KR20140130097A - Indefinite form filter medium layer and filter device provided with same - Google Patents
Indefinite form filter medium layer and filter device provided with same Download PDFInfo
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- KR20140130097A KR20140130097A KR1020147010351A KR20147010351A KR20140130097A KR 20140130097 A KR20140130097 A KR 20140130097A KR 1020147010351 A KR1020147010351 A KR 1020147010351A KR 20147010351 A KR20147010351 A KR 20147010351A KR 20140130097 A KR20140130097 A KR 20140130097A
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01D—SEPARATION
- B01D24/00—Filters comprising loose filtering material, i.e. filtering material without any binder between the individual particles or fibres thereof
- B01D24/02—Filters comprising loose filtering material, i.e. filtering material without any binder between the individual particles or fibres thereof with the filter bed stationary during the filtration
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Abstract
The filtration media (4, 104, 204) for capturing the suspended substances contained in the liquid to be treated and the filtration tank materials (5, 105) for passing the suspended substances contained in the liquid to be treated , 205). The filtration media 4, 104 and 204 and the filtration media 5, 105 and 205 are mixed and passed through the filtration media 4, 104 and 204 and the filtration media 5, 105 and 205, do. The filtration apparatuses 1A, 1B, 101 and 201 are provided with filtration tanks 2, 102 and 202 for receiving the irregular filtration media 3, 103 and 203 and the irregular filtration media 3, 103 and 203, respectively.
Description
The present invention relates to an irregular filtration material layer (an amorphous filtration material layer) for separating and removing suspended substances contained in a liquid to be treated (raw water) and a filtration device having the irregular filtration material layer .
BACKGROUND ART A filtration apparatus constituting a filter material layer by a particulate particulate filter material is widely used in solid-liquid separation (solid-liquid separation) and biological treatment apparatuses. The above filtration apparatus performs surface filtration (surface filtration) in which suspended substances in the liquid to be treated are mainly captured on the surface of the filter medium layer. In the surface filtration, suspended matter trapped on the surface of the filter material layer is accumulated, and clogging occurs in the filter material layer even when the entire filter material layer is not used efficiently. As a result, the filtration pressure rises in a short time, and the filter medium needs to be frequently cleaned. In the case where the water passage (the gap between the adjoining filter materials) of the filter material layer is narrow, the balance of the filter material layer becomes poor and the surface layer filtration tends to occur easily. Deep filtration (deep filtration) in which suspended solids in the liquid to be treated are captured not only on the surface of the filter material layer but also inside the filter material layer makes it difficult to increase the filtration pressure of the filtration material layer, so that the amount of solid content per solid cycle is large. When the water passage through which the suspended material can pass is formed up to the inside of the filter material layer, the entire filter material layer can be efficiently used.
As an example of the filter medium constituting the filter medium layer, a filter medium layer having a certain thickness is formed by a particulate particulate filter medium having voids in the inside thereof, and the filter medium is formed on the inner and outer surfaces of the filter medium,
It is possible to form granules such as sand or anthracite which have different specific gravity or particle size from each other in a multilayered structure and to capture a large suspended particle at a large gap formed by particles having a large effective diameter, A filter device for capturing a small suspended substance in a small gap formed by the filter is proposed in
In addition, the gap between the filter materials is adjusted by forming a filter material layer by mixing an appropriate amount of two kinds of filter materials (particle diameter a and
A sand filtration device using granular activated carbon and garnet is known. For example, sand or garnet having a particle diameter of 0.45 to 0.8 mm, or a first filter material layer filled with sand and garnet in multiple layers, and a granular material having a particle size of 0.9 to 1.6
BACKGROUND ART [0002] A filtration apparatus for performing solid-liquid separation and biological treatment using a resinous filtration material (resinous filtration material) or a fiber filter material is known. For example, an apparatus for treating primary effluent using a resinous filter medium is provided. The filter is made of an upflow type (upflow type) filter with a small cylindrical filter medium having a porosity of 70% or more and a specific gravity of 1.0 or less, ) Is disclosed in
Which is a synthetic resin having a specific gravity of 0.800 to 0.999 and has a large surface area and has a substantially spherical outer periphery (water treatment filler, Is disclosed in
As a fiber filter material for separating suspended substances contained in sewage, a filament is wound around a core yarn and a pressing yarn which are twisted together to form a molybdenum filter material (mogol filter material) A water treatment fiber filter material is proposed in
It is difficult to select the filter material for the liquid to be treated when filtering is performed by the granular fiber filter material having an irregular shape. As the filter material layer composed of such a filter material passes over the filter material layer, the trapping band of the suspended material gradually proceeds from the surface layer portion of the filter material layer along the flow direction of the liquid to be treated. Further, since the fiber filter material is compressed by the filtration pressure, the flow path is reduced.
