality of desalination plants was ion leakage. Here, the ion leakage does not mean the ion leakage from the plurality caused by the impurity ions contained in the plurality not being removed by the ion exchange resin during the normal operation of the mixed bed ion exchange resin tower, but regeneration Ion leaks from a type of contaminated resin, especially sodium ions (Na ⁺ ) and chlorine, reacted with unwanted chemicals in the process of treating ion exchange resins that have lost their function in the facility to recover ion exchange capacity. It means the leakage of ions (Cl ^_ ).

In general, the resin separation method of the mixed bed ion exchange resin is backwashed, and the light weight anion exchange resin is sent to the top of the tower, and the heavy cation exchange resin is dependent on the technique of hydraulic separation that drops to the bottom of the tower.

However, the resin separation method by the simple hydraulic separation was largely separated into a heterogeneous resin composed of a cation exchange resin and an anion exchange resin, but the heterogeneous water of the mixed layer formed around the boundary layer of the cation exchange resin and the anion exchange resin. There was a limit that can not be separated completely.

This is due to the resin being crushed during the operation of multiple desalination plants. Since the above-mentioned hydraulic separation technique depends not only on the specific gravity of the resin but also on the particle size of the resin, the crushed resin is surrounded by the boundary layer between the cation exchange resin and the anion exchange resin. Densely distributed to form a mixed layer.

Therefore, no matter how careful the surroundings, when the anion exchange resin is transferred from the cation exchange resin to a separate independent tower, the mixed layer formed around the heterogeneous resin boundary layer is inevitably swept along with the anion exchange resin. The small amount of cation exchange resin swept away causes sodium ions (Na ⁺ ) leakage, whereas the remaining anion exchange resins in the cation exchange resin layer cause leakage such as chlorine ions and sulfate ions (SO ₄ ^2- ). .

Among these causes of leakage, sodium ions (Na ⁺ ) or chlorine ions that enter the ion exchange resins, which are contaminated with iron oxides, are not removed but remain inside the ion exchange resins. Leaching and leaking, ammonia perfusion is caused by the ammonia injected to control the acidity (pH) and release sodium ions (Na ⁺ ).

However, high-pressure perfusion boilers, hard water reactors, or pressurized water nuclear power plants in thermal power plants strictly regulate the concentrations of sodium ions (Na ⁺ ) and chlorine ions in the plural treated waters. Even leaking ions can cause very serious problems in multiple systems.

As described above, in order to reduce the ion leakage, especially the leakage of sodium ions, which is the biggest problem while operating the multiple desalination plant, a new process is added over the multiple desalination method using the conventional resin separation method. One special plural desalting method has emerged. This uses a large amount of the ammonia solution in a small amount of cation exchange resin containing swept away with a later reproduction of the anion exchange resin by a sodium hydroxide is complete, the anion exchange resin, sodium (Na ⁺⁾ type cationic ammonium exchange resin (NH ₄ ⁺⁾ It is a method of substituting a type cation exchange resin.

However, the conventional method described above requires a large amount of ammonia and a long regeneration period to remove relatively small amounts of sodium ions (Na ⁺ ), but cannot completely remove sodium ions (Na ⁺ ). I had it.

As another method, sodium (Na ⁺ ) type cations using a calcium hydroxide [Ca (OH) ₂ ] solution in a small amount of cation exchange resin swept along with the anion exchange resin after the regeneration of the ion exchange resin by caustic soda is completed. There is a method of replacing the exchange resin with a calcium (Ca ²⁺ ) type cation exchange resin, which is an insoluble calcium hydroxide which may be present in the piping and anion exchange resin after injection of the calcium hydroxide [Ca (OH) ₂ ] solution is completed. In order to prevent the coagulation of [Ca (OH) ₂ ] particles, it must be thoroughly washed, and additional injection equipment and additional chemicals are required to inject calcium hydroxide [Ca (OH) ₂ ] This demanded, and had the problem that strict attention is required in operation.

