JP5632779B2 - Backwash type filtration device - Google Patents

Description

  The present invention relates to a backwashing type filtration apparatus capable of washing raw water with a filtration element and washing the filtration element by flowing the filtered water back.

  This type of backwashing type filtration apparatus includes a pressure vessel and a plurality of cylindrical filtration elements arranged in the pressure vessel.

  During the filtration operation of the backwash type filtration device, the raw water is allowed to flow inside the filtration element and pass through the filtration channel formed in the filtration element, while the filtration element is appropriately selected from a plurality of filtration elements On the other hand, continuous filtration is enabled by reversing the filtered water to remove microorganisms or suspended solids clogged in the filtration flow path and washing the filtration element sequentially (for example, Patent Document 1, Patent Document 2).

  And as a filtration element, what wound wires, such as a notch wire, is known (for example, patent documents 3).

  However, a filtration element configured by winding a wire has a problem in strength because it has a small wire diameter and is easily deformed against a hydraulic pressure.

  Therefore, in order to solve such problems, a filter element in which a disk-type filter medium is laminated has been proposed (for example, Patent Document 4). Since the disk-type filter medium can sufficiently secure a width in the radial direction, a sufficient strength can be ensured.

Utility Model Registration No. 3137987 JP 2001-170416 A JP 2000-1117013 A JP 2001-300216 A

  However, a filter element with a disc-shaped filter medium laminated increases the length of the filter flow path between the filter mediums to the extent that a sufficient radial width can be secured. There was a problem that the amount of processing was reduced. Moreover, there has been a problem that microorganisms and the like clogged in the filter element cannot be sufficiently removed during backwashing.

  In addition, when draining backwash water after washing the filtration element from the backwash pipe, there is a problem that an outlet pressure acting as a back pressure is generated. Such a problem occurs, for example, when a backwash filter is mounted on a ship and ballast water is filtered.

  In view of the above problems, the present invention is excellent in raw water treatment capacity, can effectively remove microorganisms and the like clogged in the filtration element during backwashing, and has an outlet pressure that acts as a back pressure. It is an object of the present invention to provide a backwashing type filtration device that can solve the problem.

The backwashing type filtration apparatus according to the first technique related to the present invention is:
A pressure vessel having a raw water chamber and a filtrate water chamber, a cylindrical filtration element disposed in the pressure vessel, and a control means are provided, and the raw water is passed from the inside to the outside of the filtration element for filtration. And a backwash type filtration device for washing the filtration element by flowing the filtered water back,
The filtration element is configured by laminating a disk-type filter medium in which a filtration channel forming groove is formed in the radial direction, and forming a filtration channel between the upper and lower filter media,
The flow path height of the filtration flow path is configured such that the downstream side is higher than the upstream side,
The control means includes
A control valve for controlling the outflow of the filtrate from the filtrate chamber;
Detecting means for detecting a differential pressure between the pressure in the filtered water chamber and the pressure in the raw water chamber;
A control unit for controlling the control valve by a detection signal of the detection means,
When the differential pressure does not reach a predetermined reference value, operate in a normal operation mode in which the filtration element is washed in a normal state,
When the differential pressure reaches a predetermined reference value, the control valve is controlled based on the detection signal of the detection means to increase the pressure of the filtered water chamber to clean the filtration element. It is characterized by returning to a normal operation mode after driving.

The backwashing type filtration apparatus according to the second technique related to the present invention is:
The control means includes
Fresh water supply means for supplying fresh water for forced backwashing to the filtered water chamber;
A control unit for controlling the fresh water supply means by a detection signal of the detection means for detecting the differential pressure,
When the control valve cannot be returned to the normal operation mode, the control valve is fully closed and the fresh water is supplied to the filtrate water chamber to clean the filter element. It is characterized by returning to the normal operation mode after driving in the mode.

