JP2014104403A - Pure water producing apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a pure water producing apparatus capable of saving power in the operation of a pressure pump.SOLUTION: In a pure water producing apparatus 1, when a ratio of the flow rate of concentrated water W3 and W5 to the flow rate of permeated water W2 and W4 separated by reverse osmosis membrane modules 11 and 12 is defined as a circulation ratio in the reverse osmosis membrane modules 11 and 12, at least one of the flow rate of supply water W1, the flow rate of permeated water W2 and W4 and the flow rate of concentrated water W3 and W5 is set so that a ratio R2/R1 of a circulation ratio R2 in the reverse osmosis membrane module 12 at the final stage of a plurality of reverse osmosis membrane modules to a circulation ratio R1 in the reverse osmosis membrane module 11 at the forefront stage of a plurality of reverse osmosis membrane modules is in the range of 0.08≤R2/R1≤0.12.

Description

  The present invention relates to a pure water production apparatus including a reverse osmosis membrane module that separates permeate from supply water, and an electrodeionization stack that demineralizes the permeate to obtain demineralized water.

  In semiconductor manufacturing processes, electronic component cleaning, medical instrument cleaning, and the like, high-purity pure water that does not contain impurities is used. When manufacturing this kind of pure water, a pure water manufacturing apparatus may be used. As pure water production equipment, reverse osmosis membrane module (hereinafter also referred to as “RO membrane module”) that separates permeate from feed water, and permeate separated by reverse osmosis membrane module is desalted to obtain demineralized water. An electrodeionization stack to be obtained (hereinafter also referred to as “EDI stack”) is known (see, for example, Patent Document 1). In such a pure water production apparatus, in general, raw water such as ground water and tap water is treated in a multi-stage with an RO membrane module using a reverse osmosis membrane, so that most of the dissolved salts are removed from the raw water. Isolate. Thereafter, the purity is further increased by purifying the permeate with an EDI stack.

JP 2001-259376 A

  By the way, in the RO membrane module using the spiral type element, in order to prevent the membrane surface from being blocked by an organic component or a suspended substance, a separation operation by a cross flow method is usually employed. In this cross-flow method, a separation operation is performed by applying a pressure higher than the osmotic pressure of the feed water to the primary side of the membrane while circulating the feed water at a flow rate more than 5 times the flow rate of the permeated water by a pressure pump. I do. At this time, since the supply water flowing out from the RO membrane module is concentrated water, the circulation ratio defined by the ratio of the flow rate of the concentrated water to the flow rate of the permeated water is maintained at 5 or more.

  In the multi-stage processing of the RO membrane module, in order to maintain the circulation ratio of each stage at 5 or more, it is necessary to provide a pressure pump with a very large discharge amount and discharge pressure. Power consumption is large because a large-capacity motor is driven. Here, the condition of the circulation ratio described above is set on the assumption that the suspended water is contained in the supply water. Therefore, if the permeated water obtained in the upstream RO membrane module is clean, the downstream RO membrane module can reduce the circulation ratio, and consequently suppress the power consumption of the pressure pump. . This invention is made | formed in view of such a situation, and it aims at providing the pure water manufacturing apparatus which can aim at energy saving in operation | movement of a pressurization pump.

  The present invention provides a plurality of reverse osmosis membrane modules for separating supplied water into permeated water and concentrated water, and the permeated water separated by one reverse osmosis membrane module is condensed with the permeated water by another reverse osmosis membrane module. A plurality of reverse osmosis membrane modules connected in series so as to be separable from water, and a pressure pump for discharging supply water toward the forefront of the plurality of reverse osmosis membrane modules connected in series, A circulation ratio R1 in the reverse osmosis membrane module located in the foremost stage when a ratio of the flow rate of the concentrated water to the flow rate of the permeated water separated by the reverse osmosis membrane module is defined as a circulation ratio in the reverse osmosis membrane module. The flow rate and the permeation rate of the feed water so that the ratio R2 / R1 of the circulation ratio R2 in the reverse osmosis membrane module located at the last stage is in the range of 0.08 ≦ R2 / R1 ≦ 0.12. Flow rate, and to at least pure water production system in which one is set among the flow rate of the concentrated water.

  Moreover, it is preferable to provide an electrodeionization stack that obtains demineralized water by desalting the permeated water from the plurality of reverse osmosis membrane modules.

  ADVANTAGE OF THE INVENTION According to this invention, the pure water manufacturing apparatus which can aim at energy saving in operation | movement of a pressurization pump can be provided.

It is a whole block diagram of the pure water manufacturing apparatus 1 which concerns on one Embodiment.

  The pure water manufacturing apparatus 1 which concerns on one Embodiment of this invention is demonstrated referring drawings. FIG. 1 is an overall configuration diagram of a pure water production apparatus 1 according to an embodiment. The pure water production apparatus 1 is applied to, for example, a pure water production apparatus that produces demineralized water from raw water (for example, tap water). The desalted water produced by the pure water production apparatus is sent as pure water to a demand location or the like. In the pure water production apparatus, supplying pure water to a demand point or the like is also referred to as “water sampling”.

  As shown in FIG. 1, the pure water production apparatus 1 includes an activated carbon filter 2, a safety filter 3, a raw water tank 4 as a supply water storage tank, a pressurizing pump 5, an inverter 6, and a reverse osmosis membrane module. The first RO membrane module 11 and the second RO membrane module 12, the EDI stack 20 as an electrodeionization stack, a control unit 30, a notification unit 31, an input operation unit 32, and a DC power supply device 33.