When the chemical method for preventing ion leakage has the problems as described above, it corresponds to the middle of the specific gravity of the anion exchange resin and the cation exchange resin specific gravity to prevent the cation exchange resin from being mixed on the anion exchange resin. There has been a way to separate the resin using any intermediate media. This is a method of performing plural desalination by using a method of flotation of anion exchange resin from the cation exchange resin using a liquid having any particular specific gravity corresponding to the middle of the cation exchange resin and the anion exchange resin.

In this case, as the intermediate specific gravity solution, 8-16% of caustic soda solution is used. When such intermediate mediator is used, an anion exchange resin layer on the top, a caustic soda solution layer on the middle, and a cation exchange resin layer on the bottom It was able to successfully separate the ion exchange resin.

However, this method inevitably comes into contact with the strong alkaline caustic soda solution, even with a small amount of cation exchange resin, and it requires a large amount of caustic soda solution and also requires a large amount of washing water. In addition to being uneconomical, the regeneration process was complicated and consumed a lot of regeneration time.

On the other hand, in order to supplement the above-mentioned drawbacks of the prior art, by using an active resin mixed with a certain amount of an inert resin or a cation exchange resin and an anion exchange resin as an intermediate medium for the resin separation, all the above-mentioned process has a problem The method to solve this problem was suggested. That is, in addition to the mixed resin composed of a cation exchange resin and an anion exchange resin for the purpose of plural desalination before the backwashing process, an active resin composed of a certain amount of an inert resin or a cation exchange resin and an anion exchange resin for the purpose of resin separation only It is added as a medium resin and then backwashed to make a dissimilar resin. In this state, a certain amount of anion exchange resin for desalting is transferred to a separate independent storage tower for regeneration, and before the backwashing process. It is a method of recovering a certain amount of resin corresponding to the volume of the intermediate mediator resin added, that is, remaining inert resin or some anion exchange resin and cation exchange resin.

In order to regenerate the mixed bed ion exchange resin tower resin which has lost the desalting function in the regenerated mixed bed type desalination plant of the tower as described above, the mixed bed resin in the separation column may be backwashed or other similar methods such as cation exchange resin and anion exchange resin. And the intermediate media resin, the cation exchange resin, which has the heaviest specific gravity due to the specific gravity difference, sinks first in the lower part of the separation tower, and an intermediate mediator layer is formed on the cation exchange resin layer. It is formed on the intermediate layer. The cation exchange resin and anion exchange resin separated in this way is transferred to a separate regeneration tower for separation. If the separation tower also functions as a cation exchange resin regeneration tower, the anion exchange resin is regenerated under transfer to the anion exchange resin regeneration tower through a transfer pipe located below the anion exchange resin, i.e., the intermediate medium layer. Then, the intermediate layer is sent to the intermediate medium resin storage tower for reuse. In addition, the cation exchange resin is transferred to the cation exchange resin regeneration tower through the transfer pipe located below the separation tower to be regenerated, and the intermediate layer is sent to the intermediate medium resin storage tower for reuse.

However, the ion exchange resin separation and transfer method is a transfer separation method of a fixed resin piled up from the bottom of the separation tower, and can not effectively prevent the mixing of the resin during transfer of the separated ion exchange resin, effectively separating the ion exchange resin, There was a limitation in conveying and regenerating, and since the generation of recycled waste water is large and the pure water used in regeneration is large, and compressed air consumption is large, the ion exchange resin cannot be separated and regenerated economically. I had it.

After all, the present invention is to solve the above-mentioned problems of the prior art, the object of the present invention is to efficiently and economically transport separation and regeneration of the ion exchange resin of the regeneration multi-phase desalination plant outside the tower, and the amount of generated wastewater And it is possible to reduce the amount of pure water used during regeneration, and to provide a method and apparatus for transport separation regeneration of ion exchange resin that can reduce the consumption of compressed air.