The backwashing type filtration apparatus according to the third technique related to the present invention is:
A pressure vessel having a raw water chamber and a filtrate water chamber, a cylindrical filtration element disposed in the pressure vessel, and a control means are provided, and the raw water is passed from the inside to the outside of the filtration element for filtration. And a backwash type filtration device for washing the filtration element by flowing the filtered water back,
The filtration element is configured by laminating a disk-type filter medium in which a filtration channel forming groove is formed in the radial direction, and forming a filtration channel between the upper and lower filter media,
The flow path height of the filtration flow path is configured such that the downstream side is higher than the upstream side,
The control means includes
A control valve for controlling the outflow of the filtrate from the filtrate chamber;
Detecting means for detecting a differential pressure between the pressure in the filtered water chamber and the pressure in the raw water chamber;
A control unit for controlling the control valve by a detection signal of the detection means,
When the differential pressure does not reach the first reference value, the operation is performed in the operation mode 1 in which the filtration element is washed with a predetermined backwash time,
When the differential pressure reaches the first reference value, after operating in the operation mode 2 for cleaning the filtration element in a time longer than the predetermined backwash time, return to the operation mode 1,
When the differential pressure reaches a second reference value that is greater than the first reference value, the control valve is controlled based on the detection signal of the detection means to increase the pressure in the filtered water chamber. After the operation in the operation mode 3 in which the filtration element is washed, the operation mode 1 is restored.

The backwashing type filtration apparatus according to the fourth technique related to the present invention is:
A drain valve provided in the backwash pipe of the backwash water;
Detecting means for detecting the outlet pressure of the drain valve,
Before starting the cleaning of the filter element in the operating mode,
The pressure of the filtered water chamber and P _2, the outlet pressure of the water discharge valve and P _4, the discharge pressure of the backwash water required to perform the pipe resistance and backwashing efficiently when the alpha,
P ₄ + α ≦ P ₂
The control valve is controlled so that the above relationship is established.

The present invention is made based on each of the above technologies, and the backwashing type filtration apparatus according to claim 1
A pressure vessel having a raw water chamber and a filtrate water chamber, a cylindrical filtration element disposed in the pressure vessel, and a control means are provided, and the raw water is passed from the inside to the outside of the filtration element for filtration. And a backwash type filtration device for washing the filtration element by flowing the filtered water back,
The filtration element is configured by laminating a disk-type filter medium in which a filtration channel forming groove is formed in the radial direction, and forming a filtration channel between the upper and lower filter media,
  The flow path height of the filtration flow path is configured such that the downstream side is higher than the upstream side,
The control means includes
A control valve for controlling the outflow of the filtrate from the filtrate chamber;
Detecting means for detecting a differential pressure between the pressure in the filtered water chamber and the pressure in the raw water chamber;
A control unit for controlling the control valve by a detection signal of the detection means;
With
When the differential pressure does not reach the first reference value, the operation is performed in the operation mode 1 in which the filtration element is washed with a predetermined backwash time,
When the differential pressure reaches the first reference value, after operating in the operation mode 2 for cleaning the filtration element in a time longer than the predetermined backwash time, return to the operation mode 1,
When the differential pressure reaches a second reference value that is greater than the first reference value, the control valve is controlled based on the detection signal of the detection means to increase the pressure in the filtered water chamber. After the operation in the operation mode 3 in which the filtration element is washed, the operation mode 1 is restored.

  According to the present invention, the raw water is excellent in treatment capacity, and at the time of backwashing, microorganisms and the like clogged in the filter element can be effectively removed, and the problem of the outlet pressure acting as a back pressure can be solved. It is possible to provide a backwashing type filtration device that can be used.

It is sectional drawing which shows the structure of the backwashing type | mold filtration apparatus which concerns on embodiment of this invention. It is sectional drawing of the AA line shown in FIG. It is a perspective view which shows the filtration element of the backwashing type | mold filtration apparatus which concerns on embodiment of this invention. It is a perspective view which shows the filter material of the filtration element of the backwashing type filter apparatus which concerns on embodiment of this invention. It is sectional drawing which expanded a part of filtration element of the backwashing type filter apparatus which concerns on embodiment of this invention. It is a perspective view which shows a part of other example of the filtration element of the backwashing type filter apparatus which concerns on embodiment of this invention.