  The pure water production apparatus 1 includes a raw water replenishment valve 61, a first flow path switching valve 62, a second flow path switching valve 63, a third flow path switching valve 64, a desalted water return valve 65, 1 RO valve 101 to 4 RO valve 104, 1st EDI valve 201 to 6th EDI valve 206, water level sensor 41, in-tank electrical conductivity sensor 42, in-tank temperature sensor 43, and 1st electrical conductivity sensor 51 The pressure sensor 52, the first flow sensor 53, the second flow sensor 54, the second electrical conductivity sensor 55, the third flow sensor 56, the fourth flow sensor 57, and the first raw water pressure sensor 581 , A concentrated water pressure sensor 582, a second raw water pressure sensor 583, a first concentrated water flow sensor 591, a second concentrated water flow sensor 592, and a third concentrated water flow sensor 593.

  In FIG. 1, the electrical connection path is omitted, but the control unit 30 performs the raw water supply valve 61, the first flow path switching valve 62, the second flow path switching valve 63, the water level sensor 41, and the electric conductivity in the tank. Sensor 42, tank internal temperature sensor 43, first electrical conductivity sensor 51, second electrical conductivity sensor 55, pressure sensor 52, first flow sensor 53, second flow sensor 54, third flow sensor 56, fourth flow rate The sensor 57, the first raw water pressure sensor 581, the concentrated water pressure sensor 582, the second raw water pressure sensor 583, the first concentrated water flow sensor 591, the second concentrated water flow sensor 592, and the third concentrated water flow sensor 593 are electrically connected. Connected. Moreover, in this embodiment, the 3rd flow-path switching valve 64, the desalted water return valve 65, the 1st RO valve 101-the 4th RO valve 104, and the 1st EDI valve 201-the 6th EDI valve 206 switch an open / close state by manual operation. Or the valve opening degree can be adjusted.

  In addition, the pure water production apparatus 1 includes the raw water line L1, the first permeate water line L2, the second permeate water line L3, the first RO concentrated water return line L5, the first RO concentrated water discharge line L41, and the second RO. Concentrated water return line L6, second RO permeated water return line L7, second RO permeated water discharge line L42, desalted water line L8, desalted water return line L9, EDI concentrated water return line L10, and EDI concentrated water discharged A line L43 and an EDI electrode water discharge line L44. The “line” in the present specification is a general term for lines capable of flowing a fluid such as a flow path, a radial path, and a pipeline.

  Raw water W1 (supply water) flows through the raw water line L1. The raw water line L1 is a line through which the raw water W1 is circulated to the first RO membrane module 11. The raw water line L1 includes a first raw water line L11 and a second raw water line L12.

  The first raw water line L11 is a line connecting a supply source (not shown) of the raw water W1 and the raw water tank 4. The upstream end of the first raw water line L11 is connected to a supply source (not shown) of the raw water W1. Further, the downstream end of the first raw water line L <b> 11 is connected to the raw water tank 4.

  In the first raw water line L11, a raw water supply valve 61, a first raw water pressure sensor 581, an activated carbon filter 2, a safety filter 3, and a raw water tank 4 are provided in order from the upstream side. The raw water supply valve 61 is a valve capable of opening and closing the first raw water line L11. The raw water supply valve 61 is electrically connected to the control unit 30. The opening / closing operation of the raw water supply valve 61 is controlled by a flow path opening / closing signal from the control unit 30.

The activated carbon filter 2 is a device that removes a chlorine component (mainly free chlorine) contained in the raw water W1. The activated carbon filter 2 has a filter medium bed made of activated carbon in a pressure tank. The activated carbon filter 2 purifies the raw water W1 by decomposing and removing chlorine components contained in the raw water W1, and adsorbing and removing organic components and capturing suspended substances. The activated carbon filter 2 reliably removes organic components and suspended solids that cause clogging of the membrane surface in the RO membrane module, which will be described later. Therefore, the height H of the filter media bed is in the range of 250 mm ≦ H ≦ 1000 mm. Is set. For the same reason, the space velocity SV (Space Velocity) of the raw water W1 in the filtration operation is set in a range of 50h ⁻¹ ≦ SV ≦ 60h ⁻¹ .

  The safety filter 3 is a filter that removes fine particles contained in the raw water W1 filtered by the activated carbon filter 2. The safety filter 3 is configured by accommodating a filter element in a housing. As the filter element, for example, a nonwoven fabric filter element or a thread wound filter element having a filtration accuracy of 1 to 50 μm is used. The raw water tank 4 is a tank that stores raw water W1 purified through the activated carbon filter 2 and the safety filter 3 as supply water and supplies the raw water W1 to the pressurizing pump 5.

  Here, the raw water W1 supplied to the activated carbon filter 2 satisfies the water quality standard specified in the “Ministerial Ordinance on Water Quality Standards” (May 30, 2003 Ministry of Health, Labor and Welfare No. 101) based on Article 4 of the Water Supply Law. It is desirable that In tap water that satisfies such water quality standards, organic matter (TOC amount), turbidity, and the like are suppressed to a predetermined value or less in advance. Therefore, the tap water purified through the activated carbon filter 2 and the safety filter 3 contains almost no organic components or suspended substances, and it is difficult for the RO membrane module to block the membrane surface.