The ion-exchange resin transfer separation regeneration method of the regeneration-type multiphase desalination plant outside the tower according to the present invention, which achieves the above object, is a separation tower and a cation exchange resin regeneration tower of a mixed phase ion exchange resin tower which has lost the desalting function. Transporting to a; Transferring the intermediate medium resin stored in the intermediate medium resin storage tower to the separation column and the cation regeneration tower: the mixed resin and intermediate medium of the separation column and the cation regeneration tower using the circulation water of the circulation water storage vessel Backwashing the resin to separate the anion exchange resin and the cation exchange resin;

In order to transfer the resin separated in the above step to the top of the separation tower and the cation regeneration tower while maintaining the separated state, the resin is backwashed at a flow rate of 20 m / H or more, and the separation resin is transferred to the top of the separation tower and the cation regeneration tower, Circulating backwash water at a flow rate of 5 m / H or more by means of a circulating water circulating water reservoir to circulate by a circulating water circulating pump to keep the separation resin from the bottom of the separation column and the cationic regeneration tower:

Transferring the anion exchange resin to the anion regeneration tower through a resin transfer path at the top of the separation column and the cation regeneration tower;

Transferring the intermediate medium resin to the intermediate medium resin storage tower through the resin transfer path at the top of the separation column and the cationic regeneration tower; And regenerating the cation exchange resin of the separation column and the cation regeneration tower and the anion exchange resin of the anion regeneration tower using a regenerant.

At this time, the scrubbing drainage can be reused in the separation column and the cation regeneration tower and reused during the transfer of the anion exchange resin and the intermediate resin. It is preferable to further include the step of draining the regeneration agent remaining inside by the first washing, and then collecting the washing drainage discharged during the second washing in the circulating water storage container.

In addition, the ion exchange resin transfer separation and regeneration apparatus of the regeneration type multiphase desalination plant of the tower according to the present invention, which achieves the above object, separates the mixed phase resin transferred from the mixed phase ion exchange resin tower and regenerates the cation exchange resin. A separation tower and a cationic regeneration tower, an anion regeneration tower for regenerating anion exchange resin separated and transported from the separation tower and a cationic regeneration tower, and an intermediate for separating the mixed resin in the separation tower and a cationic regeneration tower. An intermediate medium resin storage tower for storing the mediator resin, and a circulating water storage container for circulating the circulating water in the separation column and the cation regeneration tower using a circulating water circulation pump.

At this time, the separation column and the cationic regeneration tower to facilitate the transfer of the anion exchange resin and the intermediate medium resin from the upper end of the separation column and the cation regeneration tower, and to minimize the mixing of the resin during separation and transfer of the resin, It is preferable to comprise so that an upper part may become a conical shape.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the ion exchange resin transport separation regeneration method and apparatus of the out-of-column regenerative mixed bed type desalination plant according to the present invention will be described in more detail.

In the present invention, the resin is separated and transferred through the upper part of the separation column and the cation regeneration tower, and the cation exchange resin, the anion exchange resin, and the intermediate resin are separated and stagnated through the first backwash and the second backwash in the separation tower. After the pressure is applied with water to separate the separated resin layer, the circulating water is introduced from the lower portion at a flow rate of 20 m / H or more to float the separated resin layer to the upper part of the separation tower.

At this time, the inflowing circulating water maintains a flow rate of 5 m / H or more so that the resin layer located at the upper portion does not fall while the circulating water of the circulating water storage container is introduced into the separation column and the cation regeneration tower by using the circulating water circulation pump. As such, the anion exchange resin of the upper resin layer held by the circulating water is first sent to the anion regeneration tower, and the intermediate layer resin of the next layer is sent to the intermediate medium resin storage tower for reuse.

1 to 7 are views sequentially simplifying the ion exchange resin regeneration process using the ion exchange resin transfer separation and regeneration device according to an embodiment of the present invention, in Figures 1 to 7 The connection between the tanks is made by appropriate pipes and electronic equipment, and pumps for transferring various resins and regenerants, compressors for transferring air, and ion exchange resin towers for transferring mixed phase resins from the ion exchange resin tower to the separation tower and the cationic regeneration tower The process and the process of transferring the resin to the resin storage tower after the regeneration of the cation exchange resin and the anion exchange resin are similar to those of the conventional ion exchange resin regeneration process, and are not shown in the drawings.

