JP2891820B2 - Regeneration method of ion exchange resin - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates are those concerning the reproduction how the ion exchange resin condensate demineralizer for processing condensate such as thermal power plant or nuclear power plants.

[0002]

2. Description of the Related Art In general, a condensate desalination apparatus for treating condensate in a thermal power plant or a nuclear power plant is composed of a plurality of water towers and a series of regeneration equipment.

[0003] That is, when condensate is treated in a plurality of water towers, when the pressure loss of one of the water towers increases, or the purity of the treated water decreases, or when a constant yield is reached, The used ion exchange resin (mixed resin of cation exchange resin and anion exchange resin) in the water flow tower is transferred to the regeneration facility, and the regenerated mixed resin that has been regenerated and stored in the regeneration facility is passed through the recycle facility. Filling the water tower and restarting the water supply, or switching the standby water tower filled with the regenerated mixed resin that has already been regenerated in the regeneration equipment to the water flow, while transferring the used water transferred to the regeneration equipment It is provided to regenerate the mixed resin and prepare for the next water flow.

There are various types of regeneration equipment used in such a condensate desalination apparatus. For example, after separating a cation exchange resin and an anion exchange resin into upper and lower layers in a single tower, the regeneration treatment is sequentially performed. Or a two-column regeneration system in which the cation exchange resin and the anion exchange resin are separated into separate columns and then regenerated after separation is known and actually applied. .

[0005] In any of these regeneration systems, various proposals have conventionally been made for the purpose of improving the ion removal rate when returning the ion-exchange resin after the regeneration treatment to the water tower and performing the condensate treatment. The present applicant has also proposed, for example, the method of Japanese Patent Publication No. 58-20312 relating to a single-tower regeneration method, and the method of Japanese Utility Model Publication No. 3-53758 relating to a two-tower regeneration method.

[0006]

The method and equipment for the above-mentioned condensate treatment are required to be further improved. Applicants are conducting further research and development.

[0007] In the process, the present inventors have found that the quality of the treated water can be remarkably improved by performing an operation which has never been attempted before.

[0008] The present invention has been made based on such knowledge, and has as its object to provide a regeneration method capable of improving the quality of treated water in a condensate desalination apparatus.

Another object of the present invention is to provide an ion-exchange resin regeneration facility to which the above-mentioned regeneration method can be applied.

[0010]

In order to achieve the above object, the present inventor has completed the invention of a method and an apparatus described in each of the claims.

One of the features of the regeneration method of the present invention is that the anion exchange resin separated above the cation exchange resin layer in one column or the anion exchange resin separated in a separate column from the cation exchange resin. the resin layer, a method of disconnect from the lower part of the layer play effluent to Togai play an anion exchange resin as well as through drugs warmed <br/> alkaline regenerant from the layer of the upper, in the column A liquid layer of a thin regenerant that can always be immersed in the regenerant up to the upper surface of the anion exchange resin without being filled with water is maintained above the anion exchange resin , and
The temperature of water and gas existing above the exchange resin layer in advance.
With the temperature almost the same as that of the alkali regenerant,
The place to do the medicine .

In the above, the liquid layer of the alkali regenerant maintained on the anion exchange resin layer is preferably as thin as possible as long as the condition that the anion exchange resin is always immersed in the regenerant is satisfied. Although not limited, it is generally preferable to set the liquid level in a range of about 20 to 40 cm from the upper surface of the anion exchange resin layer in consideration of the fluctuation of the liquid level.

In the single-column regeneration method, any of a method using only caustic soda as an alkali regenerant and a method using ammonia circulation may be used.

The supply position of the regenerant into the tower is not limited, but it is often preferable to start from the vicinity of the liquid level of the regenerant.

The method of the present invention is not limited to the above-described single-column regeneration method in which an anion exchange resin and a cation exchange resin are regenerated in one column, but also separates these resins into another column to perform the regeneration process. The present invention can be similarly applied to the so-called double column regeneration method, and there is no particular distinction between the single column type and the double column type in the regeneration treatment of the anion exchange resin.

In the single-column or double-column regeneration method described above, the regeneration of the cation exchange resin, which is another resin, is not limited by the regeneration method of the anion exchange resin of the present invention. Can be applied as it is.

When the method of the present invention is carried out on an anion exchange resin in a single-column regenerator, it is preferable to employ some more devised methods in relation to the regeneration of the cation exchange resin. Recommended.