  The second raw water line L12 is a line connecting the raw water tank 4 and the first RO membrane module 11. The upstream end of the second raw water line L12 is connected to the raw water tank 4. Further, the downstream end of the second raw water line L12 is connected to the primary inlet port (the inlet of the raw water W1) of the first RO membrane module 11. The second raw water line L12 circulates raw water W1 as supply water to the first RO membrane module 11.

  In the second raw water line L12, the pressurizing pump 5, the first RO valve 101, the second raw water pressure sensor 583, and the first RO membrane module 11 are provided in this order from the upstream side. The first RO valve 101 is provided between the pressurizing pump 5 and the first RO membrane module 11 in the second raw water line L12. The first RO valve 101 is a valve capable of adjusting the flow rate of the raw water W1 flowing through the second raw water line L12.

  The pressurizing pump 5 is a device that sucks raw water W1 as supply water flowing through the second raw water line L12, discharges the raw water W1 toward the first RO membrane module 11, and pumps it. Driving power having a converted frequency (or voltage) is supplied from the inverter 6 to the pressurizing pump 5. The pressurizing pump 5 is driven at a rotational speed corresponding to the supplied drive power frequency (hereinafter also referred to as “drive frequency”) or the drive power voltage (hereinafter also referred to as “drive voltage”).

  The inverter 6 is an electric circuit (or a device having the circuit) that supplies driving power whose frequency is converted to the pressure pump 5. The inverter 6 is electrically connected to the control unit 30. A command signal is input to the inverter 6 from the control unit 30. The inverter 6 drives the pressurization pump 5 by outputting the drive power of the drive frequency (or drive voltage) corresponding to the command signal (current value signal or voltage value signal) input by the control unit 30 to the pressurization pump 5. To do. That is, the control unit 30 can control the drive frequency or drive voltage output from the inverter 6.

  The first RO membrane module 11 as the reverse osmosis membrane module in the foremost stage is composed of the raw water W1 pumped by the pressurizing pump 5, the first permeated water W2 from which dissolved salts are removed, and the first concentration in which dissolved salts are concentrated. Separated into water W3. The first RO membrane module 11 is configured by accommodating a single or a plurality of spiral RO membrane elements in a pressure vessel (vessel). Examples of the RO membrane used in the RO membrane element include a crosslinked aromatic polyamide composite membrane. Examples of RO membrane elements composed of a crosslinked aromatic polyamide composite membrane include: Toray Industries, Inc .: model name “TMG20-400”, Eunjin Chemical Co., Ltd .: model name: “RE8040-BLF”, Nitto Denko Corporation: model name: “ESPA1” Are commercially available, and these elements can be suitably used.

  The first RO concentrated water return line L5 is a line for circulating a part of the first concentrated water W3 separated by the first RO membrane module 11 to the raw water tank 4 and returning it. The first RO concentrated water return line L5 includes an upstream first RO concentrated water return line L51 and a downstream first RO concentrated water return line L52.

  The upstream end of the upstream first RO concentrated water return line L51 is connected to the primary outlet port (the outlet of the first concentrated water W3) of the first RO membrane module 11. The downstream end of the upstream first RO concentrated water return line L51 is branched into a downstream first RO concentrated water return line L52 and a first RO concentrated water discharge line L41 at a branch portion J11.

  The upstream end of the downstream first RO concentrated water return line L52 is connected to the branch portion J11. The downstream end of the downstream first RO concentrated water return line L52 is connected to the raw water tank 4. A second RO valve 102 is provided in the downstream first RO concentrated water return line L52. The 2nd RO valve 102 is a valve which can adjust the flow volume of the 1st concentrated water W3 which distribute | circulates the downstream 1st RO concentrated water return line L52.

  The 1st RO concentrated water discharge line L41 is a line which distribute | circulates so that the remainder of the 1st concentrated water W3 isolate | separated by the 1st RO membrane module 11 may be discharged | emitted out of the apparatus from the middle of the 1st RO concentrated water return line L5. . The upstream end of the first RO concentrated water discharge line L41 is connected to the branch portion J11. The downstream side of the first RO concentrated water discharge line L41 is connected or opened to a drain pit (not shown), for example. The first RO concentrated water discharge line L41 is provided with a third RO valve 103. The third RO valve 103 is a valve capable of adjusting the drainage flow rate of the first concentrated water W3 discharged out of the apparatus via the first RO concentrated water discharge line L41.

  The first permeate line L2 connects the first RO membrane module 11 and the second RO membrane module 12 in series, and distributes the first permeate W2 separated by the first RO membrane module 11 to the second RO membrane module 12. It is. The upstream end of the first permeate line L2 is connected to the secondary port (the outlet of the first permeate W2) of the first RO membrane module 11. The downstream end of the first permeate line L2 is connected to the primary inlet port (the inlet of the first permeate W2) of the second RO membrane module 12.

  The second RO membrane module 12 as the reverse osmosis membrane module in the last stage is obtained by dissolving the first permeated water W2 separated by the first RO membrane module 11 and pumped by the pressure pump 5 from the first permeated water W2. It isolate | separates into the removed 2nd permeated water W4 and the 2nd concentrated water W5 in which the dissolved salt was concentrated. The second RO membrane module 12 is configured by accommodating a single or a plurality of spiral RO membrane elements in a pressure vessel (vessel). In the first RO membrane module 11, the same RO membrane element as that of the second RO membrane module 12 can be used.