As shown in FIGS. 1 to 7, the ion-exchange resin transfer separation and regeneration apparatus of the out-of-column regenerative mixed bed type desalination plant according to the present invention is a mixed bed resin transferred from a mixed bed ion exchange resin tower (not shown). Separation column and cation regeneration tower (1) for separating and regenerating cation exchange resin, and anion reconstruction tower (3) for regenerating anion exchange resin separated and transferred from the separation column and cation regeneration tower (1). , The intermediate medium resin storage tower (2) for storing the intermediate medium resin for separating the interphase resin in the separation tower and the cationic regeneration tower (1), and the circulating water in the separation tower and the cationic regeneration tower (1) It includes a circulating water storage container 4 for circulating using a circulating water circulation pump (5).

At this time, the regeneration water introduced through the regeneration water inlet pipe 11 is used as resin transfer water, backwash water, or resin mixed water according to a process, and the compressed air introduced through the compressed air inlet pipe 8 is used for resin transfer and resin. Used for mixing.

As shown, the upper part of the separation tower and the cationic regeneration tower 1 of the present invention is configured in the shape of a cone, bringing an increase in the flow rate in the cone during resin transfer, and can easily transport the resin, The upper part of the cone has a small volume to minimize the mixing of the resin during separation and transport of the resin.

In order to transfer-segregate and regenerate the ion exchange resin of the tower-type regeneration mixed bed type desalination plant according to the present invention using the ion exchange resin regeneration device described above, as shown in FIG. The mixed bed resins 12 and 13 of the common ion exchange resin tower are transferred to the separation tower and the cation exchange resin regeneration tower 1.

Thereafter, as shown in FIG. 1, the intermediate resin 14 stored in the intermediate resin storage tower 2 is transferred to the separation tower and the cation regeneration tower 1 described above, and then the third As shown in the figure, by using the circulating water of the circulating water storage container (4) backwashing the mixed resin (12, 13) and the intermediate resin (14) of the separation column and the cation regeneration tower (1) described above anion The exchange resin 12 and the cation exchange resin 13 are separated.

In this case, water is generally used as a means for separation, and by flowing a flow rate capable of sufficiently floating the anion exchange resin 12 having a light specific gravity above the cation exchange resin 13, thereby forming a lower layer. The phase may be divided into a cation exchange resin 13 and an anion exchange resin 12 forming a high layer. At this time, the backwash water used may use the circulating water of the circulating water storage container (4).

Next, as shown in FIG. 4, while maintaining the resin separated in the above step in a separated state, it is backwashed at a flow rate of 20 m / H or more to transfer to the upper end of the separation column and the cationic regeneration tower 1 described above. The backwash water is circulated at a flow rate of 5 m / H or more in order to transfer the separation resin to the top of the separation tower and the cationic regeneration tower (1), and to keep the separation resin from lowering the separation tower and the cationic regeneration tower (1). The circulation water of the storage container 4 is used and circulated by the circulation water circulation pump 5.

After that, as shown in FIG. 5, the above-described anion exchange resin 12 is transferred to the anion regeneration tower 3 through the resin transfer path at the top of the separation column and the cation regeneration tower 1, As shown in FIG. 6, the intermediate medium resin 14 is transferred to the intermediate medium resin storage tower 2 through the resin transfer path at the top of the separation column and the cationic regeneration tower 1.

Subsequently, as shown in FIG. 7, the regeneration agent is used to regenerate the cation exchange resin 13 of the separation column and the cation regeneration tower 1 and the anion exchange resin 12 of the anion regeneration tower 3. .

At this time, the regenerant of suitable concentration for regenerating the cation exchange resin (13) is supplied through a valve connected to the cation regenerant inlet pipe (6), the regeneration of the anion exchange resin (12) is an anion regenerant inlet pipe (9) Through the valve connected to the regeneration agent by supplying the appropriate concentration.

Meanwhile, after the regeneration of the cation exchange resin 13, the regeneration agent remaining in the cation exchange resin 13 in the separation column and the cation regeneration tower 1 is discharged by the first washing, and then the washing drainage discharged during the second washing is It is collected in the circulating water storage container 4, and this washing and draining water is used for separating the resin and transferring the anion exchange resin 12 and the intermediate medium 14 resin in the separation column and the cation regeneration tower 1.

