JPH0553525B2 - - Google Patents

Description

[Detailed Description of the Invention] [Object of the Invention] (Industrial Application Field) The present invention relates to a filtration device that uses a hollow fiber membrane module as a filtration medium, which efficiently removes the air layer formed in the upper part of the filtration chamber. The present invention relates to a hollow fiber membrane filtration device that can discharge water.

(Prior art) In general, in nuclear power plants, the generation of corrosion products is suppressed and removed as a radiation reduction measure. Filtration equipment is used to separate and remove substances. Conventionally, such filtration devices include filtration devices that use precoated filters such as powdered ion exchange resin, flat membrane filtration filters such as filter paper, filter cloth, and membrane filters, and hollow filters such as sintered metal and ceramic filters. Pipe filters were used, but
In recent years, hollow fiber membrane filtration devices using hollow fiber membrane modules as filter media have become widespread. This hollow fiber membrane is a hollow fiber membrane with an outer diameter of about 0.3 to 3 mm and a large number of fine permeation pores.
It is capable of capturing suspended particles of less than 100 m in diameter, has a large filtration area per unit volume, and has excellent pressure resistance, so it is suitable as a filter material for ultrafiltration and reverse osmosis filtration.
Widely used in electronic industry, medicine and wastewater treatment fields.

FIG. 5 is a sectional view showing an example of this hollow fiber membrane filtration device. This hollow fiber membrane filtration device is divided into a filtration chamber 3 and a processing liquid chamber 4 by a closed container 1 and a tube plate 2, and a plurality of hollow fiber membrane modules 5 are vertically installed in the filtration chamber 3 in multiple stages. It is configured. Each hollow fiber membrane 6 is fixed to a tube plate 2 via a module fixing part 7, and the tube plate 2 is narrowed by outer peripheral flanges 8 and 9 attached to the edges of the body 1A and lid plate 1B of the closed container 1. held and fixed.
The hollow fiber membrane module 5 generally has a module structure in which a large number of fibrous hollow fiber membranes are bundled in a straight line or in a U-shape, and the ends are fixed with a resin or the like, and the part fixed with the resin or the like is the module. This is the fixed part 7. In the hollow fiber membrane filtration apparatus of this example, three hollow fiber membrane modules 5 in which hollow fiber membranes 6 are linearly bundled and their ends are fixed are arranged in series, and the module fixing part 7 is connected to a connecting tool. The membranes are connected together and installed as an integrated hollow fiber membrane module structure.

The waste liquid generated from the nuclear power plant is introduced into the filtration chamber 3 from the feed liquid inlet nozzle 10, and when passing through each hollow fiber membrane 6, foreign substances such as crud are separated and removed, and the waste liquid is filtered. The processing liquid passes through the hollow part of the hollow fiber membrane 6 and flows into the water collecting pipe 11 provided at the center of the bundle of hollow fiber membrane modules 5, and after flowing into the processing liquid chamber 4 via the tube plate 2,
It passes through the processing liquid outlet nozzle 12 and is transferred to the outside of the system.

By the way, an air layer 13 is usually formed above the filtration chamber 3 during the filtration process of the feed liquid in a predetermined manner. This air layer 13 is formed by minute air bubbles in the water, air bubbles attached to the inner surface of piping or the surface of equipment, etc. that gradually accumulate in the upper part due to long-term operation. In this case, a valve downstream of the nozzle of the vent 14 was opened to discharge air along with the feed liquid to the waste treatment system. This vent 14 is also used for backwashing operations to remove crud and the like adhering to the surface of the hollow fiber membrane 6 when the permeation pressure loss increases due to clogging of the hollow fiber membrane 6. In addition, 15 in the figure is a protection tube, 1
6 is a backwash air inlet nozzle, 17 is an air blowing pipe, and 18 is a backflow water outlet nozzle.

(Problem to be Solved by the Invention) However, when the air layer is discharged using the nozzle of the vent 14, the vent 1 in the filtration chamber
The air layer in the clearance between the tip of the pipe 4 and the tube plate 2 is difficult to discharge and tends to remain, and the air layer exists in the upper part of the filtration chamber and the hollow fiber membrane 6 is exposed to air for a long time. Then, there was a problem that the filtration efficiency decreased because the filtration area of the hollow fiber membrane 6 decreased.

In addition, due to the pressure loss during water backwashing in the above-mentioned clearance section, it is not possible to shorten it beyond the specified limit, and the nozzle diameter is also 150A to 300A (165.2 to 318.5
mm), so if the supply liquid such as waste liquid was discharged from the vent 14 for a long time when air was discharged, the amount of waste liquid sent to the waste treatment system would increase, which would increase the load on the waste treatment system. .