  The second RO concentrated water return line L6 is a line through which the second concentrated water W5 separated by the second RO membrane module 12 is circulated to the raw water tank 4 and returned. The upstream end of the second RO concentrated water return line L6 is connected to the primary outlet port (the outlet of the second concentrated water W5) of the second RO membrane module 12. The downstream end of the second RO concentrated water return line L6 is connected to the raw water tank 4. A fourth RO valve 104 is provided in the second RO concentrated water return line L6. The fourth RO valve 104 is a valve capable of adjusting the flow rate of the second concentrated water W5 flowing through the second RO concentrated water return line L6.

  The second permeated water line L3 is a line through which the second permeated water W4 separated by the second RO membrane module 12 flows through the EDI stack 20. The second permeate line L3 includes a front-stage permeate line L31, a middle-stage permeate line L32, a desalting chamber inflow line L321, a concentration chamber inflow line L322, and an electrode chamber inflow line L323.

  The upstream end of the front-stage permeate line L31 is connected to the secondary port (the outlet of the second permeate W4) of the second RO membrane module 12. The downstream end of the front-stage permeate line L31 is connected to the middle-stage permeate line L32 and the second RO permeate return line L7 via the first flow path switching valve 62.

  The first flow path switching valve 62 allows the second permeated water W4 separated by the second RO membrane module 12 to flow toward the EDI stack 20 via the middle-stage permeated water line L32 (water sampling side flow path). ) Or a valve that can be switched to a flow path (circulation side flow path and drain side flow path) that flows toward the third flow path switching valve 64 via the second RO permeate return line L7. The first flow path switching valve 62 is configured by, for example, an electric or electromagnetic three-way valve. The first flow path switching valve 62 is electrically connected to the control unit 30. The switching of the flow path in the first flow path switching valve 62 is controlled by a flow path switching signal from the control unit 30.

  The second RO permeated water return line L7 is a line for returning the second permeated water W4 separated by the second RO membrane module 12 to the raw water tank 4 on the upstream side of the first RO membrane module 11. The second RO permeate return line L7 includes an upstream second RO permeate return line L71 and a downstream second RO permeate return line L72.

  The upstream end of the upstream second RO permeate return line L71 is connected to the first flow path switching valve 62. The downstream end of the upstream second RO permeate return line L71 is connected to the third flow path switching valve 64.

  The third flow path switching valve 64 allows the second permeated water W4 flowing through the upstream second RO permeate return line L71 to flow toward the raw water tank 4 via the downstream second RO permeate return line L72. This is a valve that can be switched to a channel (circulation side channel) or a channel (drainage side channel) that circulates so as to be discharged to the outside of the apparatus via the second RO permeated water discharge line L42. The third flow path switching valve 64 is a valve that can be manually switched between open and closed states.

  The upstream end of the downstream second RO permeate return line L72 is connected to the third flow path switching valve 64. The downstream end of the downstream second RO permeate return line L72 is connected to the raw water tank 4.

  The second RO permeate discharge line L42 is a line through which the second permeate W4 separated by the second RO membrane module 12 joins the second RO permeate return line L7 and is discharged out of the apparatus. The upstream end of the second RO permeate discharge line L42 is connected to the third flow path switching valve 64. The downstream side of the third flow path switching valve 64 is connected or opened to a drainage pit (not shown), for example.

  The second RO permeated water discharge line L42 is joined to the first RO concentrated water discharge line L41 at the connection portion J12. The connection part J12 is arrange | positioned rather than the 3rd RO valve 103 in the 1st RO concentrated water discharge line L41. The portion of the second RO permeated water discharge line L42 on the downstream side of the connection portion J12 is common to the portion of the first RO concentrated water discharge line L41 on the downstream side of the connection portion J12.

  The upstream end of the middle permeate line L32 is connected to the first flow path switching valve 62. The downstream end of the middle-stage permeate line L32 is branched into a desalting chamber inflow line L321, a concentration chamber inflow line L322, and an electrode chamber inflow line L323 at a branch portion J4.

  The downstream ends of the desalination chamber inflow line L321, the enrichment chamber inflow line L322, and the electrode chamber inflow line L323 are the primary ports of the EDI stack 20 (each inlet side of the desalination chamber 21, the concentration chamber 22, and the electrode chamber 23). )It is connected to the.

  The EDI stack 20 is a water treatment device that desalinates the second permeated water W4 separated from the first permeated water W2 by the second RO membrane module 12 to obtain desalted water W6, concentrated water W7, and electrode water W8. is there. The EDI stack 20 is electrically connected to the DC power supply device 33. A DC voltage is input from the DC power supply device 33 to the EDI stack 20. The EDI stack 20 is energized and operated by the DC voltage input from the DC power supply device 33.

  The DC power supply device 33 applies a DC voltage between the pair of electrodes of the EDI stack 20. The DC power supply device 33 is electrically connected to the control unit 30. The DC power supply device 33 outputs a DC voltage to the EDI stack 20 in response to the command signal input by the control unit 30.