The cation exchange resin 13 and the anion exchange resin 12 regenerated by the above process is transferred to a resin storage tower (not shown) through the resin transfer pipe 10 to stand by.

The ion exchange resin transfer separation regeneration method and apparatus of the regeneration type mixed bed type desalination plant according to the present invention have the following advantages and effects.

First, the upper part of the separation tower and the cationic regeneration tower (1) is configured in a conical shape can minimize the mixing of the transfer resin of the separated resin, it is possible to easily transfer the separated resin.

Second, since the washing and draining water during the regeneration of the resin can be stored in the circulating water storage container 4 to be used for separation and backwashing of the consumption resin, the transfer of the medium-value media resin 14, and the like, the regeneration waste water can be reduced as well. The amount of pure water used in the process can be greatly reduced.

Third, after the separation of the consumed resin, since the compressed air is not used during the transfer of the anion exchange resin 12 and the transfer of the intermediate medium resin 14, it is possible to reduce the consumption of the compressed air.

As described in detail above, according to the ion exchange resin transfer separation regeneration method and apparatus of the present invention, the ion exchange resin of the tower-type regeneration type mixed bed type desalination plant can be efficiently and economically transferred and regenerated, and the amount of regeneration wastewater generated. And it was confirmed that it is possible to reduce the amount of pure water used during regeneration, and at the same time reduce the consumption of compressed air.

Claims (4)

Transferring the mixed phase resin of the mixed phase ion exchange resin tower having lost the desalting function to a separation tower and a cation exchange resin regeneration tower (1); Transferring the intermediate resin 14 stored in the intermediate resin storage tower 2 to the separation column and the cation regeneration tower 1 described above; By using the circulating water of the circulating water storage container 4, the mixed resins 12 and 13 and the intermediate resin 14 of the above-described separation column and cation regeneration tower 1 are backwashed, and the anion exchange resin 12 and the cation are Separating into an exchange resin (13); In order to transfer the resin separated in the above step to the upper end of the separation tower and the cationic regeneration tower 1 while maintaining the separated state, it is backwashed at a flow rate of 20 m / H or more to separate the separation resin and the cationic regeneration tower 1. In order to transfer the backwashed water at a flow rate of 5 m / H or more to maintain the separation resin from the lower part of the separation column and the cationic regeneration tower (1), the circulating water using the circulating water of the circulating water storage container (4). Circulating by the circulation pump (5); Transferring the anion exchange resin (12) to the anion regeneration tower (3) through a resin transfer path at the top of the separation tower and the cation regeneration tower (1); Transferring the intermediate medium resin 14 to the intermediate medium resin storage tower 2 through the resin transfer path at the top of the separation tower and the cationic regeneration tower 1; And regenerating the cation exchange resin 13 of the separation column and the cation regeneration tower 1 and the anion exchange resin 12 of the anion regeneration tower 3 using a regenerant. Ion exchange resin feed separation regeneration of desalination plant. The method of claim 1, wherein after regeneration of the cation exchange resin 13 and the anion exchange resin 12, the regenerant remaining in the separation column and the cation regeneration tower 1 is discharged by primary washing, and then A method of transporting and regenerating the ion exchange resin of an out-of-column regenerative mixed bed type desalination plant, the method further comprising: collecting the washing drainage discharged during the washing in a circulating water storage unit (4). Separation tower and cation regeneration tower (1) for separating the mixed phase resin transferred from the mixed bed ion exchange resin tower and regenerating the cation exchange resin (13), and separated and transferred from the separation tower and cation regeneration tower (1). Intermediate resin storage for storing an anion regeneration tower (3) for regenerating the anion exchange resin (12), and an intermediate resin (14) for separating the interphase resin in the separation column and the cation regeneration tower (1). A plurality of out-of-the-box regeneration type mixed phase type including a tower (2) and a circulating water storage container (4) for circulating the circulating water in the separation tower and the cation regeneration tower (1) using the circulating water circulation pump (5). Ion-exchange resin feed separation regeneration device of desalination plant. [4] The ion exchange resin transfer separation and regeneration device according to claim 3, wherein the separation tower and the cation regeneration tower (1) are divided so that the upper portion is conical.