JP2889302B2 - Raw water treatment method using reverse osmosis membrane module - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial Application Field> The present invention relates to a method for treating raw water using a reverse osmosis membrane module.

<Prior Art> When raw water is treated with a reverse osmosis membrane module to obtain pure water, it is necessary to inject an oxidizing agent such as sodium hypochlorite into the raw water for disinfection and sterilization.

<Problem to be Solved> By the way, tap water is usually used as the raw water.
However, tap water contains heavy metals such as iron and manganese, and the deterioration of the reverse osmosis membrane (particularly, a polyamide-based composite membrane) is captured due to the coexistence of iron and manganese and the above-mentioned oxidizing agent. Is advanced. That is, clogging of the porous layer, which is the support of the semipermeable membrane, and deterioration of the semipermeable membrane reduce the amount of permeated water, and inevitably lowers the TUS (total dissolved solids) of the permeated liquid. For this reason, it has been proposed to inject a reducing agent immediately before the reverse osmosis membrane module to neutralize the oxidizing agent, but in this case, microorganisms are generated in the module, and The membrane is clogged and a decrease in the amount of permeated water is inevitable.

An object of the present invention is to treat a raw water containing a heavy metal such as iron and manganese by a reverse osmosis membrane module under the pouring of the oxidizing agent. It is to propose a method capable of preventing clogging of a reverse osmosis membrane caused by occurrence.

<Means for Solving the Problems> A method for treating raw water using a reverse osmosis membrane module according to the first invention is a method for treating raw water containing heavy metals by reverse osmosis membrane mothur under sterilization by injecting an oxidizing agent. A microfiltration membrane module or an ultrafiltration membrane module is installed in front of the osmosis membrane module, the raw water is supplied to the front module, and the permeated water is treated by the reverse osmosis membrane module. An oxidizing agent is injected, and the injection is performed so that the concentration of the oxidizing agent in the permeated water can be sterilized. The method for treating raw water by the reverse osmosis membrane module according to the second invention includes the steps of: The injection is also performed between the front module and the reverse osmosis membrane module.

<Description of Example> Hereinafter, an example of the present invention will be described with reference to the drawings.

FIG. 1 shows a membrane separation system used in one embodiment of the first invention.

In FIG. 1, reference numeral 1 denotes a raw water tank, which contains heavy metals such as iron and manganese. Reference numeral 2 denotes a reverse osmosis membrane module, which uses a composite membrane in which a semi-permeable membrane is provided on the surface of a porous support membrane, and includes a spiral type, a hollow fiber type, a tubular type, and a plate type as a module type. Any one may be used. Reference numeral 21 denotes a stock solution chamber of the reverse osmosis membrane module 2, 22 denotes a permeate chamber, 23 denotes a permeate outlet pipe, 24 denotes a pressure regulating valve, and 25 denotes a return pipe. 3
Is a microfiltration membrane module or an ultrafiltration membrane module as a front module, and a reverse osmosis membrane module 2
It is installed in front of. The membrane of the front module 3 has sufficient durability against an oxidizing agent described later.
A polyolefin, polysulfone, fluororesin, or the like is used, and any of a spiral type, a hollow fiber membrane type, a tubular type, and a plate type can be used. Reference numeral 31 denotes a stock solution chamber of a front module (microfiltration membrane module or ultrafiltration membrane module), 32 denotes a permeation chamber, 33 denotes a pressure regulating valve, and a permeate chamber 32 denotes a stock solution chamber 21 of the reverse osmosis membrane module 2. And a communication pipe 4. 5 is a liquid feed pump. Reference numeral 6 denotes an oxidizing agent injecting machine, which can use, for example, a metering pump, and is connected to the vicinity of the outlet of the raw water tank 1. As the oxidizing agent, sodium hypochlorite, hydrogen peroxide and the like are usually used. 7 is an oxidant detection sensor.