  In the EDI stack 20, a cation exchange membrane and an anion exchange membrane (not shown) are alternately arranged between a pair of electrodes. The inside of the EDI stack 20 is partitioned into a desalting chamber 21, a concentration chamber 22, and an electrode chamber 23 by these ion exchange membranes. The desalting chamber 21 is filled with an ion exchanger (not shown). As the ion exchanger filled in the desalting chamber 21, for example, an ion exchange resin, an ion exchange fiber, or the like is used. In FIG. 1, a plurality of desalting chambers 21, concentration chambers 22, and electrode chambers 23 partitioned inside the EDI stack 20 are schematically shown.

  A desalting chamber inflow line L321 through which the second permeated water W4 flows is connected to the inlet side of the desalting chamber 21. On the outlet side of the desalting chamber 21, a desalting water line L <b> 8 through which the desalted water W <b> 6 discharged from the desalting chamber 21 is removed is connected. A concentrating chamber inflow line L322 through which the second permeated water W4 flows is connected to the inlet side of the concentrating chamber 22. An EDI concentrated water return line L10 that circulates the concentrated water W7 that has been concentrated and discharged is connected to the outlet side of the concentration chamber 22. An electrode chamber inflow line L323 through which the second permeated water W4 flows is connected to the inlet side of the electrode chamber 23. An electrode water discharge line L44 through which the electrode water W8 flows is connected to the outlet side of the electrode chamber 23.

  A first EDI valve 201 is provided in the desalination chamber inflow line L321. A second EDI valve 202 is provided in the concentration chamber inflow line L322. A third EDI valve 202 is provided in the electrode chamber inflow line L323. The first EDI valve 201 is a valve capable of adjusting the flow rate of the second permeated water W4 flowing through the demineralization chamber inflow line L321 (that is, the flow rate of the demineralized water W6 flowing through the demineralization chamber 21). The second EDI valve 202 is a valve capable of adjusting the flow rate of the second permeated water W4 flowing through the concentration chamber inflow line L322 (that is, the flow rate of the concentrated water W7 flowing through the concentration chamber 22). The third EDI valve 203 is a valve capable of adjusting the flow rate of the second permeated water W4 flowing through the electrode chamber inflow line L323 (that is, the flow rate of the electrode water W8 flowing through the electrode chamber 23).

  The second permeated water W4 flowing through the second permeated water line L3 flows into each of the desalting chamber 21, the concentration chamber 22, and the electrode chamber 23. Residual ions contained in the second permeated water W4 are captured by an ion exchanger (not shown) filled in the desalting chamber 21 to become desalted water W6. The desalted water W6 is sent to the demand point via the desalted water line L8 (described later). Further, residual ions captured by the ion exchanger in the desalting chamber 21 move to the concentration chamber 22 by the applied electric energy. And the water containing a residual ion is discharged | emitted as the concentrated water W7 from the concentration chamber 22 via the EDI concentrated water return line L10 and the EDI concentrated water discharge line L43 (after-mentioned). The second permeated water W4 that has flowed into the electrode chamber 23 is discharged out of the apparatus as electrode water W8 from the electrode chamber 23 via the EDI electrode water discharge line L44.

  The desalted water line L8 is a line that sends the desalted water W6 obtained in the EDI stack 20 as pure water toward the demand point. The demineralized water line L8 includes an upstream demineralized water line L81 and a downstream demineralized water line L82.

  The upstream end of the upstream demineralized water line L81 is connected to the secondary port of the EDI stack 20 (the outlet side of the demineralized chamber 21). The downstream end of the upstream demineralized water line L81 is connected to the downstream demineralized water line L82 and the demineralized water return line L9 (described later) via the second flow path switching valve 63.

  The second flow path switching valve 63 is a flow path (water sampling side flow path) for sending the desalted water W6 obtained in the desalination chamber 21 of the EDI stack 20 toward the demand point via the downstream desalted water line L82. ) Or a valve that can be switched to a flow path (circulation side flow path) that circulates toward the raw water tank 4 via the desalted water return line L9. The second flow path switching valve 63 is configured by, for example, an electric or electromagnetic three-way valve. The second flow path switching valve 63 is electrically connected to the control unit 30. Switching of the flow path in the second flow path switching valve 63 is controlled by a flow path switching signal from the control unit 30.

  The second flow path switching valve 63 performs a process of sending the demineralized water W6 obtained in the EDI stack 20 from the demineralized water line L8 to the demand point by being switched to the water sampling side flow path by the control unit 30. It functions as an executable sending means.

  An upstream end portion of the downstream demineralized water line L <b> 82 is connected to the second flow path switching valve 63. The downstream end of the downstream desalted water line L82 is connected to a device or the like (not shown) at the demand point.

  The desalted water return line L9 is a line for returning the desalted water W6 obtained in the desalting chamber 21 of the EDI stack 20 to the raw water tank 4 on the upstream side of the first RO membrane module 11 from the middle of the desalted water line L8. . In the present embodiment, the upstream end of the desalted water return line L9 is connected to the second flow path switching valve 63. The downstream end of the desalted water return line L9 is connected to the raw water tank 4. The desalted water return line L <b> 9 returns the desalted water W <b> 6 obtained in the desalting chamber 21 of the EDI stack 20 to the raw water tank 4. A desalted water return valve 65 is provided in the desalted water return line L9.

  The EDI concentrated water return line L10 is a line that joins the concentrated water W7 discharged from the concentration chamber 22 of the EDI stack 20 to the desalted water return line L9 and returns it to the raw water tank 4. The upstream end of the EDI concentrated water return line L10 is connected to the secondary port of the EDI stack 20 (the outlet side of the concentration chamber 22). The downstream end of the EDI concentrated water return line L10 is connected to the raw water tank 4.

