JPH0743365B2 - Water treatment equipment performance diagnostic equipment - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an ion exchange type water treatment device used in a condensate purification system of a thermal power plant such as nuclear power generation, and particularly to grasping and regenerating treated water quality. Or suitable for grasping the replacement time,
The present invention relates to a water treatment device performance diagnosis device.

[Conventional technology]

Conventionally, as a method of measuring the treatment capacity of a water treatment device using an ion exchange resin, which has been generalized as an ion exchange medium, a column having a resin packing height simulating an actual machine is continuously subjected to an ion load of an appropriate concentration. The method has been adopted in which the treatment capacity is determined from the time until the treated water quality deteriorates and the accumulated ionic load until then, by monitoring the outlet water quality with conductivity. However, there is no known example of estimating the total processing capacity from the performance per unit amount.

[Problems to be Solved by the Invention] The above-mentioned conventional technique does not consider performance evaluation such as transient change, that is, when the ion load of the actual machine changes in a relatively short time, such as capable of coping with a change in concentration. Therefore, there was a problem that the properties of outlet water could not be predicted when the processing capacity was used up. In the conventional technology, since the measure to regenerate with a sufficient margin against the design load was taken, there was no need for actual operation to grasp the transient performance in particular, but it is more than necessary. Since the recycling is repeated, the burden on the economic side is large, such as the waste disposal cost, the recycling chemical purchase cost, and the labor cost for the recycling operation.

An object of the present invention is to improve the performance evaluation of a water treatment device by providing a performance diagnosis device for a water treatment device, which makes it possible to determine whether to regenerate or replace the ion exchange medium at an appropriate time. , To reduce the operating cost.

[Means for Solving the Problems]

In order to achieve the above object, the present invention is a performance diagnostic apparatus for a mixed-bed type water treatment apparatus using an ion exchange resin as an ion exchange medium, wherein a cation exchange resin and an anion exchange resin are used as samples from the ion exchange medium. And sampled separately, and based on the difference in ion concentration between the inlet and the outlet, the ion-exchange capacity per unit thickness of these two types of samples of the collected cation-exchange resin and anion-exchange resin, respectively. And an automatic analysis means for analyzing the ion exchange capacity of the ion exchange medium to analyze the water treatment performance of the entire amount of the ion exchange medium used in an actual machine based on the measurement data. It is characterized by having done.

Further, the automatic analysis means, based on the ion concentration change of the sample by passing water containing ions of an appropriate concentration in the range of sodium chloride concentration 1ppm ~ 1000ppm, the ion exchange capacity of the ion exchange medium It is something to measure. Further, the automatic analysis means is capable of arbitrarily setting and holding the temperature of the test sodium chloride solution and arbitrarily setting the flow rate of the solution.

Further, the data processing means obtains the temperature dependency and the water flow rate dependency of the performance per fixed amount of the ion exchange resin from the measurement data by the automatic analysis means, and based on the temperature dependency and the water flow rate dependency. By estimating the performance of the entire water treatment device under the usage conditions of the water treatment device, the quality of treated water and the operable time of the water treatment device are predicted. Further, the data processing means predicts treated water quality and operable time with respect to an increase in ion load when the ion load of the water treatment device changes in a relatively short time.

[Action]

According to the above configuration, by separately collecting the cation exchange resin and the anion exchange resin, the performance under each condition such as temperature dependency per unit thickness of each resin having different performance, flow velocity dependency, etc. can be measured. Therefore, it is possible to evaluate the performance when the actual use conditions change, and it is possible to diagnose the water treatment performance of the ion exchange medium in use in a short time.

Also, by applying an ionic load with sodium chloride, it is possible to automatically analyze the ion exchange capacity from changes in conductivity or changes in ion concentration.
Since the flow rate can be set arbitrarily, analysis can be performed very easily. By adding the data of actual usage conditions to this, it is possible to predict the treated water quality and operational time in response to the rapid change in the ion concentration, especially when the ion load of the actual device changes in a relatively short time. The regeneration or exchange frequency of the ion exchange medium in use can be optimized. Further, it is not necessary to carry out a long-term test as conventionally performed, and moreover, the treatment performance of the water treatment device under any condition and the continuous operation time can be promptly obtained.

〔Example〕

An embodiment of the present invention will be described below with reference to FIG. This device includes a sample liquid container 1, a connection pipe 2, a liquid feed pump 3, a flow rate adjusting valve 4, a flow meter 5, a conductivity meter thermometer 6, a sample ion exchange medium container 7, a data processing device 8, and external data. It comprises an input device 9.

Put 1 to 1000ppm sodium chloride solution in the sample solution container 1, and adjust the flow rate by the flow rate adjusting valve 4 and the flow meter 5 by the solution sending pump 3 through the connecting pipe 2 while the sample solution in the sample ion exchange medium container 7. To send.