In order to treat the raw water, that is, raw water containing heavy metals such as iron and manganese, according to the first invention, the liquid feed pump 5 is driven, the pressure regulating valves 33 and 24 are adjusted, and the front module (microfiltration membrane) is operated. Module or ultrafiltration membrane module) 3 and the inter-actual pressure difference of the reverse osmosis membrane module 2 at predetermined pressures (normally, the former is 2 to 4 kg).
f / cm ² , and the latter is set to 10 to 12 kgf / cm ² ). Under such pressure conditions, the raw water in the raw water tank 1 is supplied to the module by the pump 5 and the oxidant is injected into the supplied raw water by the operation of the oxidant injector 6. In this case, the oxidizing agent detector 7 detects the oxidizing agent concentration in the permeated liquid of the front module 3, that is, the oxidizing agent concentration in the stock solution chamber 21 of the reverse osmosis membrane module 2 so that the oxidizing agent is injected into the oxidizing agent injector. 6 is controlled to adjust the oxidant injection amount.

The raw water supplied to the front module 3 by the pump 5 is subjected to permeation processing under the above-described predetermined inter-differential pressure, and the remaining non-permeated raw water is returned to the raw water tank 1, and a part of the raw water permeates the membrane of the module 3. At this time, since heavy metal particles such as iron and manganese can be removed by the membrane of the module 3, even if the oxidizing agent is contained in the liquid in the stock solution chamber 21 of the reverse osmosis membrane module 2, The coexistence of a heavy metal and an oxidizing agent can be prevented, and clogging or deterioration of a reverse osmosis membrane (composite membrane of a semipermeable membrane and a porous support membrane), which cannot be avoided under the coexistence, can be prevented. Also, since the liquid in the stock solution chamber 21 of the reverse osmosis membrane module 2 contains an oxidizing agent at a concentration required for sterilization, the formation of microorganisms in the stock solution 21 of the reverse osmosis membrane module 2 can be eliminated. Also, clogging of the reverse osmosis membrane due to microbial slime can be prevented. Therefore, according to the first invention, a decrease in the amount of permeated water (due to clogging) and an increase in TDS (due to gland deterioration) can be prevented, and the initial permeated water amount and permeated water quality can be favorably maintained. This is clear from the following experimental examples.

Example The front module 3 has an operating pressure of 2 kg f / cm ² and a temperature of 25 kg / cm ² .
An ultrafiltration membrane spiral module with a permeated water flow rate of 10 m ³ / m ² at 10 ° C. is used. The reverse osmosis membrane module 2 has an operation pressure of 10 kg f / cm ² and a rejection rate at a temperature of 25 ° C. A polyamide-based spiral module having a water permeability of 1.0 m ³ / m ² · day at 95% was used. Raw water contains TDS110ppm, PH
7.0, F14, and tap water having an iron concentration of 0.1 ppm, and this tap water is supplied by the pump 5 at a pressure of 15 kgf / cm ² , and the transmembrane pressure of the ultrafiltration membrane module 3 is set to 3 kgf / cm ² , Adjusting valve 33 so that the transmembrane pressure of osmosis membrane module 2 is 12 kg f / cm ²
And 24 were adjusted (total recovery was 75%). Also,
As an oxidizing agent, sodium hypochlorite is injected by the volume injection pump 6 so that the free chlorine concentration in the raw water is 0.5 ppm, and the free chlorine concentration in the raw solution chamber 21 of the reverse osmosis membrane module 2 is reduced to 0.3. ppm was set.

After operating under these conditions for one year, the TDS of the permeated water of the reverse osmosis membrane module 2 remained almost at the initial value and was 12 ppm.
The decrease in the permeated water amount with respect to the initial value was only 5%.

On the other hand, without using the above ultrafiltration membrane module, using only the reverse osmosis membrane module and operating under the same conditions as in the above experimental example, TDS was performed 6 months after the start of operation. Increased by a factor of three, and the permeate volume was 2
Dropped to 0%. This difference in permeation performance is due to the reaction of heavy metal ions with the oxidant on the raw water flooding side of the front microfiltration membrane module or ultrafiltration membrane module, which produces colloids, which are removed by the front module to remove heavy metal. It is presumed that the ions were blocked by the front module, and the performance deterioration of the reverse osmosis membrane module due to heavy metal ions was suppressed.