  The EDI concentrated water return line L10 is joined to the demineralized water return line L9 at the connection J13. The connecting portion J13 is disposed between the raw water tank 4 and the desalted water return valve 65 in the desalted water return line L9. The portion downstream of the connection portion J13 in the EDI concentrated water return line L10 is common to the portion from the connection portion J13 to the raw water tank 4 in the desalted water return line L9. A fifth EDI valve 205 is provided on the upstream side of the connection portion J13 in the EDI concentrated water return line L10.

  The EDI concentrated water discharge line L43 is a line through which the concentrated water W7 discharged from the concentration chamber 22 of the EDI stack 20 is circulated so as to be discharged out of the apparatus from the middle of the EDI concentrated water return line L10. The upstream end portion of the EDI concentrated water discharge line L43 is connected to the connection portion J9. The connecting portion J9 is disposed between the concentrating chamber 22 and the fifth EDI valve 205 in the EDI concentrated water return line L10. The downstream side of the EDI concentrated water discharge line L43 is connected or opened to a drain pit (not shown), for example. A sixth EDI valve 206 is provided in the EDI concentrated water discharge line L43.

  The electrode water discharge line L44 is a line through which the electrode water W8 discharged from the electrode chamber 23 of the EDI stack 20 is circulated out of the apparatus. The upstream end of the electrode water discharge line L44 is connected to the electrode chamber 23 of the EDI stack 20. The electrode water discharge line L44 is joined to the EDI concentrated water discharge line L43 at the connection portion J10. The connecting portion J10 is disposed on the downstream side of the sixth EDI valve 206 in the EDI concentrated water discharge line L43. A portion of the electrode water discharge line L44 on the downstream side of the connection portion J10 is common to a portion of the EDI concentrated water discharge line L43 on the downstream side of the connection portion J10.

  The water level sensor 41 is a device that measures the water level of the raw water W1 stored in the raw water tank 4. The water level sensor 41 is disposed on the lower side inside the raw water tank 4. Further, the water level sensor 41 is electrically connected to the control unit 30. The water level of the raw water tank 4 measured by the water level sensor 41 is transmitted to the control unit 30 as a detection signal. In the present embodiment, the water level sensor 41 is a continuous level sensor, and for example, a capacitive sensor, a pressure sensor, an ultrasonic sensor, or the like is used. FIG. 1 shows an example in which a pressure sensor is provided on the outer wall surface near the bottom of the raw water tank 4 as the water level sensor 41. The water level sensor 41 is not limited to a continuous level sensor, and may be a level switch, for example. The level switch is a preset liquid level position detector, and is configured to detect, for example, a plurality of liquid level positions. As the level switch, for example, a float type or an electrode type is used.

  The in-tank electrical conductivity sensor 42 is a device that measures the electrical conductivity of the raw water W1 stored in the raw water tank 4. The in-tank electrical conductivity sensor 42 is disposed on the lower side inside the raw water tank 4.

  The 1st electrical conductivity sensor 51 is an apparatus which measures the electrical conductivity of the 2nd permeated water W4 which distribute | circulates the 2nd permeated water line L3. The first electrical conductivity sensor 51 is connected to the second permeated water line L3 at the connection portion J1. The connection portion J1 is disposed between the second RO membrane module 12 and the first flow path switching valve 62 in the second permeated water line L3. The 2nd electrical conductivity sensor 55 is an apparatus which measures the electrical conductivity of the desalted water W6 which distribute | circulates the desalted water line L8. The second electrical conductivity sensor 55 is connected to the demineralized water line L8 at the connection portion J6. The connecting portion J6 is disposed between the EDI stack 20 and the fourth EDI valve 204 in the desalted water line L8.

  The in-tank electrical conductivity sensor 42, the first electrical conductivity sensor 51, and the second electrical conductivity sensor 55 are electrically connected to the control unit 30. The electrical conductivity of the raw water W1 measured by the in-tank electrical conductivity sensor 42, the electrical conductivity of the second permeated water W4 measured by the first electrical conductivity sensor 51, and the second electrical conductivity sensor 55 were measured. The electrical conductivity of the desalted water W6 is transmitted to the control unit 30 as a detection signal.

  The in-tank temperature sensor 43 is a device that measures the temperature of the raw water W <b> 1 as supply water stored in the raw water tank 4. The tank internal temperature sensor 43 is disposed on the lower side of the raw water tank 4. The tank internal temperature sensor 43 is electrically connected to the control unit 30. The temperature of the raw water W1 measured by the tank temperature sensor 43 is transmitted to the control unit 30 as a detection signal.

  The first flow rate sensor 53 is a device that measures the flow rate of the second permeated water W4 flowing through the second permeated water line L3. The first flow rate sensor 53 is connected to the second permeated water line L3 at the connection portion J3. The connecting portion J3 is disposed between the second RO membrane module 12 and the first flow path switching valve 62 in the second permeated water line L3. The second flow rate sensor 54 is a device that measures the flow rate of the desalted water W6 that flows through the desalted water line L8. The second flow rate sensor 54 measures the flow rate of the water flowing through the desalting chamber 21 by measuring the flow rate of the desalted water W6 flowing through the desalted water line L8. The second flow rate sensor 54 is connected to the desalted water line L8 at the connection portion J5. The connecting portion J5 is disposed between the EDI stack 20 and the fourth EDI valve 204 in the desalted water line L8.