The ion exchange medium to be measured is placed in the sample ion exchange medium container 7, and the height of the ion exchange medium layer at that time is set as the unit treatment height of the sample ion exchange medium. The conductivity and temperature of the inlet and the outlet of 7 are measured by the conductivity meter thermometer 6, and the data is input to the data processing device 7 to determine the ion exchange capacity of the sample ion exchange medium at any temperature and flow rate. By measuring and inputting other necessary data to the external data input / output device 9, the treated water quality of the water treatment device of an arbitrary scale is calculated.

Here, the operation principle of automatic analysis and data processing concerning ion removal of the ion exchange medium according to the present embodiment will be described in detail.

Desalination rate α per unit processing height of ion exchange medium If this is defined as the desalination rate per the number of processing stages, the ion concentration at the outlet of the ion exchange medium layer can be estimated by the following equation.

C = Co · (1-α) ^Z (1) where C: ion exchange medium layer outlet concentration (unit arbitrary) Co: ion exchange medium layer inlet concentration (unit arbitrary) Therefore, by combining a device that collects a part of the ion-exchange medium and obtains the desalination rate per unit treatment height with a device that processes this data, it is possible to grasp the treated water quality under arbitrary load conditions. Become.

Further, the residual ion exchange amount of the ion exchange medium required for the calculation of the treatable time can be obtained by the following formula based on the water flow amount until reaching the above Co and C = Co and the average desalination rate during that period.

Rh = Co ·· f / V (2) However, Rh: Ion exchange medium residual ion exchange capacity.

: C = Co average desalination rate until reaching Co.

f: Integrated water flow until C = Co is reached.

V: amount of sample ion exchange medium.

The residual ion exchange amount and C in the equation (1) are defined as the required treated water quality under the arbitrary condition at the inlet of the water treatment device, and the difference between the required treated stage number and the actual treated stage number is used to determine the dynamics under the condition. A typical ion exchange capacity (usually called the once-through ion exchange capacity) is determined.

From this once-through ion exchange capacity and the inlet water quality condition that is the calculation condition, the operable time of the water treatment device under that condition can be calculated.

The desalination rate per unit treatment height of the ion exchange medium can be determined by the following equation from the rate of change in the target ion concentration at the inlet / outlet of the sample ion exchange medium layer from its rate of change in conductivity.

However, S: Ion exchange medium layer outlet conductivity (μS / cm) So: Ion exchange medium layer inlet conductivity (μS / cm) St: Ion exchange medium When the sample is anion exchange medium, loaded anion Theoretical conductivity when all are replaced by OH ^- ions. When it is a cation exchange medium, the theoretical conductivity when it is replaced by H ⁺ ions.

Since the above α is determined by the ion exchange rate of the ion exchange medium, it is influenced by the water flow velocity and temperature of the sample solution loaded on the ion exchange medium sample, and therefore it is necessary to measure it according to the actual device. But, approximately, the second
Experimentally obtained data on the flow rate dependence of the desalination ratio of the ion exchange medium, as shown in FIGS. 4 and 5, and FIGS.
It is possible to obtain a value at an arbitrary water flow velocity and temperature by correcting the temperature dependence data as shown in the figure.

In the formula (3), St is calculated by the following ion exchange reaction.
Since the neutral salt in the test solution changes to an acid or an alkali, a cation or an anion that is a constituent of the neutral salt,
It becomes higher than the inlet conductivity due to the difference in equivalent conductivity of H ⁺ ion and OH ⁻ ion. Similarly, S in the formula (2) is a result of a part thereof being changed to an acid or an alkali and becoming higher than the inlet conductivity.

(Yin reaction when the ion exchange ^{medium) R-OH - + Na +} Cl - → R-Cl - + Na + OH - R-OH -: OH - anion exchange medium having an ion.

(Reaction in the case of cation-exchange ^{medium) R-H + + Na +} Cl - → R-Na + + H + Cl - R-H +: H + cation-exchange medium with an ion.

That is, since St in the equation (3) is equal to the limit value of S, the ratio of S-So and St-So is the reaction efficiency of the ion exchange medium sample, and is equal to the desalination rate value described above. Become.

The value of the static exchange capacity of this ion exchange medium is S
= It can be calculated from the amount of load until reaching So.

From the values obtained above, the operable time of the water treatment device under each inlet water quality condition can be obtained by the following method.

From the above equation (1), C = Co (1-α) ^Z ...... (1) C / Co = (1-α) ^Z ...... (4) where C is the required treated water quality of the water treatment device ( If given as a (concentration) value, the required number of processing steps is Z = ln (C / Co) / ln (1-α) (5) from equation (4).

Therefore, if the total number of treatment stages given as the design condition of the water treatment device is H, HZ is a margin amount in the inlet water quality condition. When all the exchange capacity for this margin is consumed, the outlet water quality of this water treatment device reaches the required treated water quality. The capacity of this margin is equal to the value of the static exchange capacity of the ion exchange medium. If this value is Q, Rh: static exchange capacity of ion exchange medium V: amount of ion exchange medium of water treatment equipment.