[0018] For example, in the case of performing through drug alkaline regenerant for the anion exchange resin, prior to this, a full level in the water introduced to separate e.g. mixed ion-exchange resin by backwashing separation method Air flows in from the top of the regenerating tower, and water from the drainage means (usually a collector) installed near the lower part of the anion exchange resin layer pushes water slightly above the anion exchange resin layer out of the tower. In this operation, at the same time as water is drained, hot water that is almost equal to the temperature of the alkali regenerant that is heated and used for promoting desorption in the regeneration treatment of the anion exchange resin is generally introduced, and water is discharged. It is preferable that the temperature of the water and the gas part existing above the anion exchange resin layer at the time of the completion of the extraction be set to be substantially the same as the temperature of the alkali regenerant.
This is because, in the regeneration method of the anion exchange resin of the present invention, a gas phase (air) region is formed in the upper part of the regeneration tower, so if there is a temperature change in the tower during the regeneration treatment, this gas phase part Expansion and shrinkage are likely to occur, which is inconvenient for maintaining the liquid level of the alkali regenerant liquid layer, which is to be maintained at a stable height above the anion exchange resin layer. is there.

The anion exchange resin layer separated above the cation exchange resin layer in one tower is subjected to the anion exchange resin regeneration method of the present invention, and then the cation exchange resin layer is acid-regenerated. the in passing drugs to play method for reproducing cation exchange resin, the upper boundary surface for the cation exchange resin is contracted by passing drugs acid regenerant is liable to vary. Therefore, an operation for suppressing the influence of such a fluctuation and maintaining a stable drug passing state of the acid regenerant is required. Such operations, for example, a method of balancing the liquid passing amount of water to the cation-exchange passage dose of the acid regenerant to the resin layer and the top of the anion exchange resin layer is also possible, as a simple method, anion It is recommended to use a method in which the space from the exchange resin layer to the top is filled with water.

In the single-column regeneration method, after the regeneration treatment of the anion exchange resin, a re-separation operation for separating the anion exchange resin and the cation exchange resin up and down again is performed.
Regeneration of the lower cation exchange resin layer is also preferable for further improving the regeneration rate.

The reason why a condensate desalination column using a mixed ion exchange resin obtained by regenerating an anion exchange resin according to the method of the present invention can exhibit excellent performance inconceivable from the conventional regeneration method is not necessarily clear. However, according to the comparison between the method of the present invention and the conventional method, in the conventional method, a small amount of alkali regenerant was brought into the water column together with the anion exchange resin after regeneration for some reason. It is presumed that the method of the present invention greatly reduces the amount of such an alkali regenerant brought into the water tower. As a cause of the alkali regenerant being brought into the water flow tower, in the conventional method, since the regeneration is performed with the regenerator in a full state, the alkali regenerant is likely to adhere and remain on the inner wall of the tower or a member in the tower,
It is considered that the washing is likely to be insufficient.

The regeneration method of the present invention can be carried out using the following ion exchange resin regeneration equipment.

[0023] That is, double column regeneration method, a regenerator anion exchange resin is filled separately from the cation exchange resin, through drugs alkali regenerant against the anion exchange resin layer of regeneration the column and a regenerant passage agent means, as the regenerant passage drug unit, and regenerant supply means for supplying a regenerant from above against the anion exchange resin layer, the position of the upper constant height of the anion exchange resin layer In addition, it can be carried out by a regenerating facility having a liquid level maintaining means for maintaining the liquid level of the regenerant and a means for extracting the regenerated waste liquid from the lower part of the anion exchange resin layer to the outside of the tower. One-to-one regeneration method
Is a one-column regeneration tower for sequentially regenerating an anion exchange resin and a cation exchange resin, and a resin separation for separating the anion exchange resin and the cation exchange resin in the regeneration tower into upper and lower layers in the regeneration tower. means and includes a first regenerant passage agent means Ru passing drugs to <br/> alkaline regenerant against the anion exchange resin layer of the upper layer separated by the regeneration the column, the lower separated by regeneration the column second for passing drug an acid regenerant respect cation exchange resin layer
And a regenerant passage drug unit, as the first regenerant passage drug unit, and regenerant supply means for supplying a regenerant from above to anion-exchange resin layer, the position of the layer of the upper fixed height It can be carried out by a regeneration facility having a liquid level maintaining means for maintaining the liquid level of the regenerant and a means for extracting the regeneration waste liquid from the lower part of the layer to the outside of the tower.

In any of the above facilities, the regenerant supply means (distributor) for supplying the regenerant from above the anion exchange resin layer may be provided near the liquid level of the regenerant maintained at a constant height. preferable.