  Hereinafter, the present invention will be described based on embodiments.

1. 1 is a cross-sectional view showing a configuration of a backwashing filtration apparatus according to the present embodiment. 2 is a cross-sectional view taken along line AA shown in FIG.

  As shown in FIGS. 1 and 2, the backwashing type filtration apparatus 1 includes a pressure vessel 2, a plurality of cylindrical filtration elements 6 disposed in the pressure vessel 2, and a control means C. While the raw water is filtered from the inside to the outside of the filtration element 6 for filtration, the filtered water is made to flow backward to wash microorganisms and the like clogged in the filtration element 6. In FIG. 1, 3 is an inlet for raw water, 4 is an outlet for filtered water, 5 is a partition plate, 8 is backwashing means, and 9 is a motor.

  The interior of the pressure vessel 2 is partitioned into a raw water chamber 11 having an inflow port 3 and a filtered water chamber 12 having an outflow port 4 by a partition plate 5 having a plurality of openings 10.

  The plurality of filtration elements 6 are disposed on the filtered water chamber 12 side, and the bottom opening 14 of the filtration element 6 is attached to the plurality of openings 10 of the partition plate 5.

  Then, the raw water is pumped by a pump outside the figure and is filtered after flowing from the inlet 3 through the raw water chamber 11 into the filter element 6 through the opening 10 as shown by the solid line arrow in FIG. And flows out into the filtered water chamber 12 as filtered water. On the other hand, the backwashing means 8 is used to backwash the filtration element 6 during the filtration operation.

2. Backwashing means As shown in FIG. 1, the backwashing means 8 includes a backwashing pipe 21 provided with a ball valve (drainage valve) C7 near one end, and the backwashing pipe 21 includes branch pipes 21a and 21b. And a fixed pipe 211 connected to the ball valve C7, and a connecting portion between the rotary pipe 210 and the fixed pipe 211 is sealed. Further, backwash nozzles 20a and 20b are provided at the ends of the branch pipes 21a and 21b. The rotating tube 210 of the backwash tube 21 is connected to the motor 9 by the rotating shaft 22.

  Then, during the filtration operation, the backwash tube 21 is rotated to connect the backwash nozzles 20a, 20b to the opening 10 of the partition plate 5 in order, so that the filtered water is filtered inside the filtration element 6 by utilizing the pressure difference. Then, the liquid flows backward through the backwash pipe 21 as shown by the broken line arrow and is discharged from one end of the backwash pipe 21 to the outside. Thereby, microorganisms and the like clogged in the filter element 6 are removed.

3. FIG. 3 is a perspective view showing a filtration element of the backwashing type filtration apparatus according to the present embodiment, and FIG. 4 is a perspective view showing a filtering material of the filtration element of the backwashing type filtration apparatus according to the present embodiment. FIG. 5 is an enlarged cross-sectional view of a part of the filtration element of the backwash type filtration apparatus according to the present embodiment.

  As shown in FIGS. 3 to 5, the filtration element 6 includes a laminated body in which a filter medium 7 having a disk shape and a filtration channel forming groove 15 formed on the upper surface is laminated, and the upper filter medium 7 is flat. The lower flow path 16 is formed by the lower surface and the filtration flow path forming groove 15 of the lower filter medium 7, and the upper opening of the uppermost filter medium 7 is closed by the top plate 13.

  As shown in FIG. 3, the fixing means for the filtration element 6 includes a rod bolt 17 and a positioning rod 19 erected on the partition plate 5 (see FIG. 1). The fixed grooves 7a (see FIG. 4) are formed, these fixed grooves 7a are fitted to the positioning rods 19, the upper ends of the rod bolts 17 and the positioning rods 19 are inserted into the mounting holes 13a of the top plate 13, A nut 18 is fitted to the upper end of the rod bolt 17. Thereby, the laminated body of the filter medium 7 is fixed by pressing the laminated body of the filter medium 7 with the nut 18 through the top plate 13. In addition, a screw part may be provided in the positioning rod 19 and a nut may be fitted to this screw part. In such a structure, the rod bolt 17 can be omitted.