Therefore, the continuous operating time T of the water treatment device can be calculated from the capacity of Q, the water treatment device inlet concentration Co and the treated water amount (design value) f per unit time by the following formula.

T = Q / Co · f (7) In the analysis by the above equations (4) to (7), by repeating Co in an arbitrary range, the continuous operating time of the water treatment device for each inlet water quality condition can be determined. You can ask.

When this is applied to a condensate demineralizer (hereinafter referred to as CD), which is an important water treatment device of a boiling water nuclear plant (hereinafter referred to as BWR), Co is considered to be CD inlet water quality and C is considered to be outlet water quality. In BWR operation, it is necessary to keep the water quality of the reactor water within the standard value, but the water quality of the reactor water is determined by the operating state of the plant and the value of C above. Therefore,
CD outlet water quality C required to keep the reactor water quality at the standard value
Is calculated by the following formula.

However, C _R : Reactor water quality standard F _C : Reactor coolant purification system flow rate F _f : Reactor feed water flow rate DF: Reactor coolant purification system removal factor In case of BWR, keep CD outlet water quality below C Is an operable condition in terms of water quality, C can be calculated by Eq. (8) and analysis of Eqs. (4) to (7) can be performed to determine the continuous operation time of the BWR plant under arbitrary conditions. You can ask.

As described above, according to the present embodiment, unlike the conventional practice, a long-time test is not required, and further, the treatment performance and the continuous operation time of the water treatment device under arbitrary conditions can be quickly obtained. There is.

〔The invention's effect〕

According to the present invention, it is possible to predict the operating performance of a water treatment device under all operating conditions that could not be easily obtained by the conventional method in a short time. Since the frequency of regeneration or replacement of the existing ion exchange medium can be optimized, the operating cost of the water treatment device can be minimized, and the amount of secondary waste generated is also minimized. .

[Brief description of drawings]

FIG. 1 is a block diagram of one embodiment of the present invention, FIGS. 2 and 3 are data of flow rate dependence of desalination rate of an ion exchange medium used in data analysis obtained experimentally, FIG. 4 and FIG. 5 shows an example of measurement of the temperature dependence data. 1 ... Test liquid container with a temperature adjustment function that can be set to any temperature. 6 ... Conductivity meter and thermometer provided to measure the performance of the ion exchange medium sample. 7 ... Ion exchange medium sample container. 8 ... A data processing device having a data processing function. 9 ... External data input / output device for inputting / outputting data.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Katsumi Otsuka 3-1-1, Saiwaicho, Hitachi, Ibaraki Hitachi Ltd. Hitachi factory (72) Inventor Fumio Mizuba 3 Bentencho, Hitachi, Ibaraki No. 10-2 within Hitachi Kyowa Industry Co., Ltd. (72) Inventor Atsushi Kinase 3-10-2 Bentencho, Hitachi City, Ibaraki Prefecture Within Hitachi Kyowa Industry Co., Ltd.

Claims (5)

[Claims] 1. A performance diagnostic device for a mixed-bed type water treatment device using an ion exchange resin as an ion exchange medium, wherein a cation exchange resin and an anion exchange resin are separately sampled from the ion exchange medium, For each of the collected cation exchange resin and anion exchange resin samples, these 2
In the total amount of the ion exchange medium used in the actual machine based on the automatic analysis means for analyzing the ion exchange ability per unit thickness of the samples of various types to measure the ion exchange ability of the ion exchange medium. A performance diagnostic device for a water treatment device, comprising: a data processing means for analyzing water treatment performance. 2. The performance diagnosing device according to claim 1, wherein the automatic analyzing means has a sodium chloride concentration of 1 ppm to 1000 ppm.
A performance diagnostic device for a water treatment device, which measures the ion exchange capacity of the ion exchange medium based on a change in the ion concentration of the sample caused by passing water containing water having an appropriate concentration of ions in the ppm range. 3. The performance diagnosing device according to claim 1 or 2, wherein the automatic analysis means is capable of arbitrarily setting and holding the temperature of the test sodium chloride solution and setting the flow rate of the solution. Performance diagnostic device for water treatment equipment. 4. The performance diagnosing device according to claim 1, wherein the data processing means uses the data measured by the automatic analysis means to determine the temperature dependence of the performance of the ion exchange resin per fixed amount. And the flow velocity dependence of the water treatment device, and based on the temperature dependence and the flow velocity dependence of the water treatment device, the performance of the entire device under the usage conditions of the water treatment device is estimated to obtain the treated water quality and operation of the water treatment device. A performance diagnostic device for water treatment equipment that predicts the available time. 5. The performance diagnosing device according to claim 4, wherein the data processing means predicts treated water quality and operable time with respect to an increase in ion load when the ion load of the water treatment device changes in a relatively short time. A performance diagnostic device for water treatment equipment.