When a fiber filter material having a narrow channel between fibers constituting the inside of the filter medium is used, clarifying filtration for capturing a large amount of suspended material becomes possible. However, the surface layer filtration in which the suspended material is captured in large quantities by the filter material in the vicinity of the surface of the filter material layer is clogged in a short period of time, and the filtration pressure is increased. The process proceeds to the cleaning process based on the predetermined filtration pressure or the predetermined filtration continuation time. However, since the filtration material layer is not effectively used for filtration up to the deepest portion of the filter material layer, the number of times of the cleaning process is increased with respect to the trapping amount of the suspended material, thereby reducing the throughput. Further, since the gap between the filter materials must be adjusted in accordance with the liquid to be treated, it is necessary to select the filter material having an appropriate particle diameter and to adjust the pressure density of the filter material layer by the inflow pressure of the liquid to be treated.
When a fiber filter medium having a strength that can not be compacted by a wide fiber filter material or a filtration pressure is used, the deep filtration that the trapper advances to the deepest portion of the filter material layer becomes possible. The filtration pressure does not rise substantially but the quality of the treated liquid deteriorates and the suspended matter contained in the liquid to be treated flows out along with the treated liquid (breakthrough phenomenon) from the beginning of the filtration.
In a filtration device composed of a multi-layered granular material such as sand or anthracite having different specific gravity or particle size, a large particle diameter of the suspended material contained in the liquid to be treated is used first as a coarse particle filter material layer , And a small particle diameter is sequentially captured toward the particulate filter medium layer (particulate filter medium layer). The deep filtration in which the entire filter medium layer is effectively used is performed, but the processing speed is slow because the water channel in the filter medium tank is only the gap between the filter media. In the cleaning of the filter medium, it is necessary to spray a high-pressure fluid in cleaning by backwash. Further, in cleaning by agitation, the specific gravity difference of each filter medium must be made large so as to be composed of multiple layers after cleaning. In this case, a large power for stirring the filter medium having a large specific gravity is required. There is a possibility that a lump of the suspended material in the gap portion that is not released during the cleaning of the filter medium remains in the packed bed.
A filter material layer in which two kinds of filter materials (particle diameter (a) and particle diameter (3 to 5a)) having different particle diameters are mixed in an appropriate amount adjusts the gap distribution between the filter materials to efficiently capture the suspended material in the entire filter material layer . In a filter material layer having only a large particle size (3 to 5a), deep filtration is performed because a gap between the filter materials is large, but the trapping amount of the suspended material is small and a breakthrough phenomenon is likely to occur. On the other hand, in the case of the filter material layer having only a small particle size (a), the amount of trapped substance is large, but the gap between the filter materials is narrow, so that the filtration is performed in the surface layer and the filtration pressure rises in a short time. However, by mixing the large and small particle sizes, the gaps between the filter media are averaged, resulting in filtration performance equivalent to that of the filter media layer composed of two kinds of average particle diameters.