  As shown in FIG. 4, a plurality of fixing grooves 7a of the filter medium 7 are provided at unequal intervals in the circumferential direction. Thereby, when the filter media 7 are stacked in an inverted state, the fixing grooves 7a of the upper and lower filter media 7 do not coincide with each other, and the positioning rod 19 cannot be fitted. Work mistakes can be prevented.

  As shown in FIGS. 4 and 5, a plurality of filtration flow path forming grooves 15 of the filter medium 7 are formed at predetermined intervals in the circumferential direction of the filter medium 7.

  The filtration flow path forming groove 15 includes an upstream groove e, a middle flow groove f, and a downstream groove g. The upstream groove e is formed at the same depth over the entire length, and the middle flow groove f has an inclination angle of 0.5 to 5 degrees. The downstream groove g is formed at the same depth over the entire length. Specifically, the length of the upstream groove e is set to 2 mm, the length of the midstream groove f (horizontal direction) is set to 2.5 mm, and the length of the downstream groove g is set to 2.5 mm. The channel width is set to about 1 mm. The width dimension which is the difference between the outer radius and the inner radius of the filter medium 7 is 7 mm, and the thickness d of the filter medium 7 is formed to be 0.2 to 0.4 mm. Such a filter medium 7 is formed by pressing or the like.

  As shown in FIG. 5, the filtration flow path 16 includes an upstream portion E, a middle flow portion F, and a downstream portion G corresponding to the upstream groove e, the middle flow groove f, and the downstream groove g of the filtration flow path forming groove 15. The upstream portion E and the downstream portion G are formed with the same flow path height over the entire length, and the midstream portion F is formed so that the flow path height increases toward the downstream side. Moreover, the corner | angular part of the filter material which forms the inflow port 3 of raw | natural water is not a round but a sharp shape.

4). Control means The control means C controls the apparatus so as to cope with normal operation and high load operation such as an increase in SS concentration.

  That is, during normal operation, regular backwashing (normal backwashing) is performed, and during high load operation, normal backwashing cannot remove clogging of the filter element 6 and the filter element 6 is completely removed. Since filtration becomes impossible when clogged, the control is performed so as to eliminate clogging of the filter element 6.

  The control means C is a butterfly valve (an example of a control valve) C1 that controls the outflow of filtrate water from the filtrate water chamber 12, a detection means C2, and a fresh water supply means that supplies fresh water for forced backwashing to the filtrate water chamber 12. C3 and a control unit C4 that controls the butterfly valve C1 and the fresh water supply means C3.

  The butterfly valve C1 is disposed at the filtrate outlet of the filtrate chamber 12 and is driven by a control damper motor (CDM) C11 to adjust the flow rate of the filtrate.

Detecting means C2 is, the differential pressure ΔP between the pressure _{P 2} of the raw water chamber 11 and the pressure provided in the filtration water chamber 12 meter C42, equipped with a C41, raw water chamber pressure _{P 1} and the filtered water chamber 12 of 11 ( A detection signal is output when P ₁ -P ₂ ) reaches a first reference value, and a detection signal is also output when a second reference value greater than the first reference value is reached. Yes.

The detection unit C2 is provided with a pressure gauge C43 for measuring the outlet pressure _{P 4} of the opposite ball valve of wash pipe 21 (drain valve) C7.

  The fresh water supply means C3 includes a supply path C31 for supplying fresh water from a fresh water source (not shown) to the filtrate water chamber 12, a ball valve C32 provided in the supply path C31, and a cleaning motor (CM) C33 for driving the ball valve C32. I have.

5. Next, the first control method and the second control method will be described.

A. 1st control method A 1st control method performs backwash control by the following operation modes 1-4 according to the grade of the density | concentration of SS, and the clogging state of the filtration element 6. FIG.

(1) Operation mode 1
When the differential pressure ΔP does not reach the first reference value, in the regular backwash mode of the operation mode 1, normal backwash (the control valve is fully opened) is performed at regular intervals to reduce the differential pressure ΔP. Filter in good condition.

