JP4936783B2 - Filtration concentrator - Google Patents

Description

The present invention relates to a filter plate of a sludge filtration and concentration device in a water purification plant, a sewage treatment plant, or the like.

Since sludge discharged from water treatment plants and sewage treatment plants contains 90% or more of moisture, conventionally, after concentration in a gravity sedimentation tank, mechanical dehydration is performed, and concentrated sludge with a moisture content of 80% or less. The concentrated sludge is incinerated and disposed of in landfills.
In the conventional sludge concentration in the gravity settling tank, the residence time is long and the moisture content varies greatly depending on the properties of the sludge. Therefore, it is difficult to stably operate the mechanical dehydration. Therefore, a filtration and concentration device was developed as an alternative to the gravity sedimentation tank.

  A conventional filtration concentration apparatus will be described with reference to FIG. When a conventional filtration and concentration apparatus supplies sludge tank 1 having a tapered bottom, piping for supplying raw sludge to sludge tank 1, valve 8, pump 2, and sludge tank 1 for supplying raw sludge. A water level meter 18 that detects the sludge water level to activate the pump 2 and put sludge to a predetermined water level, a pipe and valve 9 for discharging the concentrated sludge after being concentrated at the bottom of the sludge tank 1, and the sludge tank 1 A plurality of filter plates 3 disposed therein, a filtrate discharge pipe 4 for discharging the filtrate filtered by the filter plate 3, a water supply tank 5 connected in the middle of the filtrate discharge pipe 4, and water is supplied to the water supply tank 5 A tap water supply pipe 6 and a valve 12, a pipe and valve 14 for discharging air accumulated in the water supply tank 5, and a compressor 7 and a valve 13 connected to the water supply tank 5 for supplying pressurized air. ing. The outlet height of the filtrate discharge pipe 4 is set to be lower than the lower end of the filter plate 3. The filter plate 3 includes a filter membrane 3a that separates the filtrate and sludge, and a filter frame 3b that supports the filter membrane 3a.

  FIG. 11 is a diagram showing the configuration of the filter plate 3. An air distribution pipe 15 is provided on the inner upper part of the filter plate 3 for sucking the filtrate and peeling the concentrated sludge. The air distribution pipe 15 is a round or square pipe made of metal, vinyl chloride, or the like installed in the horizontal direction, and a plurality of holes 16 are provided vertically downward at the bottom of the pipe. The holes 16 are provided for sucking the filtrate inside the filter plate 3 and for supplying pressurized air for separating the concentrated sludge from the filter membrane 3a. The end of the air distribution pipe 15 opposite to the pressurized air blowing port is sealed.

Next, the operation method of the conventional filtration concentration apparatus will be described. Valves 9-14 are all closed and valve 8 is open. Then, the pump 2 is operated to supply the raw sludge to a predetermined water level where the filter plate 3 installed in the sludge tank 1 is submerged.
Next, after the valves 12 and 14 are opened and water is supplied until the water supply tank 5 reaches a predetermined water level, the valves 12 and 14 are closed. Then, the valves 10 and 11 are opened to start filtration. During the filtration process, the pump 2 is operated so that the water level of the raw sludge maintains this predetermined water level. The supply and filtration of the sludge is continued until the thickness of the sludge deposited on the filtration membrane 3a is preferably 10 to 13 mm. The time for which the filtration is continued may be carried out by examining the relationship between the sludge accumulation thickness and the filtration time in advance, and thereafter using the filtration time when the sludge accumulation thickness is 10 to 13 mm as an index. For example, in the case of this siphon filtration, filtration is performed for 90 minutes.