A high-speed filtration device such as a capillary tube or a fiber filtration device is a deep filtration device which forms a filter material layer of a certain thickness and captures a suspended substance inside the filter material layer. However, if the filter medium is agglomerated, the suspended material can not be captured because the suspended material can not be captured, and if the filter medium layer is excessively dense, the surface layer is filtered. It is necessary to select a filter material according to properties and treatment conditions of the liquid to be treated (raw water), but it is difficult to prepare many kinds of filter materials. For this reason, a filter material capable of coping with a standard-shaped liquid to be treated, such as sewage effluent, is required. This standard filter material can not use the entire filter material layer in a treatment liquid which is likely to be subjected to surface layer filtration such as coagulation filtration (aggregated filtration), shortening the duration of filtration, thereby increasing the frequency of cleaning and failing to exhibit sufficient function as deep filtration . It is necessary to develop a special filter medium and cope with it appropriately. Even if only one type of dedicated filter material different from the standard filter material is developed in this correspondence, it is easy to be subjected to surface layer filtration, but it can not be said that it is the optimum filter material in the intermediate case. In addition, in the case of a turbid solution to be treated such as river water immediately after rain, it is necessary to develop and adapt a filter material having a specific property to cope with the optimum material. When the structure of the filter material layer deviates from the optimum condition, the operation is performed by operating at a throughput lower than the standard performance of the filtration device, or by increasing the cleaning frequency of the filter material.
The floating filter method using two kinds of filter media described in
BACKGROUND ART [0002] In a filtration apparatus, a method of constructing a deep-seated filter medium layer by using filter media having a small particle diameter and a large particle diameter has been popularized in water treatment and the like. As described in
The small-sized cylindrical filter medium as described in
A high-speed filtration apparatus using a fiber filter material is a deep-filtration apparatus for forming a filter material layer of a predetermined thickness and capturing suspended matter in the fluid to be treated in the filter material layer. When the filtration is continued normally, The capture zone proceeds along the flow direction of the gas. If the filtration pressure loss due to the trapping of the suspended material does not reach a predetermined pressure, the trapping band progresses to the deep portion of the filter material layer, and eventually the phenomenon of breakthrough in which a large amount of suspended material flows out Lt; / RTI > The turbidity of the treated water is monitored to detect the breakthrough, thereby completing the filtration process and entering the cleaning process of the filter medium or the timer by the timer at predetermined intervals. When the filtration pressure loss due to trapping of the suspended material reaches a predetermined pressure before breakthrough, the filtration process is terminated without using the filter medium layer, and the filtration material is subjected to a washing process.
The above-described filtration apparatuses may be deep filtrated by selecting a filter material suited to the characteristics and conditions of the liquid to be treated, respectively, to exhibit predetermined filtration performance. However, the liquid to be treated includes various inorganic and organic substances. It is necessary to prepare a suitable filter medium such as the porosity inside the filter medium or the strength of the filter medium, thereby making production and inventory management difficult and troublesome.
An object of the present invention is to provide an irregularly shaped filter medium layer which does not require the selection of a filtration material suitable for a liquid to be treated and has a long continuous filtration time, and a filtration apparatus using the same.
An embodiment of the present invention is characterized in that it comprises a filter medium for trapping suspended solids contained in a liquid to be treated and a filtration tank for passing the suspended matter contained in the liquid to be treated, wherein the filter medium and the filtration tank material are mixed, Wherein the to-be-treated liquid is an irregular filtration material layer which is passed through the filtration material mixed with the filtration material and filtered.
According to the above configuration, the liquid to be treated is easily passed through the filtration material through the filtration material, so that not only the surface of the filtration material layer but also the inside of the filtration material layer can be effectively used for filtration. Further, it is unnecessary to select the filter material matched to the liquid to be treated, and the filtration continuation time can be prolonged.
Further, the filtration tank may have a gap through which the suspended material can easily pass through the filtration tank at all times.
According to the above configuration, the liquid to be treated can be easily passed to the inside of the filter material layer through the filtration tank.
The filtration tank may be formed of fibers.
According to the above configuration, since the suspended material can easily pass through the interior of the filtration tank at all times, it is possible to flow the liquid to be treated appropriately into the interior of the filtration material layer and perform deep filtration using the entire filtration material layer.