In the above, as a means for maintaining the liquid level of the alkali regenerant at a substantially constant height, the outlet of the collector pipe for extracting the regenerated waste liquid from the lower part of the anion exchange resin layer to the outside of the column is connected to the vicinity of the liquid level. After opening up to the atmosphere after opening, the level switch LS
_H, provided a valve in conjunction with the level switch in the collector pipe with the LS _L respectively provided, the valve opening on-the LS _H, format the valve is closed in on the LS _L, the liquid level indicating controller LIC A type in which the opening of a control valve provided in the middle of the collector pipe is adjusted can be exemplified, but the present invention is not particularly limited thereto.

[0026]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be further described below with reference to the embodiments shown in the drawings.

Embodiment 1 FIG. 1 shows an embodiment of a single-column ion-exchange resin regeneration facility, which has a regeneration tower 3 and a resin storage tank 8 as main devices.

The details of this facility will be described below according to the operating procedure. First, the used mixed ion exchange resin in the desalting tower 11 is transferred via the resin transfer pipe 10 and filled in the regeneration tower 3. After sufficiently scrubbing with air or the like to discharge the iron oxide or the like to the outside of the regeneration tower 3 by a water stream, backwashing water of an ascending flow flows from a lower portion of the regeneration tower 3 to sufficiently remove both ion exchange resins. By expanding and separating, and then stopping the inflow of the backwash water to settle, the difference in the sedimentation speed of both ion exchange resins is used to form the cation exchange resin layer C in the lower layer and the anion exchange resin layer A in the upper layer. Let it form. Reference numeral 13 denotes a separation surface between the upper and lower layers A and C.

Next, the regeneration of the anion exchange resin in the regeneration tower 3 is performed as follows.

That is, in a state where the ion-exchange resin is separated into the upper and lower layers as described above, air is introduced from the washing water / air pipe 6 through the distributor 7 so that the water filled in the tower is filled. Is drained to the level of the liquid level 14 on which the level switch 15 is installed. At this time, the temperature of the alkaline regenerant (for example, 60
° C.) intends substantially in a row the drain while flowing water at the same temperature from NaOH communication agent pipe 1.

Next, the NaOH solution as alkaline regenerant, and through drug from the upper portion of the upper anion exchange resin layer A via dei string bi Yuta 2 from the NaOH communication agent pipe 1,
On the other hand, in order to prevent the NaOH liquid from entering the lower layer of the cation exchange resin layer C, the support water was supplied in an upward flow from the H ₂ SO ₄ passage pipe 4 while being installed below the anion exchange resin layer A. The regeneration waste liquid and the supporting water are extruded from the collector 5.

As a feature of the regeneration treatment of the anion exchange resin of the present embodiment, the waste liquid pipe 16 from the collector 5 is once raised to the level of the liquid surface 14 and then opened to the atmosphere. To be discharged to Reference numeral 18 indicates this open-to-atmosphere portion. By raising the waste liquid pipe 16 and opening the air to the atmosphere, the liquid level 1 of the NaOH liquid supplied from the distributor 2 is increased.
4 will be kept in the position shown.

Thereafter, the refining agent in the column is washed out while maintaining the liquid level after the completion of the drug delivery, and the inside of the column is filled with water while bleeding the air from the air vent pipe 9, and then washing is performed. The regeneration treatment of the anion exchange resin ends.

Next, for the regeneration of the lower cation exchange resin C, according to a conventional method, the supporting water from above as well as liquid permeability of H ₂ SO ₄ is an acid regenerant from H ₂ SO ₄ copies drug pipe 4 Flush and remove from collector 5. At this time, the valves 19 and 20 of the waste liquid pipe 16 from the collector 5 are switched so that the regenerated waste liquid and the supporting water flow out through the valve 20 without passing through the air opening part.

After passing the chemicals, the regenerant in the column is washed out and washed to complete the regeneration of the cation exchange resin.

The ion-exchange resin having undergone the above-mentioned regeneration treatment of both resins is sent to the resin storage tank 8 via the resin transfer pipe 30. The mixed resin that has been stored in the resin storage tank 8 by performing the previous regeneration process is sent to the desalination tower 11 in advance via the resin transfer pipe 31.

After the regeneration of the anion exchange resin, prior to the regeneration of the cation exchange resin, backwash water is passed through the lower portion of the regeneration tower 3 to separate the anion exchange resin and the cation exchange resin again. In this case, a small amount of the cation exchange resin remaining in the anion exchange resin layer migrates to the cation exchange resin layer side, so that there is an advantage that the regeneration rate is further improved.