The present invention was made to solve such problems, and an object of the present invention is to provide a hollow fiber membrane filtration device that improves filtration efficiency and reduces the load on a waste treatment system.

[Structure of the Invention] (Means for Solving the Problems) The hollow fiber membrane filtration device of the present invention includes a closed container, a processing liquid chamber formed in the upper part, and a filtration chamber formed in the lower part. A hollow fiber membrane filtration device comprising: a tube sheet partitioned into two; a hollow fiber membrane module structure vertically installed from the tube sheet into the filtration; and a vent opening below the tube sheet of the sealed container; The present invention is characterized in that, in addition to the vent, an air vent nozzle is provided which opens at the same level as or above the lower surface of the tube plate and communicates between the inside and outside of the closed container.

Note that the release of the air purge nozzle is controlled by, for example, a detection device that detects the air layer formed in the upper part of the filtration chamber, a control device that suppresses the opening and closing of the air purge nozzle based on the output of this detection device, a timer, and the output of this timer. This can be done using a control device that controls the opening and closing of the air purge nozzle based on the flow rate, a flow meter that measures the amount of liquid to be processed, and a control device that controls the opening and closing of the air purge nozzle based on the output of the flow meter.

In addition, the air vent nozzle has an outer diameter of 10 to 100A.
(17.3~114.3mm), preferably 10A~50A (17.3~
60.5mm) is suitable.

(Function) In the hollow fiber membrane filtration device of the present invention, when air accumulates in the upper part of the filtration chamber during filtration processing and an air layer is formed, the hollow fiber membrane filtration device is provided on the tube plate or the body near the tube plate, and is attached to the bottom surface of the tube plate. Air is exhausted through a small-diameter air vent nozzle with an internal opening on the same or upper side, so no waste liquid is discharged.
Most of the air in the filtration chamber can be exhausted,
This prevents the filtration processing area of the hollow fiber membrane from decreasing due to the air layer, and improves the filtration processing efficiency.

Further, since the diameter of the air vent nozzle is small, even if waste liquid is discharged together with air during air discharge, the amount thereof is small, and the load on the waste treatment system is reduced.

(Example) Examples of the present invention will be described below with reference to the drawings. Note that the same elements and parts as in the conventional example are indicated by the same reference numerals, and the explanation thereof will be omitted.

FIG. 1 is a sectional view of a hollow fiber membrane filtration device according to an embodiment of the present invention. In this hollow fiber membrane filtration device, a closed container 1 is divided into a filtration chamber 3 and a processing liquid chamber 4 by a tube plate, hollow fiber membrane modules 5 are vertically disposed in multiple stages from the tube plate 2, and a filtration chamber 3 is provided. A detector (liquid level system) 20 for detecting an air layer 13 formed in the inner upper part is connected to the filtration chamber 3, and an air vent nozzle 21 is provided in the upper part of the filtration chamber. Liquid level system 20
can detect the water level in the filtration chamber 3 in the range from the upper end to the lower end of the hollow fiber membrane module structure. The lower liquid level gauge seat 23 led out from the filtration chamber 3 below the lower end of the hollow fiber membrane module 5 is connected via a base valve 24.

Next, the air vent nozzle 21 will be explained in detail. FIG. 2 is an enlarged sectional view of the air vent nozzle portion of the hollow fiber membrane filtration device of the example. This air vent nozzle has a diameter of 10A to 50A (173.5 to 60.5 mm), is provided on the tube plate 2, and communicates from the tube plate 2 into the filtration chamber 3. The tube plate around the air introduction part of the air vent nozzle 21 into the filtration chamber 3 has a shaved shape as shown in FIG. There is no problem even if the tube sheet is not shaved.

Using the hollow fiber membrane filtration device configured as described above, overtreatment is performed in the same manner as in conventional devices. That is, the feed liquid such as waste liquid generated from a nuclear power plant is passed from the feed liquid inlet nozzle 10 to the filtration chamber 3.
After being press-fitted into the interior and filtered by the hollow fiber membrane 6, the treatment liquid flows into the treatment liquid chamber 4 and is transferred to the outside via the treatment liquid outlet nozzle 12. In the filtration process, when a certain amount of air layer 13 is formed in the upper part of the filtration chamber 3 and detected by the liquid gauge 20, the air purge nozzle 21 is opened by a control device (not shown) to discharge the air. .

When discharging air, the valve on the downstream side of the piping of the air vent nozzle 21 is opened for a specified period of time while continuing the filtration treatment operation, thereby discharging the air together with the supply liquid to the waste treatment system.