  The third flow rate sensor 56 is a device that measures the flow rate of the second permeated water W4 flowing through the concentration chamber inflow line L322. The third flow rate sensor 56 measures the flow rate of the water flowing through the concentration chamber 22 by measuring the flow rate of the second permeated water W4 flowing through the concentration chamber inflow line L322. The third flow sensor 56 is connected to the enrichment chamber inflow line L322 at the connection portion J7. The connecting portion J7 is disposed between the EDI stack 20 and the second EDI valve 202 in the concentration chamber inflow line L322. The fourth flow rate sensor 57 is a device that measures the flow rate of the second permeated water W4 flowing through the electrode chamber inflow line L323. The fourth flow rate sensor 57 measures the flow rate of the water flowing through the electrode chamber 23 by measuring the flow rate of the second permeated water W4 flowing through the electrode chamber inflow line L323. The fourth flow rate sensor 57 is connected to the electrode chamber inflow line L323 at the connection portion J8. The connecting portion J8 is disposed between the electrode chamber 23 of the EDI stack 20 and the third EDI valve 203 in the electrode chamber inflow line L323.

  The first concentrated water flow sensor 591 is a device that measures the flow rate of the first concentrated water W3 flowing through the downstream first RO concentrated water return line L52. The first concentrated water flow sensor 591 is connected to the downstream side first RO concentrated water return line L52 at the connection portion J22. The connecting portion J22 is disposed between the second RO valve 102 in the downstream first RO concentrated water return line L52 and the raw water tank 4. The second concentrated water flow sensor 592 is a device that measures the flow rate of the first concentrated water W3 flowing through the first RO concentrated water discharge line L41. The second concentrated water flow sensor 592 is connected to the first RO concentrated water discharge line L41 at the connection portion J23. The connection part J23 is arrange | positioned between the 3rd RO valve 103 in the 1st RO concentrated water discharge line L41, and the connection part J12. The third concentrated water flow rate sensor 593 is a device that measures the flow rate of the second concentrated water W5 flowing through the second RO concentrated water return line L6. The third concentrated water flow rate sensor 593 is connected to the second RO concentrated water return line L6 at the connection portion J24. The connecting portion J24 is disposed between the fourth RO valve 104 and the second RO membrane module 12 in the second RO concentrated water return line L6.

  The first flow sensor 53, the second flow sensor 54, the third flow sensor 56, the fourth flow sensor 57, the first concentrated water flow sensor 591, the second concentrated water flow sensor 592, and the third concentrated water flow sensor 593 are: The control unit 30 is electrically connected. The flow rate of the second permeate water W4 measured by the first flow rate sensor 53, the flow rate of the desalted water W6 measured by the second flow rate sensor 54, the flow rate of the second permeate water W4 measured by the third flow rate sensor 56, 4, the flow rate of the second permeate W 4 measured by the flow sensor 57, the return flow rate of the first concentrate W 3 measured by the first concentrate flow sensor 591, and the first concentration measured by the second concentrate flow sensor 592. The discharge flow rate of the water W3 and the return flow rate of the second concentrated water W5 measured by the third concentrated water flow rate sensor 593 are transmitted to the control unit 30 as detection signals.

  The pressure sensor 52 is a device that measures the pressure of the second permeated water W4 flowing through the second permeated water line L3. The pressure sensor 52 is connected to the second permeated water line L3 at the connection portion J2. The pressure sensor 52 is electrically connected to the control unit 30. The connecting portion J2 is disposed between the second RO membrane module 12 and the first flow path switching valve 62. The pressure of the second permeated water W4 measured by the pressure sensor 52 is transmitted to the control unit 30 as a detection signal.

  The first raw water pressure sensor 581 is a device that measures the pressure of the raw water W1 flowing through the first raw water line L11. The first raw water pressure sensor 581 is connected to the first raw water line L11 at the connection portion J21. The first raw water pressure sensor 581 is electrically connected to the control unit 30. The connecting portion J21 is disposed between the raw water supply valve 61 and the activated carbon filter 2. The pressure of the raw water W1 measured by the first raw water pressure sensor 581 is transmitted to the control unit 30 as a detection signal.

  The concentrated water pressure sensor 582 is a device that measures the pressure of the first concentrated water W3 flowing through the upstream first RO concentrated water return line L51. The concentrated water pressure sensor 582 is connected to the upstream first RO concentrated water return line L51 at the connection portion J25. The concentrated water pressure sensor 582 is electrically connected to the control unit 30. The connecting part J25 is disposed between the first RO membrane module 11 and the branch part J11. The pressure of the first concentrated water W3 measured by the concentrated water pressure sensor 582 is transmitted to the control unit 30 as a detection signal.

  The second raw water pressure sensor 583 is a device that measures the pressure of the raw water W1 flowing through the second raw water line L12. In the connection part J27, it is connected to the 2nd raw | natural water line L12. The second raw water pressure sensor 583 is electrically connected to the control unit 30. The connecting portion J27 is disposed between the first RO valve 101 and the first RO membrane module 11. The pressure of the raw water W1 measured by the second raw water pressure sensor 583 is transmitted to the control unit 30 as a detection signal.

