JP3675561B2 - Water treatment equipment - Google Patents

Description

標記試験の結果を、以下の表１に示す。
【００２８】
【表１】

【００２９】
上記の試験結果によると、実施例１では、比較例１に比べて高い濃縮倍率で安定して本発明装置の運転を行うことができた。これに対して、比較例１では、濃縮倍率も低く、かつ短期間に膜差圧が増大し、運転停止の止むなきに至った。
【００３０】
【発明の効果】
本発明の水処理装置によれば、膜モジュールの膜密度を４００ｍ² ／ｍ³ 以上とすることにより、膜面付近での微細コロイドの高濃度領域を形成することがなく、長期間安定的に運転でき、かつ濃縮効率、濾過水の回収性に極めて優れた濾過を行うことができる。
【図面の簡単な説明】
【図１】図１は、本発明の水処理装置の一例を示す模式図である。
【符号の説明】
１…濃縮装置
２…導入部
３…膜モジュール
４…沈殿部
５…散気管
６…邪魔板[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a water treatment apparatus that enables filtration with a high recovery rate while preventing accumulation of suspended substances on the membrane surface as much as possible when performing water purification treatment and wastewater treatment by membrane filtration.
[0002]
[Prior art]
Conventionally, in a membrane separation water purification process for producing tap water from river water or the like, concentration in the membrane filtration tank is suppressed by discharging about 10% of raw water out of the system as waste water. For the same reason, in the membrane separation wastewater treatment process for concentrating the wastewater, about 10% of the wastewater was discharged out of the system as concentrated water. As a means for suppressing the concentration in the membrane filtration tank, a technique for preventing the accumulation of suspended substances by constantly applying a shearing force to the membrane surface like a rotating flat membrane is known.
[0003]
[Problems to be solved by the invention]
However, in water treatment devices such as a water purification device and a wastewater treatment device by membrane filtration, when filtration through the membrane proceeds, the suspended matter in the membrane filtration tank is concentrated and adheres to the membrane surface, so the filtration flow rate decreases. There was a problem.
[0004]
Moreover, in the conventional water purification apparatus, in order to prevent the accumulation of suspended solids, the recovery rate of the purified water with respect to the raw water remains at 90% by extracting about 10% of the raw water as waste water. For the same purpose, about 10% of the wastewater was drawn out as concentrated water, so the concentration rate remained 10 times.
[0005]
Furthermore, since the above rotating flat membrane is filtered in high concentration wastewater, it is difficult to completely prevent accumulation of turbidity and requires a great deal of power. Also, since this is a device with many operating parts, its maintenance is difficult.
[0006]
In order to solve this, the present applicants devised a device provided with a sedimentation tank for sedimenting suspended substances separated from the membrane by physical cleaning, and further provided with a baffle plate for preventing re-floating of the sediment. (Japanese Patent Application No. 8-25522 and Japanese Patent Application No. 8-25569), fine colloids of 1 micron or less of the suspended matter in the raw water do not precipitate as they are, so they can be collected in the sedimentation part. However, there was a problem of concentration in the membrane filtration tank. Furthermore, since the suspended matter separated by the membrane forms a high concentration region near the membrane surface, there is a problem that membrane clogging is likely to occur.
[0007]
[Means for Solving the Problems]
As a result of further studies to solve such problems, the present inventors have not caused membrane clogging by the fine colloid when concentrating raw water or wastewater by membrane filtration, and at a high concentration ratio. They found a water treatment device that can be operated stably.
[0008]
That is, the gist of the present invention is that the whole amount of the suspension is filtered by the membrane module, the filtration part which is a height part from the upper end part to the lower end part of the membrane module, and the concentrated part provided below the filtration part. A concentration unit having a sedimentation part for depositing turbidity in the suspension, and having an introduction part for introducing the suspension to be treated above the filtration part, the membrane density of the membrane module in the filtration part is The water treatment apparatus is characterized in that the membrane module is disposed in the filtration part so as to be 400 m ² / m ³ or more.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
Examples of the present invention will be described below, but the present invention is of course not limited thereto.
[0010]
FIG. 1 is a schematic view showing an example of the form of the water treatment apparatus of the present invention.
The introduction unit 2 uses raw water such as river water for water purification treatment, and waste water that concentrates turbidity in the raw water by sand filtration or membrane separation in the water purification treatment process. It is introduced into the concentrating device 1. The position of the introduction part 2 is provided in the upper part of the concentration apparatus 1. It is preferable that raw water or waste water that is commensurate with the amount of filtration by the membrane module 3 flow gently into the apparatus because treated water can be introduced into the concentrating apparatus 1 without disturbing sedimentation of turbidity.
[0011]
The filtration unit is formed in the upper part of the concentrating device 1, and the membrane module 3 is immersed therein, and the membrane module 3 performs total filtration of raw water or waste water. The size and material of the concentrating device 1 are not limited.
[0012]
The membrane module 3 provided in the concentrating device 1 is provided with a porous separation membrane that performs substantially turbid separation filtration.
The separation membrane used in the membrane module 3 can be a separation membrane of any shape such as a flat membrane, a hollow fiber membrane, a tubular membrane, a multi-lumen type.
[0013]
As the material of the separation membrane, inorganic membranes (ceramic membranes), organic membranes (PAN-based, cellulose-based, polyolefin-based, polysulfone-based, Teflon-based, vinylidene fluoride-based, acrylic-based, polyamide-based, etc.) should be used. Can do.
These separation membranes may be microfiltration membranes having an average pore size of about 0.01 to 5 μm or ultrafiltration membranes having a fractional molecular weight of about 1000 to 3000000 daltons. It is preferable to use a microfiltration membrane because it can be performed.
[0014]
In the membrane module 3 of the present invention, a membrane module having a membrane density of 400 m ² / m ³ or more is used. The membrane density in the present invention refers to the membrane area of the membrane module occupying in the volume in the filtration part (hereinafter referred to as “module part volume”) at the height from the upper end to the lower end of the membrane module. As a separation membrane, if a hollow fiber membrane module provided with a plurality of hollow fiber membranes is used, the membrane area per unit volume can be increased compared to a membrane module using a flat membrane or a tubular membrane. The membrane module 3 with high efficiency can be obtained, and the water treatment apparatus can be downsized. Preferably, in the present invention, a flat hollow fiber membrane module in which hollow fiber membranes are arranged in a flat plate shape is used, the arrangement direction of each hollow fiber membrane is a horizontal direction, and the flat plate surface on which the hollow fibers are laminated is It arrange | positions in the concentration apparatus 1 so that it may face a perpendicular direction.