Further, the filtration tank may have a hollow interior and two or more openings in the peripheral wall.
According to the above arrangement, since the suspended material can always pass through the interior of the filtration tank, it is possible to flow the liquid to be treated appropriately into the interior of the filtration material layer, thereby enabling deep filtration using the entire filtration material layer.
Further, the filtration tank may be provided with a wool-finishing fiber partially napped for capturing the suspended material.
According to the above-described structure, the suspended matter can be effectively captured in the gap between the filter material and the filtration tank material, thereby facilitating purification filtration.
Further, the filtration tank may have a rectangular shape, a spherical shape, a molar shape, or a cylindrical shape.
According to the above configuration, various shapes can be adopted as the filtration tank.
The filter material may be formed of fibers.
According to the above configuration, the suspended material can be trapped by the gap between the filter materials and the air gap inside the filter material.
The filter material may be formed as a solid granular granular material.
According to the above configuration, the suspended material can be trapped by the gap between the filter materials.
The filter material is a wave-shaped filament fiber having a large number of voids therein and adhered to each other. The fibers between the fibers of the filter material are dense so as to trap the suspended material, and the filter material is a fiber And a strength not to be compacted by the filtration pressure may be provided, and the spaces between the fibers in the interior of the filter material may also be formed.
According to the above configuration, the to-be-treated liquid can be appropriately introduced into the interior of the filter material layer to perform deep filtration using the entire filter material layer.
Further, the filtration tank may be configured so as to have a larger internal space than the filter medium at the time of filtration of the liquid to be treated.
According to the above arrangement, even if the filtration pressure is increased and the filtration media layer is compacted, the flow passage for the inside of the filtration material layer can be ensured through the filtration filter material.
The filter material may be a thermoplastic resin.
According to the above constitution, it is possible to mass-produce the solid particulate filter material having a uniform shape and specific gravity.
The filter material may be a softening resin having closed cells.
According to the above configuration, since the specific gravity is small, the filter material does not settle even if a suspended material adheres to the filter material in the surface layer of the filtration surface, and an appropriate filtration layer thickness can be maintained.
The filter material may be a filter yarn, garnet, anthracite or a combination thereof.
According to the above configuration, various solid particulate materials can be employed as the filter medium.
Further, the filter material and the filtration tank may have floatability with respect to the liquid to be treated, and the filter material layer may pass the liquid to be treated upward from below in the gravity direction.
According to the above configuration, the irregular filter medium layer can be used as an upflow type filtration device.
Further, the filter material and the filtration tank material may have settleability with respect to the liquid to be treated, and the filter material layer may pass the liquid to be treated downward from above in the gravity direction.
According to the above configuration, the irregular filter medium layer can be used for the filtration device of the downflow type.
In addition, both the filter material and the filtration tank material may have a specific gravity of 0.1 or more and less than 1.0, when the specific gravity of the liquid to be treated is 1.0.
According to the above configuration, the irregular filter medium layer can be used as an upflow type filtration device.
In addition, both of the filter material and the filtration tank material may have a specific gravity of 1.0 or more and less than 3.0 when the specific gravity of the liquid to be treated is 1.0.
According to the above configuration, the irregular filter medium layer can be used for the filtration device of the downflow type.
The filtration tank may be evenly dispersed.
According to the above configuration, the liquid to be treated containing the suspended material can be appropriately introduced into the interior of the filter material layer, and the entire filter material layer can be trapped as it is, thereby enabling deep filtration using the entire filter material layer.
Further, the filtration tank may be more mixed on the upstream side than the downstream side.
According to the above configuration, clogging near the surface layer is less likely to occur, clogging of the filter material near the surface layer is delayed, and increase in filtration pressure in a short time can be prevented. Therefore, deep filtration using the entire filter material layer can be performed by positively introducing the liquid to be treated into the interior of the filter material layer.
Further, the volume mixing ratio of the filter medium and the filtration tank may be 0.95-0.5: 0.05-0.5.
According to the above configuration, it is possible to maintain the trapped SS amount of the entire filter material layer while preventing the break-through phenomenon, and to stabilize deep filtration utilizing the entire filter material layer.