The method of regenerating the ion exchange resin performed in the facility of the present embodiment as described above is characterized in that in the operation of the regeneration treatment of the anion exchange resin, the liquid level is kept sufficiently low without filling the column with water. Although it is different from the conventional method, there is an advantage that the effect of significantly reducing the amount of Na ions in the treated water can be obtained as described in the following test examples.

Example 2 FIG. 2 shows an example in which the present invention is applied to a conventional general two-tower type ion-exchange resin regeneration facility, in which separation and cation-exchange resin regeneration and cation-exchange resin regeneration are performed. It comprises an exchange resin regeneration tower 101, a mixed resin receiving tank 102, an anion exchange resin regeneration tower 103, and a resin storage tank 104 provided as needed.

In the equipment shown in FIG. 2, first, the used mixed resin transferred from a water tower (not shown) via a resin transfer pipe 105 is separated and cation exchanged together with the used mixed resin in the mixed resin receiving tank 102. Resin regeneration tower 101
After removing the cladding of iron oxide and the like by scrubbing, forming the cation exchange resin layer C and the anion exchange resin layer A by upward backwashing, backwashing stop settling, and above the separation interface 108 between both ion exchange resins. Is transferred to the anion exchange resin regeneration tower 103 using the resin transfer tube 109, and then the remaining small amount of the anion exchange resin 107a (shown by hatching) is left. And a small amount of the cation exchange resin 106a (shown by oblique lines) below the separation boundary surface 108 are transferred to the mixed resin receiving tank 102 using the resin transfer tube 110.

After the completion of such transfer, in the separation / cation exchange resin regeneration tower 101, the acid regenerant is passed through the acid regenerant delivery pipe 111 and the distributor 112, and then extruded. Washing is performed to regenerate the cation exchange resin 106 by a conventional method. On the other hand, in the anion exchange resin regeneration tower 103, the same anion exchange as in Example 1 is performed using an alkali regenerant drug delivery tube 113, a distributor 114 and the like. A method for regenerating the resin 107 is performed. Except for the difference in the method of regenerating the anion exchange resin, a conventional ordinary two-tower regeneration method is used.

Since each apparatus and operation for the regeneration treatment of the anion exchange resin are the same as those in the first embodiment, the respective apparatuses are illustrated (the numbers of the respective apparatuses for the regeneration treatment of the anion exchange resin are shown in FIG. 1). And the description is omitted.

After the above-described regeneration treatment for each column is completed, the regenerated cation exchange resin 106 in the separation and cation exchange resin regeneration tower 101 is transferred to the resin storage tank 104 using the resin transfer tube 115, and the anion is removed. Exchange resin regeneration tower 1
The regenerated anion exchange resin 107 in 03 is transferred to the resin storage tank 104 using the resin transfer pipe 116, and after the transfer, both ion exchange resins are sufficiently mixed and stored as a regenerated mixed resin.

Test Example 1 Regeneration treatment of an ion exchange resin was performed according to the method of Example 1 using the apparatus of FIG. The main processing conditions are as follows.

Regeneration tower capacity: 10 m ³ Anion exchange resin Type: Amberlite (registered trademark) IRA-900 Amount: 1500 liter Cation exchange resin Type: Amberlite (registered trademark) 200CT Amount: 3000 liter Anion resin regeneration treatment Regenerant (60 ° C., 7% NaOH) was passed through SV7 for 20 minutes. Simultaneously, pure water was passed from the bottom of the tower with SV7. The liquid level was maintained at about 300 mm from the upper surface of the anion exchange resin. After the completion of the passage, NaOH was washed out, the inside of the column was filled with water, and the column was washed with about SV24.

Regeneration treatment of cation exchange resin Regeneration agent (5% H ₂ SO ₄ ) with the inside of the tower being full of water
Was 40 minutes through medicine in SV4. Simultaneously, pure water was passed from the top of the tower with SV7. After the end of the drug delivery, H ₂ SO ₄ was washed out and washed with about SV24.

The ion-exchange resin subjected to the above-mentioned regenerating treatment is transferred to the resin storage tank 8 and stored therein, and then sent to the desalination tower 11 to prepare for the start-up. The Na ion concentration of the water was measured. The results are shown in Table 1 below.

Test Example 2 After the regeneration treatment of the anion exchange resin and prior to the regeneration treatment of the cation exchange resin, pure water was passed through the lower part of the column at LV8 to carry out backwashing and separation again. The same ion exchange resin regeneration treatment as in Example 1 was performed, and the regenerated ion exchange resin was sent to the desalination tower via the resin storage tank 8, and the Na water in the desalination tower treated water at the time of startup and at the time of water sampling thereafter The ion concentration was measured, and the results are shown in Table 1 below.