In this hollow fiber membrane filtration device, air is discharged from the small-diameter air vent nozzle 21, so almost the entire amount of the air layer formed in the filtration chamber can be discharged, and it can also be discharged together with the air to the waste treatment system. The amount of waste liquid generated is small. Therefore, it is possible to prevent the filtration area of the hollow membrane from decreasing and the filtration efficiency from decreasing, and to reduce the load on the waste treatment system.

In addition, as a method for determining when to discharge the air layer 13, in addition to the method used in this embodiment in which the opening and closing of the air purge nozzle is controlled using a detection device such as a liquid level gauge and a control device, There is a method in which the formation process is calculated in advance and the time is controlled using a timer and a control device that controls the opening and closing of the nozzle using the output of this timer, and a method that uses a flowmeter to measure the throughput of the supplied liquid and the opening and closing of the air purge nozzle using this flowmeter. Examples include a method of controlling the flow rate using a control device that controls the flow rate.

FIG. 3 is an enlarged sectional view of an air vent nozzle portion of a hollow fiber membrane filtration device according to another embodiment of the present invention. The hollow fiber membrane filtration device of this embodiment has the same structure as the above embodiment except that the air vent nozzle 21 is provided not from the tube plate 2 but in the body 1A of the closed container 1 near the tube plate 2. There is. One end of the air vent nozzle 21 opens in a portion where the upper tube plate inside the filtration chamber is shaved, and the other end passes through the body 1A of the closed container 1 and communicates with the outside. Then, the air layer formed in the upper part of the filtration chamber is discharged in the same manner as in the above embodiment. This embodiment can also provide the same effects as the above embodiments.

Moreover, FIG. 4 is a sectional view of a hollow fiber membrane filtration device of a comparative example. This hollow fiber membrane filtration device is constructed by bundling hollow fiber membrane modules 5 into a U-shape, and is a filtration device that doubles as a vent and an air removal nozzle. In the hollow fiber membrane filtration device of this comparative example, the air vent nozzle 21 is provided so as to pass through the tube plate 2 and the processing liquid chamber 4, penetrate the intermediate body 30 of the closed container 1, and connect to the piping side. In this device, the air vent nozzle 21 also serves as a vent, so the outer diameter is 65A to 200A (76.3 to 216.3mm).
In many cases, the diameter of the hollow fiber membrane is large, and it is difficult to exhaust the entire air layer, so the hollow fiber membrane comes into contact with the air, reducing the filtration area and reducing the filtration efficiency. Since a large amount of waste liquid is generated and sent to the waste treatment system, the load on the waste treatment system tends to increase.

[Effects of the Invention] As described above, the hollow fiber membrane filtration device of the present invention replaces the air layer formed in the upper part of the filtration chamber in the filtration process with a tube plate or a small-diameter tube disposed near the tube plate. Air can be efficiently discharged using the air vent nozzle. Therefore, it is possible to secure a large filtration area of the hollow fiber membrane module and improve the filtration efficiency, thereby extending the life of the hollow fiber membrane module and enabling continuous operation of the device for a long time.

Furthermore, since the amount of waste liquid discharged together with air is small, the load on the waste treatment system is reduced.

[Brief explanation of the drawing]

FIG. 1 is a sectional view of a hollow fiber membrane filtration device according to an embodiment of the present invention, FIG. 2 is an enlarged sectional view of an air vent nozzle portion of a hollow fiber membrane filtration device according to an embodiment of the present invention, and FIG. 3 is a sectional view of a hollow fiber membrane filtration device according to an embodiment of the present invention. An enlarged sectional view of the air vent nozzle part of a hollow fiber membrane filtration device of another example, FIG. 4 is a sectional view of a hollow fiber membrane filtration device of a comparative example, and FIG. 5 is a sectional view of a conventional hollow fiber membrane filtration device. be. 1... Airtight container, 2... Tube plate, 3... Filtration chamber,
4... Processing liquid chamber, 5... Hollow fiber membrane module, 6
...Hollow fiber membrane, 14...Vent, 20...Liquid level gauge, 21...Air vent nozzle.

Claims (1)

[Claims] 1. A sealed container, a tube plate that divides the sealed container into a processing liquid chamber formed in the upper part and a filtration chamber formed in the lower part, and a hollow fiber membrane module that is vertically installed from the tube plate into the filtration chamber. In a hollow fiber membrane filtration device having a structure and a vent opening under the tube plate of the sealed container, the hollow fiber membrane filtration device has an opening on the same level as or above the bottom surface of the tube plate, separate from the vent, and communicating between the inside and outside of the sealed container. A hollow fiber membrane filtration device characterized by being equipped with an air release nozzle.