An embodiment of the present invention is a filtration apparatus comprising the irregular filter medium layer and the filtration tank for containing the irregular filtration media.
BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic structural diagram of a filter material layer uniformly dispersed in the filtration apparatus according to the first embodiment. Fig.
2 is a downflow type filtration device.
3 is an upflow type filtration device.
4 is a schematic view of a square fiber filter medium.
5 is a schematic view of a spherical fiber filter medium.
6 is a schematic view of a molten fiber filter medium.
7 is a schematic view of a tubular fiber filter medium.
8 is a schematic view of a rectangular filtration tank.
9 is a schematic view of a spherical filtration tank material.
10 is a schematic view of a molten filtration tank material.
11 is a schematic view of a tubular filtration tank material.
12 is a partially enlarged view of the surface layer portion in the filter material layer showing the filtration state.
13 is a schematic configuration diagram of a filter medium layer dispersed in the surface layer.
Fig. 14 is a comparison chart of the filtration pressure and the filtration continuation time according to the first embodiment and related art.
15 is a schematic configuration diagram of a filter medium layer in the filtration apparatus according to the second embodiment.
16 is an upflow type filtration device.
Fig. 17 is a schematic view of a rectangular filtration tank; Fig.
18 is a schematic view of a spherical filtration tank material.
19 is a schematic view of a molten filtration tank material.
20 is a schematic view of a cylindrical filtration tank material.
21 is a partially enlarged view of the surface layer portion in the filter material layer showing the filtration state.
22 is a schematic configuration diagram of a filter medium layer dispersed in the surface layer.
Fig. 23 is a comparison chart of the filtration pressure and the filtration duration time according to the second embodiment and related art. Fig.
24 is a schematic configuration diagram of a filter medium layer in the filtration apparatus according to the third embodiment.
25 is a longitudinal sectional view of the filtration apparatus.
26 is an external view of the rectangular filtration tank.
27 is an external view of a cylindrical filtration tank material.
28 is an external view of the spherical filtration tank.
29 is an external view of the molten filtration trough.
30 is an enlarged view of the surface layer portion in the filter material layer showing the filtration state.
Fig. 31 is a schematic configuration diagram of a filter medium layer dispersed in the surface layer. Fig.
Fig. 32 is a comparison chart of a comparison test of the filtration pressure and the filtration duration in the filter medium layer formed by mixing only the filter paper of the related art and the filter paper of the third embodiment and the molyflective material.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A filtration apparatus according to an embodiment of the present invention will be described in detail with reference to the drawings. It is to be noted that in FIGS. 2, 3, 12, 13, 16, 21, 22, 25, 30 and 31, the vertical direction of the paper surface is the gravity direction, the lower direction of the paper is the downward direction of gravity, The upper direction is referred to as the upper direction of the gravity direction.
(First Embodiment)
The
Fig. 1 is a schematic structural view of the
Figs. 4 to 7 are schematic views of the filter medium according to the first embodiment. Fig. In the present embodiment, the
When the
Fig. 4 shows a quadrilateral fiber filter material (quadrilateral fiber filter material) 4a. The quadrangular-shaped
5 shows a spherical fiber filter material (spherical fiber filter material) 4b according to a modified example of the present embodiment. The spherical
Fig. 6 shows a mosquito-type fiber filter material (mogol-shaped fiber filter material) 4c according to a modified example of the present embodiment. The molybdenum fiber filter material 4c is formed into a molten shape. Since the molyficient fiber filter material 4c is composed of fibers in the same manner as the rectangular
Fig. 7 shows a cylindrical fiber filter material (4d) according to a modified example of the present embodiment. The cylindrical
Figs. 8 to 11 are schematic views of filtration tank members according to the first embodiment. Fig. The
Even if a large amount of suspended matter is captured on the surface S of the filter material layer 3 (see Fig. 12), the
The
The inside of the
The member constituting the
The gap between the
A part of the
Fig. 8 shows a quadrangular filtration aid (quadrangular filter aid) 5a. The quadrangular-shaped
Fig. 9 shows a
Fig. 10 shows a molten filtration aid (mogol-type filtration aid) 5c according to a modified example of the present embodiment. The molten filtration tanks 5c are formed in a molten form. Although the molten filtration material 5c is generated in the same manner as the molten fiber material 4c, the interstices are formed between the fibers of the molten fiber material 4c.