Test Example 3 For comparison, using the apparatus of FIG. 1, an anionic crotch resin according to a conventional method in which the inside of the tower was filled with water without draining by introducing air prior to the regeneration treatment of the anion exchange resin. Except that the regeneration process was performed, the same ion exchange resin regeneration process as in Test Example 1 was performed, and the regenerated ion exchange resin was sent to the desalination tower via the resin storage tank 8, and collected at the time of startup and thereafter. The Na ion concentration of the deionized tower treated water in water was measured, and the results are shown in Table 1 below.

[0050]

[Table 1]

As is clear from the results in Table 1,
It is confirmed that the Na ion concentration of the water treated in the desalination tower is in an extremely excellent regenerating state when the regenerating treatment is performed by the method of the present invention, as compared with the conventional method.

[0052]

According to the present invention, when regenerating the ion exchange resin, particularly the anion exchange resin, used in the condensate desalination apparatus, a thin regenerant is added to the upper part of the anion exchange resin layer without being filled with water. By passing the alkali regenerant through while forming a liquid layer, there is an effect that the quality of treated water can be significantly improved.

The method of the present invention has a feature that, although the effect obtained is extremely large, the operation itself can be very easily changed even in comparison with the conventional reproducing method. There is an excellent effect in terms of implementation that a change in a conventional design standard can be easily realized.

The present invention also has an effect that a facility for regenerating an ion exchange resin to which the above-mentioned regenerating method can be applied can be easily provided. Furthermore, for anion exchange resin,
Exchange tree in the case of passing alkaline regenerant
In the operation of extruding water slightly above the oil layer out of the tower,
At the same time as draining water, warm the alkaline regenerant to be used.
At the end of drainage
Temperature of water and gaseous parts existing above the anion exchange resin layer
Temperature should be about the same as the temperature of the alkaline regenerant.
And the gas phase (air) region formed in the upper part of the regeneration tower
Because there is no temperature change, this gas phase expands and contracts.
And the liquid level above the alkali regenerant liquid layer is stable
Height and minimizes the effects of unstable liquid levels.
There is an effect that can be reduced.

[Brief description of the drawings]

FIG. 1 is a diagram showing an example of a configuration outline in a case where the present invention is applied to a single-column ion-exchange resin regeneration facility,

FIG. 2 is a diagram showing an example of a configuration outline in a case where the present invention is applied to a two-tower ion exchange resin regeneration facility.

[Explanation of symbols]

1 ... NaOH communication agent pipe, 2 ... distributor, 3 ... regenerator, 4 ... H ₂ SO ₄ copies drug pipe, 5
... collector, 6 ... cleaning water / air supply piping, 7
... Distributor, 8 ... Resin storage tank, 9 ...
・ Air vent piping, 11 ・ ・ ・ desalting tower, 14 ・ ・ ・ liquid level,
15: Level switch, 18: Open to atmosphere, 1
9, 20,... Valves.

Continuation of front page (58) Field surveyed (Int.Cl. ⁶ , DB name) B01J 49/00 C02F 1/42

Claims (3)

(57) [Claims] Claims: 1. An anion exchange resin separated above a cation exchange resin layer in one column, or an anion exchange resin layer separated into a different column from the cation exchange resin,
A method of disconnect from the lower part of the layer play effluent to Togai play an anion exchange resin while passing medicine from the layer of the upper warmed alkaline regenerant, without the tower and filled with water, the anion exchange resin A liquid layer of a thin regenerant that can be constantly immersed in the regenerant to the upper surface of the anion exchange resin is maintained above the anion exchange resin layer, and water existing above the anion exchange resin layer is maintained.
And the temperature of the gaseous part in advance
A method for regenerating an ion-exchange resin , wherein the above-mentioned drug passing is performed in the same state . Wherein removing the regeneration effluent from the bottom of the layer while passing drug alkaline regenerant from above to the anion exchange resin layer is separated at the top of the cation exchange resin layer in one column anion exchange according to claim 1 after regeneration method of the resin, without or to re-separation operation performed to separate up and down an anion exchange resin and a cation exchange resin again, passing agents said acid regenerant to the cation exchange resin layer separated at the bottom reproduction method of ion exchange resin, wherein a line of Ukoto regeneration of cation exchange resins Te. 3. The method of claim 2, through drugs acid regenerant to the cation exchange resin layer, reproduction method of ion exchange resin and performing in the water full level from the anion exchange resin layer to the top.