[0015]
In the filtration apparatus of the present invention, as a method of cleaning the separation membrane, a method of performing reverse cleaning by pressurizing and flowing back the filtered water from the secondary side of the membrane module 3, or allowing air to diverge below the membrane module 3 The separation membrane can be cleaned by a method of bubbling with the diffuser tube 5 provided. In this case, cleaning with a chemical solution such as chlorine, an alkali solution, an acidic solution, a surfactant solution, or an organic solvent can be used in combination.
[0016]
Preferably, when the diffuser tube 5 is provided between the membrane module 3 and the baffle plate 6 having an opening described below and cleaning is performed by bubbling, the separation membrane is shaken, Since the colloid can be removed from the membrane surface, the increased filtration resistance can be efficiently restored. In this case, the air diffuser 5 may be disposed at the upper end of the baffle plate 6.
[0017]
As a filtration method, the concentration device 1 is a pressure-resistant can body, a pressure filtration method for filtering treated water by pressurizing the primary side of the membrane module 3, and a secondary side of the membrane module 3 is sucked by a suction pump or the like. However, from the viewpoint that the can body is unnecessary and the control of air bleeding when bubbling cleaning from the air diffuser 5 is not required. It is preferable to use a suction filtration method.
[0018]
In addition, the separation membrane cleaning process by bubbling from the air diffuser 5 is performed after filtration for a predetermined time, or due to adhering turbidity and fine colloids to the membrane surface of the separation membrane, the filtration pressure increases beyond a certain pressure (or This is performed when the filtration flow rate is lower than the constant flow rate). In addition, when performing a washing process, it is preferable to stop the filtration process.
[0019]
In the water treatment apparatus of the present invention, a precipitation section 4 for depositing turbidity is provided below the membrane module 3 in the concentration apparatus 1.
By providing the sedimentation section 4, turbidity that increases as filtration of the treated water continues can be accumulated and retained in the sedimentation section 4, so that the turbidity is concentrated after the treated water to be introduced is sufficiently concentrated. It can be discharged out of the device 1.
[0020]
In the water treatment apparatus of the present invention, a baffle plate 6 having an opening between the membrane module 3 and the precipitation part 4 may be provided horizontally in the concentration apparatus 1.
By disposing the baffle plate 6 having the opening in the horizontal direction, the volume of the sedimentation portion 4 provided below the baffle plate 6 can be further reduced, so that turbidity can be deposited on the sedimentation portion 4 at a high concentration. .
Therefore, the amount of concentrated water drained from the concentrating device 1 can be reduced, and the concentration rate of treated water can be improved accordingly.
[0021]
As the baffle plate 6 having an opening, a flat plate, a lattice assembly plate, a honeycomb structure plate, a pipe structure plate, or the like can be used.
When the baffle plate 6 is composed of a plurality of flat plates and is disposed in the concentration device 1 in the horizontal direction, a plurality of flat plates with the surface direction of each plate oriented in the vertical direction are disposed as a whole. Is arranged in the horizontal direction. In this case, the gap formed between the flat plates becomes the opening.
[0022]
As another aspect of the arrangement method of the baffle plate 6 having openings, a plurality of plates having a lattice structure, honeycomb structure plates, or pipe plates having pipe-like openings may be arranged in the horizontal direction. Good.
Moreover, if the baffle plate 6 which has these opening parts is arrange | positioned in the horizontal direction as a whole, the opening part may be a taper shape, and the opening part may be inclined. .
[0023]
Since the baffle plate 6 provided in the apparatus of the present invention has a structure having an opening, the turbidity that settles from above settles to the sedimentation part 4 from the opening, so that no turbidity accumulates on the baffle plate 6. .
Further, the water flow generated when the treated water is introduced into the concentrator 1 from the introduction unit 2 or when the membrane module 3 is cleaned is blocked by the baffle plate 6 and circulates above the baffle plate 6. Therefore, it is possible to prevent the turbidity accumulated in the sedimentation part 4 from floating in the direction of the membrane module 3 due to the water flow.
[0024]
In the water treatment apparatus of the present invention, it is possible to filter the treated water without adding a flocculant, but for the purpose of removing soluble substances such as viruses and ionic substances in the treated water, An appropriate amount of an aggregating agent may be added for the purpose of reducing an increase in the differential pressure of the porous membrane.
[0025]
[Action]
By introducing the treated water into the upper part of the membrane filtration concentration device and setting the membrane density of the membrane module in the filtration unit to 400 m ² / m ³ or more , the raw water or waste water supplied from above is gradually concentrated by membrane filtration. However, since it flows downward , fine colloids of 1 micron or less also move downward without floating due to this flow.
Also, under this condition, the flow of water accompanying filtration becomes a shear flow parallel to the membrane surface, so that it is possible to prevent the suspended matter such as fine colloids from being deposited on the membrane surface, and in the membrane module part. The concentration of suspended solids can be kept at the same level as the raw water and wastewater to be introduced.
The fine colloid that has moved downward is concentrated with a concentration interface below the lower end of the membrane module.
Due to these actions, in the present invention, filtration with a high recovery rate (high concentration rate) is possible while preventing accumulation of suspended substances on the membrane surface without requiring external power.
[0026]
【Example】
The present invention will be specifically described with reference to examples.
Example 1 and Comparative Example 1
A filtration test was conducted using the water treatment apparatus shown in FIG.
As the membrane module 3, a flat hollow fiber membrane module of UMF7824FAA module manufactured by Mitsubishi Rayon Co., Ltd. was used.
[0027]
The operating conditions (common to each example) in Example 1 and Comparative Example 1 of the water treatment device in the filtration test are as follows.