Fig. 11 shows a cylindrical filtration material (cylindrical filtration aid) 5d according to a modified example of the present embodiment. The
The
12 is a partial enlarged view of an example of the
A large amount of suspended material SS is trapped in the
Since the
By filtering the treated liquid containing the suspended material SS inside the
As shown in Fig. 1, the specific gravity of the
As described above, when the specific gravity difference is set to be small in the
When the
Specifically, as shown in Fig. 13, when the surface layer dispersion (surface layer dispersion) in which the
It is possible to cope with various kinds of liquids to be treated by adjusting the mixing ratio of the
When the specific gravity is 1.0 or more, the
Fig. 2 shows a
The liquid to be treated (treatment liquid supply pipe) 7A is connected to the
The
A discharge pipe (discharge pipe) 9 for discharging the liquid to be treated (for-treatment water) and the like is connected to the lower portion of the
Next, an example of the filtration treatment in the
The liquid to be treated flows down through the
For example, when the filtration pressure rises due to clogging due to the suspended substance trapped in the
When the liquid to be treated and air are supplied into the
3 is a schematic configuration diagram of a
Fig. 3 shows an upflow
The
The
A
A treatment
The
Next, an example of the filtration process in the
The target liquid is supplied to the
For example, when the filtration pressure rises due to the clogging by the suspended matter trapped in the
When the liquid to be treated and air are supplied into the
Further, the
A
Treatment liquid: Index that includes coagulated pond water or seaweed
Filter material: Mole-shaped fiber filter material (4c) Molar fiber having a diameter of 5 mm and a length of 15 mm
Filtration tank material: Molybdenum filtration tank material (5c) Molar fiber having a diameter of 5 mm and a length of 15 mm
This gym (main body) Height: 4000mm
This gymnastic bore: Diameter 600mm
Watering speed: 40m / h
Fig. 14 is a comparison table of the filtration pressure and the filtration continuation time of the
In the filtration apparatus (line indicated by R1 in Fig. 14) associated with the provision of the filter material layer composed only of the
On the other hand, in the
Specifically, in the filter material layer 3Aa (line indicated by E1-1 in Fig. 14) in which the
In addition, in the filter material layer 3Ab (line indicated by E1-2 in Fig. 14) in which the
The filter material layer of the associated filtration device is composed solely of the
On the other hand, the
Particularly, in the case of the filter material layer 3Aa in which the
If the proportion of the
The mixing ratio (hereinafter referred to as volume mixing ratio) in the volume of the
According to the present embodiment, since the filtration material matched to the liquid to be treated is not selected and deep filtration using the entire filter material layer having a long filtration duration is effectively performed, break-through phenomenon is less likely to occur and clarifying filtration is possible do.