(2) Operation mode 2
When the differential pressure ΔP reaches the first reference value without decreasing the differential pressure ΔP, the operation mode 2 is set to the irregular backwash mode, and the backwash time is set longer than the regular backwash mode of the operation mode 1. The pressure difference ΔP is decreased by increasing the pressure (the control valve is fully opened). When the differential pressure ΔP falls below the return reference value that is smaller than the first reference value, the operation mode 1 is returned to the periodic backwash mode. Specifically, the backwash time in the operation mode 2 is necessary for the pressure difference ΔP to be lower than the first reference value by a certain value during the time required to reduce the pressure difference ΔP to the first reference value. It is the time after adding a certain time.

(3) Operation mode 3
When the differential pressure ΔP does not recover even in the operation mode 2 and the differential pressure ΔP reaches the second reference value larger than the first reference value, the opening of the butterfly valve C1 is adjusted to adjust the inside of the filtered water chamber 12 Turning to the operation mode 3 to increase the pressure P _2.

  As a result, when the differential pressure ΔP recovers and falls below the return reference value, the operation mode 1 is returned to the periodic backwash mode.

  On the other hand, if the differential pressure ΔP does not recover even after adjusting the butterfly valve C1, the operation proceeds to the forced cleaning mode of the next operation mode 4.

(4) Operation mode 4
In the forced washing mode of the operation mode 4, with the butterfly valve C1 fully closed, fresh water is supplied to the filtered water chamber 12 by the fresh water supply means C3 and backwashing with fresh water is performed for a certain period of time.

  Thereafter, the supply of fresh water is stopped, the opening of the butterfly valve C1 is adjusted, and if the differential pressure ΔP falls below the return reference value, the operation mode 1 is returned to the periodic backwash mode.

  In this way, stable filtration can be continued even when the SS concentration is high. The first reference value and the second reference value are appropriately determined in consideration of the design conditions of the device, the safety level, and the like.

  It is also possible to adopt a control method in which the operation mode 2 is omitted and the operation mode 1 is immediately shifted to the operation mode 3.

  In FIG. 1, C6 is a flow meter provided on the downstream side of the butterfly valve C1, C7 is a ball valve of the backwash pipe 21 for backwash water, C71 is a backwash motor (BWM) for driving the ball valve C7, and C8 is A ball valve C81 of the drain pipe 24 is a drain motor (DM) for driving the ball valve C8. The backwash motor C71 is linked to the motor 9 and discharges backwash water from the backwash pipe 21 during backwashing. The drain motor C81 opens the ball valve C8 for a predetermined time after the end of backwashing, and discharges dirt accumulated on the bottom of the raw water chamber 11.

The flow rate control of filtered water discharged from the filtration water chamber 12 is effected simply by measuring the pressure P ₃ of the filtered water downstream of the butterfly valve C1 by the pressure gauge C5. Further, the flow rate Q of the filtrate water is calculated using a known formula indicating the relationship between Q, Cv value, G (specific gravity of the filtrate water), and ΔP _D (pressure loss of the butterfly valve C1).

B. Second Control Method The second control method is a method of adding a backwash start preparation mode when the outlet pressure acting as a back pressure is generated as described above.

Backwash start preparation mode, the pressure of the filtered water chamber and P _2, the ball valve (drain valve) the outlet pressure of the C7 and P _4, the backwash water required to perform the pipe resistance and backwashing efficiently When the drain pressure is α, the butterfly valve C1 is controlled so that the relationship of P ₄ + α ≦ P ₂ is established.

When P ₂ ≦ P ₄ + α, the butterfly valve C1 is moved in the closing direction, and when P ₂ > P ₄ + α, the backwash operation is performed based on the first control method. The outlet pressure should not act as a counter pressure.