Next, the valve 10 is closed, the valve 8 is opened, the pump 2 is operated, and unconcentrated sludge that has not adhered to the surface of the filtration membrane 3 a is discharged from the sludge tank 1. After unconcentrated sludge is discharged from the sludge tank 1, the valve 8 is closed.
Next, the valves 10 and 13 are opened, and air is introduced into the secondary side of the filtration membrane 3a by the compressor 7 and pressurized. As a result, in the state where the water in the water supply tank 5 and the filtrate discharge pipe and the air of the compressor 7 are mixed, the concentrated sludge adhering to the primary side surface of the filtration membrane 3a is peeled off and dropped from the filtration membrane 3a. The concentrated sludge is deposited on the bottom of the sludge tank 1. Then, the valve 9 is opened to discharge the concentrated sludge from the sludge tank 1.

The concentrated sludge stripping principle using the above filter plate is summarized as follows.
The pressurized air supplied to the air distribution pipe 15 is ejected from the hole 16 provided in the distribution pipe toward the secondary side of the filtration membrane 3a to which the concentrated sludge has adhered (partly supplied to the filtration membrane channel) ) Thereby, the concentrated sludge adhering to the surface of the filtration membrane 3a around the air distribution pipe is peeled off.
-The peeled concentrated sludge falls toward the bottom of the sludge tank 1 while entraining other concentrated sludge.
Japanese Patent Publication No. 63-13721 JP 2001-145899 A

A conventional filtration and concentration apparatus provided with an air distribution pipe has a problem that concentrated sludge remains on the upper part of the filter plate. As a result, the amount of sludge treated per hour is reduced and the lifetime of the filter plate is shortened. In other words, when the filtration cycle was repeated, the portion where the sludge remained was filtered and sucked, so that the adhesion between the filtration membrane and the concentrated sludge became strong and clogging occurred.
Then, an object of this invention is to provide the filtration concentration apparatus which can prevent that concentrated sludge remains in the upper part of a filter plate.

In order to solve the above problems, the present invention has the following configuration.
The filtration concentration apparatus according to claim 1, wherein the sludge tank for storing sludge, the filtration membrane for filtering the sludge, and the gas for separating the concentrated sludge concentrated by the filtration membrane from the filtration membrane are filtered. in the filtration concentrator and a piping for supplying the secondary side of the membrane, the piping, as well is installed on the secondary side of the filtration membrane upper secondary-side surface of the filtration membrane downward A hole is provided for jetting toward the inclined region of the filtration membrane inclined so as to face . Here, the said inclination area | region is an area | region of the said filtration membrane in which the said filtration membrane descends diagonally in the head vicinity vicinity . In addition, when the top part of the said filtration membrane is horizontal, the horizontal part of the said top part is also included in the said inclination area | region. According to the above configuration, the pressurized air applied to the inside of the pipe can apply pressure from below to above the filtration membrane, and can prevent the concentrated sludge from remaining in the inclined region.

A filtration concentration apparatus according to a second aspect is the filtration concentration apparatus according to the first aspect, wherein a gap is provided between the hole and the filtration membrane. If it is set as the said structure, the vibration which pressurized air gives to a filtration membrane can be transmitted in a wide range.
The filtration concentration apparatus according to claim 3 is the filtration concentration apparatus according to claim 1 or 2, wherein the filtration membrane is flexible.

A filtration concentration apparatus according to a fourth aspect is the filtration concentration apparatus according to any one of the first to third aspects, wherein a porous member is provided between the tube and the filtration membrane. If it is the said structure, the flow of a filtrate and pressurized air can be made easy .

  According to the present invention, since the concentrated sludge adhering to the entire membrane surface can be peeled off, it is possible to prevent a decrease in the amount of sludge treated per hour. And since the concentrated sludge remaining on the upper part of the filter plate is eliminated, clogging of the filter membrane is reduced, so that the replacement cycle of the filter membrane can be lengthened.