The
According to the present embodiment, since the function of the
(Second Embodiment)
The
Fig. 15 is a schematic configuration diagram of the amorphous
16 shows the
The
The
The
The
In the
In the
The
The
The
Since the
The
The inside of the
Even if the member constituting the
The gap between the
A part of the
17 to 20 are schematic views of the
Fig. 17 shows a rectangular
Fig. 18 shows a
Fig. 19 shows a molten
Fig. 20 shows a
Further, the filtration tank materials 105 (105a to 105d) may be made thicker by increasing the strength of the fibers constituting the
The square-shaped
21 is a partially enlarged view of an example of the
The suspended substance SS is trapped in the gap between the
The
The trapping rate between the
As shown in Fig. 15, the specific gravity of the
(The specific gravity of the
It is possible to cope with various treatment liquids by adjusting the mixing ratio of the
Next, an example of filtration treatment in the
The to-be-treated liquid is filtered upward in the
For example, when the filtration pressure is increased due to clogging by the suspended substance trapped in the
The stirring wing in the
A
Treatment liquid: Coagulated effluent
Filter material: Filter material (104) PP pellet having a diameter of 3 mm
Filtration tank material: Mole-shaped filtration tank material (105c) Molar fiber having a diameter of 3 mm and a length of 3 mm
This gym height: 4000mm
This gymnastic bore: Diameter 600mm
Watering speed: 40m / h
Fig. 23 is a comparison table of filtration pressure and filtration continuation time for the
In the filtration apparatus (line indicated by R2 in Fig. 23) associated with the provision of the filter medium layer composed only of the
On the other hand, in the filtration apparatus 101 (indicated by E2-1 and E2-2 in Fig. 23) having the
Specifically, in the filtration material layer 103a in which the
Further, in the case of the filter material layer 103b (line indicated by E2-2 in Fig. 23) in which the
The filter medium layer of the associated filtration device is composed solely of the
On the other hand, the
Particularly, even if a suspended material is captured by the
By increasing the proportion of the
The volume mixing ratio of the
The
According to the present embodiment, since the function of the
(Third Embodiment)
The
Fig. 24 is a conceptual diagram of a
25 is a longitudinal sectional view of the
(Coagulated sludge) or high turbidity liquid (turbidity treated liquid) or high cleanliness degree (high clarity degree) that tend to be filtered by surface filtration It is possible to sufficiently exhibit the function of filtration by adjusting the volume mixing ratio of the
The
Figs. 26 to 29 are schematic views of the
Fig. 26 shows a
Fig. 27 shows a
The
28 shows a
The
Fig. 29 shows a
The
The
30 is a partially enlarged view of an example of the
The
31 is a conceptual diagram of a
A
Target liquid: Index containing coagulant or index including seaweed
Granular filtration media: filter
Filtration tank material: PET filament having a specific gravity of 1.38, a filament having a diameter of 5 mm and a length of 5 mm is made thick and the number of the molar fibers
This gym height: 4000mm
This gymnastic bore: Diameter 600mm
Flow rate: 20m / h
32 is a comparison result table of the
As a result of the comparative test, if the filtration pressure is increased to 15 kPa, the filtration material needs to be cleaned in order to remove the suspended suspended material from the filter material layer.
In the relevant filtration apparatus (line indicated by R3 in Fig. 32), the filtration pressure rose to 15 kPa at 8 hours. This indicates that the filter material needs to be cleaned every eight hours.
On the other hand, the filtration device 201 (indicated by E3-1 and E3-2 in Fig. 32) having the
In the filter medium layer 203b (line indicated by E3-2 in Fig. 32) in which the particulate filter medium 204 (filter paper) and the molten
The filter medium layer of the associated filtration device is composed solely of the
On the other hand, the
Particularly, in the filter material layer 203a in which the
If the proportion of the
The
The
Therefore, it can be used, for example, as a downflow filtration apparatus for treating wastewater generated in a sewage treatment plant, industrial wastewater, or a lake, a marsh or a river.
The
While the present invention has been described based on the embodiment, the present invention is not limited thereto, and the constitution of each part can be replaced with an arbitrary constitution having the same function.
Japanese Patent Application No. 2011-219139 (filing date: October 3, 2011), Japanese Patent Application No. 2012-059681 (filing date: March 16, 2012), and Japanese Patent Application No. 2012-076355 (filing date: 2012 March 29, 2008), which is incorporated herein by reference in its entirety.
Claims (21)
(Filtration aid) for passing the suspended matter contained in the liquid to be treated
Respectively,
The filter material and the filtration tank material are mixed,
Characterized in that the to-be-treated liquid is passed through the filtration material and the filtration tank material to be mixed therewith to be filtrated, thereby forming an irregular filtration material layer (amorphous filtration material layer).
Wherein the filtration tank has an air gap through which the suspended matter can easily pass through the inside of the filtration tank at all times.