6). Other Forms of Filter Material FIG. 6 is a perspective view showing a part of another example of the filtration element of the backwashing type filtration apparatus according to the embodiment of the present invention. As shown in FIG. 6, the filter medium 7 is formed so that the outer thickness is thinner than the inner thickness over the entire circumference. The upper surface of the filter medium 7 is inclined so as to become lower toward the downstream side at a predetermined inclination angle, and a cylindrical spacer 7b that can be easily manufactured and has a large aperture ratio is uniformly formed on the upper surface. A large number are formed at predetermined intervals. Moreover, the lower surface of the filter medium 7 is formed in a smooth horizontal plane.

  As still another example of the filtration element 6, a mode in which each filter medium 7 is formed in a truncated cone shape instead of a flat plate shape as described above can be considered. According to such an aspect, it is possible to prevent a mistake in the stacking operation in which the filter media 7 are stacked in an inverted state even if the fixing grooves 7a are not equally spaced in the circumferential direction as described above.

  Then, by laminating the filter media 7, a filter channel 16 is formed in which the channel height increases toward the downstream side due to the presence of the spacer 7 b of the lower filter media 7.

7). Advantages of the present invention (1) Effects relating to the control means (a) When the differential pressure ΔP reaches the first reference value, the filtration element 6 is washed with a longer backwash time than the normal backwash. The clogging of the element 6 can be eliminated.

  (B) Further, when the high load operation increases the degree of clogging of the filtration element 6 and the differential pressure ΔP reaches the second reference value exceeding the first reference value, the butterfly valve C1 causes the filtered water chamber 12 to flow. Therefore, the differential pressure ΔP can be recovered. For this reason, filtration can be performed stably even under conditions of high load operation.

  (C) Furthermore, when the differential pressure ΔP does not recover even by the butterfly valve C1, it is possible to recover the predetermined differential pressure ΔP by using fresh water as backwash water. For this reason, even when the filtration element 6 is completely clogged, the differential pressure ΔP can be recovered.

Therefore, according to the present embodiment, for example, it is used for primary filtration of ballast seawater, the SS size is 50 μm or more, the number per 1 m ³ is 10 ⁵ , and the maximum is 10 ⁷ (plankton abnormality) It is possible to cope with the case where the filtration accuracy is set to a high value of 50 μm under the condition of (when generated).

  (D) Before starting the backwash operation mode, the pressure in the filtrate water chamber is set in consideration of the relationship between the outlet pressure, the pipe resistance, and the drainage pressure of the backwash water necessary for performing the backwash efficiently. Therefore, the problem of the outlet pressure acting as a counter pressure can also be solved.

(2) Effects related to the filtration element (a) Since the flow path height outside the inside of the filtration element 6 is configured to be higher, it is possible to efficiently capture microorganisms and filter raw water during filtration. During backwashing, it can be backwashed efficiently.

  (B) Moreover, the upstream part E is formed in the same small flow path height over the full length among the filtration flow paths 16 of the filtration element 6, and the middle flow part F is such that the flow path height increases toward the downstream side. Since the downstream side is formed so that the flow path height does not become smaller than that of the midstream side, at the time of filtration, microorganisms and the like are captured at the inlet of the upstream portion E having a small flow path height, and raw water is filtered. The pressure loss can be reduced by the presence of the downstream portion G. Then, due to the presence of the midstream portion F, the pressure loss can be gradually and smoothly reduced. For this reason, the throughput of raw | natural water can be improved, performing sufficient filtration smoothly.

  (C) At the time of backwashing, the filtered water flowing into the filtration flow path 16 from the outside of the filtration element 6 is accelerated in the upstream portion E, and therefore hits microorganisms etc. clogged at the inlet of the upstream portion E. A large impact force can be given to microorganisms and the like. For this reason, microorganisms and the like clogged at the inlet of the upstream portion E can be efficiently removed.

  (D) In addition, the inclination angle of the bottom surface of the filtration flow path forming groove 15 corresponding to the midstream portion F needs to be an appropriate angle in order to suppress a loss that is disadvantageous in improving the throughput. In the present invention, since the inclination angle of the bottom surface of the filtration flow path forming groove 15 is 0.5 to 5 degrees which is an appropriate angle, it is possible to suppress a loss that is disadvantageous in improving the throughput. In addition, it is more preferable that the inclination angle of the bottom surface of the filtration flow path forming groove 15 is 0.5 to 2 degrees.