FIG. 2 shows a membrane separation system used in one embodiment of the second invention.

In FIG. 2, 1 is a raw water tank, 51 is a pump,
3 is a microfiltration membrane module or an ultrafiltration membrane module as a front module, 33 is a pressure regulating valve, 2 is a reverse osmosis membrane module, 24 is a pressure regulating valve, and 7 is an oxidant detection sensor. I have. 8 is the intermediate tank,
52 is a liquid feeding pump, 61 is an oxidizing agent injector provided on the suction side of the liquid feeding pump, for example, a metering injection pump, 62 is an oxidizing agent injector provided in front of a microfiltration membrane module or an ultrafiltration membrane module. Each is shown. To treat the raw water according to the second invention, the pump 51 is driven to supply the raw water in the raw water tank 1 to the front module 3, and the pressure regulating valve 33 is adjusted to adjust the raw water pressure in the front module 3 to a predetermined operating pressure. , The permeated water is temporarily stored in the intermediate tank 8, and the non-permeated raw water is returned to the raw water tank 1. When the raw water permeates the membrane of the front module 3, heavy metal particles such as iron and manganese in the raw water are removed. Therefore, the liquid stored in the intermediate tank 8 does not contain heavy metals. The liquid in the intermediate tank 8 is supplied to the reverse osmosis membrane module 2 by the pump 52 while injecting an oxidant.
And the permeated water is taken out by the take-out pipe 23, and the non-permeated liquid is sent back to the raw water tank 1.

In the case of the second invention, since the inside of the stock solution chamber 21 of the reverse osmosis membrane module 2 can be sterilized by the oxidizing agent, clogging of the reverse osmosis membrane by the microorganism slime can be prevented, and the water to be treated does not contain heavy metals. Therefore, clogging and deterioration of the reverse osmosis membrane, which is inevitable in the presence of the heavy metal and the oxidizing agent, can be avoided. Therefore, the initial TDS and the initial water permeability can be well maintained.

<Effects of the Invention> According to the method for treating raw water by the reverse osmosis membrane module according to the present invention, the liquid to be treated in the stock solution chamber of the reverse osmosis membrane module can be sterilized with an oxidizing agent in a state where heavy metals are eliminated. Reverse osmosis membrane clogging due to oxidizing agents and heavy metals can be prevented, which can prevent deterioration and clogging of the reverse osmosis membrane, which can not be avoided. Can be obtained at a high flow rate.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram showing a membrane separation system used in the first invention, and FIG. 2 is an explanatory diagram showing a membrane separation system used in the second invention. 2 ... reverse osmosis membrane module, 3 ... front module, 6
... Oxidant injector, 7.

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁶ Identification code FI C02F 1/50 520 C02F 1/50 520B 531 531P 540 540B 550 550H 560 560E 1/64 1/64 Z 1/72 1/72 Z (58) Investigated fields (Int.Cl. ⁶ , DB name) C02F 1/44 C02F 1/50 510-560 C02F 1/72 C02F 1/64 B01D 61/58 B01D 65/02 500

Claims (2)

(57) [Claims] In a method for treating raw water containing a heavy metal by a reverse osmosis membrane module under sterilization by injecting an oxidizing agent, a microfiltration membrane module or an ultrafiltration membrane module is installed in front of the reverse osmosis membrane module. Supplying the raw water to the front module, treating the permeated water with a reverse osmosis membrane module, and injecting an oxidant on the raw water supply side of the front module, and furthermore, injecting the oxidant concentration in the permeated water by the injection. A method for treating raw water using a reverse osmosis membrane module, wherein the raw water has a sterilizable concentration. 2. A method of treating raw water containing a heavy metal with a reverse osmosis membrane module under sterilization by injecting an oxidizing agent, wherein a microfiltration membrane module or an ultrafiltration membrane module is provided in front of the reverse osmosis membrane module. Supplying the raw water to the front module, treating the permeated water with a reverse osmosis membrane module, and injecting an oxidizing agent between the raw water supply side of the front module and the front module and the reverse osmosis membrane module. A method of treating raw water using a reverse osmosis membrane module.