Wherein the filtration tank material is formed of fibers.
Characterized in that the filtration tank has a hollow interior and two or more openings in the peripheral wall.
Characterized in that the filtration tank has a part of a nap-type filter material which is raised up to capture the suspended material.
Wherein the filtration tank material has a rectangular shape, a spherical shape, a mogol shape, or a cylindrical shape.
Wherein the filter medium is formed of fibers.
Wherein the filter medium is formed in a solid granular form.
The filter material is a wave-shaped filament fiber having many voids inside and adhered to each other,
The fibers between the fibers of the filter medium are closely packed to capture the suspended material,
Characterized in that the filtration tank material is a fiber and has a strength not being constricted by the filtration pressure and is interstices between the fibers in the interior of the filter medium.
Characterized in that the filtration tank material is configured to have an inner space larger than that of the filtration material at the time of filtration of the liquid to be treated.
Wherein the filter medium is a thermoplastic resin (thermoplastic resin).
Wherein the filter medium is a softening resin (softening resin) having independent bubbles.
Wherein the filter medium is a filtration sand, garnet, anthracite, or a combination thereof.
Wherein the filter material and the filtration tank material have floatability with respect to the liquid to be treated,
Wherein the filter medium layer permeates the liquid to be treated upwardly from below in the gravity direction.
Wherein the filter material and the filtration tank material have sedimentation property with respect to the liquid to be treated,
Wherein the filter medium layer permeates the liquid to be treated from above to below in the gravity direction.
Wherein the filtration material and the filtration material both have a specific gravity of 0.1 or more and less than 1.0 when the specific gravity of the liquid to be treated is 1.0.
Wherein the filtration material and the filtration material both have a specific gravity of 1.0 or more and less than 3.0 when the specific gravity of the liquid to be treated is 1.0.
Characterized in that the filtration tank material is uniformly dispersed (dispersed).
Characterized in that the filtration tank material is mixed more upstream on the downstream side than on the downstream side.
Wherein the volume ratio of the filtration media to the filtration media is 0.95-0.5: 0.05-0.5.
A filtration tank (filtration tank) for containing the amorphous filter medium layer
A filtering device.
Applications Claiming Priority (3)
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PCT/JP2012/074253 WO2013051405A1 (en) | 2011-10-03 | 2012-09-21 | Indefinite form filter medium layer and filter device provided with same |
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JPS60193508A (en) * | 1984-03-16 | 1985-10-02 | Hitachi Plant Eng & Constr Co Ltd | Solid-liquid separator |
JPS647920A (en) * | 1987-06-29 | 1989-01-11 | Mini Public Works | Solid-liquid separation device |
JP2735587B2 (en) * | 1988-11-24 | 1998-04-02 | サッポロビール株式会社 | Filter, filter unit using the same, and precision filter processing method |
JPH0560505U (en) * | 1992-01-17 | 1993-08-10 | 株式会社ロキテクノ | Filtration device |
JPH0679108A (en) * | 1992-09-02 | 1994-03-22 | Kurita Water Ind Ltd | Filter |
JPH07299469A (en) * | 1994-05-11 | 1995-11-14 | Sinto Brator Co Ltd | Flocculation method of waste water containing releasing agent produced from surroundings of die cast machine |
JPH11216306A (en) * | 1997-11-10 | 1999-08-10 | Toto Ltd | Purification device of bathtub water and circulating system of bathtub water |
JP3058635B1 (en) * | 1999-07-08 | 2000-07-04 | 岸本 進 | Filtration treatment method and filtration treatment device using fibrous filter medium |
JP2003200009A (en) * | 2001-12-28 | 2003-07-15 | Kobe Steel Ltd | Filter aid for cold rolling mill lubricant and filtering method for the same |
JP2004167371A (en) * | 2002-11-20 | 2004-06-17 | Kankyo Eng Co Ltd | Filtration device and method for washing filter medium |
CN101854998B (en) * | 2007-11-12 | 2014-07-23 | Mgf古切控股两合公司 | Filter medium |
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