  (E) Since the flow path height of the upstream portion E captures microorganisms and the like at the inlet of the upstream portion E, it cannot be larger than a certain height. In the present invention, the flow path height of the upstream portion E is set to 100 μm or less, so that microorganisms and the like can be captured appropriately. On the other hand, since it is set to 10 μm or more, the inflow of raw water to the upstream portion E is not excessively restricted.

  (F) Moreover, since the flow path length of the upstream part E is set to 30% or less with respect to the full length of the filtration flow path, the upstream part E whose flow path height is lower than that of the midstream part F and the downstream part G. Can be sufficiently suppressed. Moreover, since the flow path length of the upstream part E is set to 5% or more with respect to the full length of the filtration flow path 16, there is no trouble in the production of the filtration flow path forming groove 15 and the like.

  (G) Since the corners of the filter medium forming the raw water inflow port have a sharp shape rather than a large radius, microorganisms and the like are hardly clogged at the inflow port.

  As mentioned above, although this invention was demonstrated based on embodiment, this invention is not limited to said embodiment. Various modifications can be made to the above-described embodiment within the same and equivalent scope as the present invention.

DESCRIPTION OF SYMBOLS 1 Backwash type filtration apparatus 2 Pressure vessel 3 Raw water inflow port 4 Filtrated water outflow port 5 Partition plate 6 Filtration element 7 Filter material 7a Fixing groove 7b Spacer 8 Backwashing means 9 Motor 10 Opening part 11 Raw water chamber 12 Filtration water chamber 13 Top plate 13a Mounting hole 14 Bottom opening 15 Filtration channel forming groove 16 Filtration channel 17 Rod bolt 18 Nut 19 Positioning rod 20a, 20b Backwash nozzle 21 Backwash tube 21a, 21b Branch tube 22 Rotating shaft 24 Drain tube 210 Rotating pipe 211 Fixed pipe C Control means C1 Butterfly valve (control valve)
C2 Detection means C3 Fresh water supply means C4 Control units C5, C41, C42, C43 Pressure gauge C6 Flow meters C7, C8, C32 Ball valve C11 Control damper motor C31 Supply path C33 Cleaning motor C71 Drain motor C81 Drain motor E Upstream F Middle stream part G Downstream part d Filter material thickness e Upstream groove f Middle stream groove g Downstream groove P ₁ Pressure in raw water chamber P ₂ Pressure in filtered water chamber P ₄ Outlet pressure of ball valve (drain valve)

Claims (1)

A pressure vessel having a raw water chamber and a filtrate water chamber, a cylindrical filtration element disposed in the pressure vessel, and a control means are provided, and the raw water is passed from the inside to the outside of the filtration element for filtration. And a backwash type filtration device for washing the filtration element by flowing the filtered water back,
The filtration element is configured by laminating a disk-type filter medium in which a filtration channel forming groove is formed in the radial direction, and forming a filtration channel between the upper and lower filter media,
The flow path height of the filtration flow path is configured such that the downstream side is higher than the upstream side,
The control means includes
A control valve for controlling the outflow of the filtrate from the filtrate chamber;
Detecting means for detecting a differential pressure between the pressure in the filtered water chamber and the pressure in the raw water chamber;
A control unit for controlling the control valve by a detection signal of the detection means,
When the differential pressure does not reach the first reference value, the operation is performed in the operation mode 1 in which the filtration element is washed with a predetermined backwash time,
When the differential pressure reaches the first reference value, after operating in the operation mode 2 for cleaning the filtration element in a time longer than the predetermined backwash time, return to the operation mode 1,
When the differential pressure reaches a second reference value that is greater than the first reference value, the control valve is controlled based on the detection signal of the detection means to increase the pressure in the filtered water chamber. A backwashing type filtration apparatus, wherein after the operation in the operation mode 3 for cleaning the filtration element, the operation mode 1 is restored.

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