Hereinafter, embodiments of the present invention will be described based on examples. The filtration concentration apparatus of the present embodiment is a filtration concentration apparatus having the same configuration as that of FIG.
FIG. 1 is a configuration diagram of a filter plate 3 to which the present invention is applied. The filter plate 3 includes a filter membrane 3 a and an air distribution pipe 15. You may provide the filter frame 3b which is not shown in figure as needed. The filtration membrane 3a is formed into a bag shape by sewing the periphery with a sewing thread as necessary. Further, the central portion of the filtration membrane is sewn with a sewing thread to form a filtration membrane flow path. An air distribution pipe 15 through which pressurized air for sucking the moisture of the concentrated sludge adhering to the surface of the filtration membrane and for removing the concentrated sludge flows is provided inside the bag to which the filtration membrane 3a is stitched. FIG. 2 shows an AA cross-sectional view of the air distribution pipe 15 of the present embodiment. The air distribution pipe 15 is provided with a hole for ejecting air to the inclined area above the filtration membrane 3a. The end of the air distribution pipe 15 opposite to the pressurized air blowing port is sealed.

The operation method of the filtration concentration apparatus of the present embodiment is the same as the operation method in the above-described conventional filtration concentration apparatus. Valves 9-14 are all closed and valve 8 is open. Then, the pump 2 is operated to supply the raw sludge to a predetermined water level where the filter plate 3 installed in the sludge tank 1 is submerged.
Next, after the valves 12 and 14 are opened and water is supplied until the water supply tank 5 reaches a predetermined water level, the valves 12 and 14 are closed. Then, the valves 10 and 11 are opened to start filtration. During the filtration process, the pump 2 is operated so that the water level of the raw sludge maintains this predetermined water level. The supply and filtration of the sludge is continued until the thickness of the sludge deposited on the filtration membrane 3a is preferably 10 to 13 mm. The time for which the filtration is continued may be carried out by examining the relationship between the sludge accumulation thickness and the filtration time in advance, and thereafter using the filtration time when the sludge accumulation thickness is 10 to 13 mm as an index. For example, in the case of this siphon filtration, filtration is performed for 90 minutes.

Next, the valve 10 is closed, the valve 8 is opened, the pump 2 is operated, and unconcentrated sludge that has not adhered to the surface of the filtration membrane 3 a is discharged from the sludge tank 1. After unconcentrated sludge is discharged from the sludge tank 1, the valve 8 is closed.
Next, after the valves 11 and 14 are opened and the water in the water absorption tank 5 and the filtrate discharge pipe 4 is removed, the valves 11 and 14 are closed.

Next, the valves 10 and 13 are opened, and air is introduced into the secondary side of the filtration membrane 3a by the compressor 7 and pressurized. Thereby, the concentrated sludge adhering to the primary side surface of the filtration membrane 3a is peeled and dropped from the filtration membrane 3a, and the peeled concentrated sludge is deposited on the bottom of the sludge tank 1. Then, the valve 9 is opened to discharge the concentrated sludge from the sludge tank 1.
The results of the prior art and the examples of the present invention are shown in Table 1. The sludge used is dam discharge water and the amount of purified water treated is 20,000 m ³ / day of purified water sludge. The filtration was performed at a filtration pressure of −33 kPa and a filtration time of 90 minutes. Concentrated sludge stripping was continued for 5 seconds under a pressurized air pressure of 5 kg / cm ² . The filtration membrane used was a monofilament made of nylon and having a filtration area of 1.3 m ² per sheet.
From the results shown in Table 1, the air distribution pipe 15 is provided with a hole 16 for injecting air into the inclined region above the filtration membrane 3a under the same concentrated sludge thickness and concentrated sludge concentration conditions. The sludge stripping rate was 60 to 90% in the prior art, but increased to 95 to 98% in the examples of the present invention.

Moreover, even if the air distribution pipe 15 as shown in FIGS. 3 to 9 is used, the concentrated sludge remaining on the upper part of the filter plate 3 can be eliminated.
FIG. 3 shows an embodiment in which the angle formed by the inclined surface of the filtration membrane and the vertical is 45 degrees or less. Since the concentrated sludge peeled off from the upper part of the filter plate 3 entrains and separates the concentrated sludge still adhering to the filtration membrane, it becomes easy to peel the concentrated sludge from the filtration membrane. And in the case where the vertical cross-sectional shape of the air distribution pipe 15 is a triangle, if the base of the triangle is wide, the thickness of the filter plate 3 increases and the filtrate remaining in the filter plate 3 increases. Concentrated sludge concentration decreases. Therefore, it is desirable that the triangle has a narrow base.