The results of the title test are shown in Table 1 below.
[0028]
[Table 1]

[0029]
According to the above test results, in Example 1, the apparatus of the present invention could be stably operated at a higher concentration ratio than in Comparative Example 1. On the other hand, in Comparative Example 1, the concentration rate was low, the membrane differential pressure increased in a short time, and the operation was stopped.
[0030]
【The invention's effect】
According to the water treatment apparatus of the present invention, by setting the membrane density of the membrane module to 400 m ² / m ³ or more, a high-concentration region of fine colloid near the membrane surface is not formed, and stable for a long period of time. It is possible to operate and perform filtration with excellent concentration efficiency and recovered water.
[Brief description of the drawings]
FIG. 1 is a schematic view showing an example of a water treatment apparatus of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Concentrator 2 ... Introduction part 3 ... Membrane module 4 ... Precipitation part 5 ... Air diffuser tube 6 ... Baffle plate

Claims (4)

The suspension module is used to filter the entire amount of the suspension, and the suspended portion in the concentrated suspension provided below the filtration unit, which is the height of the membrane module from the upper end to the lower end. In the concentrating apparatus having a precipitation part for depositing the liquid and having an introduction part for introducing the suspension to be treated above the filtration part, the membrane density of the membrane module in the filtration part is 400 m ² / m ³ or more. Thus, the membrane module is arrange | positioned by the filtration part, The water treatment apparatus characterized by the above-mentioned.   The water treatment device according to claim 1, wherein a flat hollow fiber membrane module in which hollow fiber membranes are arranged in a flat plate shape is used as the membrane module.   The water treatment apparatus according to claim 1 or 2, wherein a baffle plate for preventing floating of turbidity is provided between the membrane module and the sedimentation part.   4. A water treatment apparatus according to claim 3, wherein a diffuser tube is disposed between the membrane module and the baffle plate.

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