FIG. 4 shows an embodiment in which a porous member 19 is provided between the air distribution pipe 15 and the filtration membrane 3a in FIG. As the porous material 19, a mesh-like material is preferable.
5 to 9 show an embodiment in which a gap is provided between the hole 16 and the filtration membrane 3a. More specifically, the protrusion 17 is provided at the top of the air distribution pipe 15, and a gap is provided between the filtration membrane 3 a and the hole 16. FIG. 5 shows an embodiment in which a protrusion 17 is provided on the top of the air distribution pipe 15 in FIG. FIG. 6 shows an embodiment in which the top of the air distribution pipe 15 shown in FIG. 2 is throttled and a protrusion 17 is provided on the top of the air distribution pipe 15. The air distribution pipe 15 shown in FIGS. 7 and 8 has a hole 16 formed in a stainless steel plate, and is curved by pressing as shown in FIG. 9 so that the two stainless steel plates are joined together and the surroundings except for the pressurized air blowing port are electrically connected. The air distribution pipe 15 is formed by resistance welding. In FIG. 9, the filtration membrane 3a is formed so as to be partially separated from the air distribution pipe 15, and the hole 16 is located under the filtration membrane inclined region where the filtration membrane is inclined with the secondary side down after filtration. This is an embodiment. That is, in the embodiment of FIG. 9, the filtration membrane 3a has flexibility and deforms before and after filtration.

Schematic configuration diagram of a filtration plate in the filtration concentration apparatus of the present invention An example of a sectional view in the vicinity of an air distribution pipe in the filtration concentration apparatus of the present invention An example of a sectional view in the vicinity of an air distribution pipe in the filtration concentration apparatus of the present invention An example of a sectional view in the vicinity of an air distribution pipe in the filtration concentration apparatus of the present invention An example of a sectional view in the vicinity of an air distribution pipe in the filtration concentration apparatus of the present invention An example of a sectional view in the vicinity of an air distribution pipe in the filtration concentration apparatus of the present invention An example of a sectional view in the vicinity of an air distribution pipe in the filtration concentration apparatus of the present invention 7 is a perspective view of the air distribution pipe in FIG. An example of a sectional view in the vicinity of an air distribution pipe in the filtration concentration apparatus of the present invention Configuration diagram of conventional filtration and concentration equipment Schematic configuration diagram of a filter plate in a conventional filter concentration device

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Sludge tank 2 Pump 3 Filter plate 3a Filtration membrane 3b Filter frame 4 Filtrate discharge pipe 5 Water supply tank 6 Tap water supply pipe 7 Compressor 8-14 Valve 15 Air distribution pipe 16 Hole 17 Protrusion 18 Water level gauge 19 Porous member

Claims (4)

A sludge tank for storing sludge, and a filtration membrane for filtering the sludge, and piping for supplying air to be peeled off the concentrated sludge that has been concentrated by the filtration membrane from the filtration membrane to the secondary side of the filtration membrane in the filtration concentrator equipped with the distribution tube, while being placed on the secondary side of the filtration membrane upper secondary-side surface of the filtration membrane is inclined so as to face downward, the slope of the filtration membrane A filtration concentrating device comprising a hole for spraying toward an area.   The filtration concentration apparatus according to claim 1, wherein a gap is provided between the hole and the filtration membrane.   The filtration and concentration apparatus according to claim 1 or 2, wherein the filtration membrane is flexible.   The filtration concentration apparatus according to any one of claims 1 to 3, wherein a porous member is provided between the tube and the filtration membrane.