  The notification unit 31 notifies a predetermined alarm. The notification unit 31 is electrically connected to the control unit 30. The notification is, for example, one or more of display, sound, light emission, and the like. That is, the notification unit 31 includes one or more of a display device (liquid crystal display or the like), a buzzer, a speaker, a lamp, and the like.

  The input operation unit 32 is an input interface that receives input operations of a user or an administrator for selection related to the operation mode of the device (for example, selection of operation / stop, release of alarm, etc.) and various settings related to the operation conditions of the device. It is. The input operation unit 32 includes an operation panel that combines a display and button switches, a touch panel that directly operates on the display, and the like. The input operation unit 32 is electrically connected to the control unit 30. Information input from the input operation unit 32 is transmitted to the control unit 30.

  The control unit 30 is configured by a microprocessor (not shown) including a CPU and a memory. In the control unit 30, various programs for controlling the pure water production apparatus 1 are stored in the memory of the microprocessor. Further, the memory of the microprocessor includes, for example, threshold values for the electrical conductivity of the second permeated water W4 and the desalted water W6, and threshold values for the flow rates of the desalted water W6, the concentrated water W7, and the electrode water W8 discharged from the EDI stack 20. The data etc. are stored.

  In the control unit 30, the CPU of the microprocessor executes various controls such as display on the touch panel according to a predetermined program read from the memory. In the control unit 30, an integrated timer unit for managing time measurement and the like is incorporated in the microprocessor.

  Next, flow rate setting during operation of the pure water production apparatus 1 according to the present embodiment will be described. First, for the reverse osmosis membrane module located in the foremost stage, that is, the first RO membrane module 11, the ratio of the flow rate of the first concentrated water W3 to the flow rate of the first permeated water W2 separated by the first RO membrane module 11 is The circulation ratio R1 in the 1RO membrane module 11 is defined. For the reverse osmosis membrane module located at the last stage, that is, the second RO membrane module 12, the ratio of the flow rate of the second concentrated water W5 to the flow rate of the second permeated water W4 separated by the second RO membrane module 12 is The circulation ratio R2 in the 2RO membrane module 12 is defined.

  In addition, the reverse osmosis membrane module located in the foremost stage may be composed of a plurality of modules. That is, the module includes a plurality of modules in which the primary side of the module (the distribution side of the raw water W1 and the first concentrated water W3) is connected in series and the secondary side of the module (the distribution side of the first permeate W2) is connected in parallel. May be. In this case, the circulation of the reverse osmosis membrane module located in the foremost stage using the flow rates of the first permeate W2 and the first concentrated water W3 flowing out from the most downstream module where the flow velocity on the primary side membrane surface is the lowest. Define the ratio R1.

  Similarly, the reverse osmosis membrane module located at the last stage may be composed of a plurality of modules. That is, from a plurality of modules in which the primary side of the module (the distribution side of the first permeated water and the second concentrated water) is connected in series, and the secondary side of the module (the distribution side of the second permeated water W4) is connected in parallel. It may be configured. In this case, the circulation of the reverse osmosis membrane module located in the last stage is performed using the flow rates of the second permeated water W4 and the second concentrated water W5 flowing out from the most downstream module with the lowest flow velocity on the primary membrane surface. Define the ratio R2.

  Subsequently, the flow rate of the raw water W1 (feed water) and the flow rate of the first permeate water W2 so that the ratio R2 / R1 of the circulation ratio R2 to the circulation ratio R1 is in the range of 0.08 ≦ R2 / R1 ≦ 0.12. The flow rate of the first concentrated water W3, the flow rate of the second permeated water W4, and the flow rate of the second concentrated water W5 are set. Specifically, the first RO valve 101, the second RO are based on the detection of the flow rate by the first flow sensor 53, the first concentrated water flow sensor 591, the second concentrated water flow sensor 592, and the third concentrated water flow sensor 593. The flow rate is set by adjusting the valve 102, the third RO valve 103, and the fourth RO valve 104 and adjusting the rotational speed of the pressurizing pump 5.

For example, with this setting, the flow rate of the raw water W1 discharged to the first RO membrane module 11 is set to 6.4 m ³ / h. Further, the flow rate of the first permeate W2 separated by the first RO membrane module 11 and circulated through the second RO membrane module 12 is set to 2.0 m ³ / h. Further, the flow rate of the first concentrated water W3 separated by the first RO membrane module 11 is set to 4.4 m ³ / h. In this setting example, the circulation ratio R1 in the first RO membrane module 11 is 4.4 / 2.0 = 2.2.

On the other hand, the flow rate of the second permeate W4 separated by the second RO membrane module 12 and circulated through the EDI stack 20 is set to 1.6 m ³ / h. The flow rate of the second concentrated water W5 separated by the second RO membrane module 12 is set to 0.4 m ³ / h. In this setting example, the circulation ratio R2 in the second RO membrane module 12 is 0.4 / 1.6 = 0.25. Therefore, the value of the ratio R2 / R1 is 0.25 / 2.2 = 0.11.

  According to the pure water manufacturing apparatus 1 which concerns on this embodiment mentioned above, the following effects are show | played, for example. In the pure water manufacturing apparatus 1, the ratio of the flow rate of the first concentrated water W3 to the flow rate of the first permeated water W2 separated by the first RO membrane module 11 located in the foremost stage of the plurality of reverse osmosis membrane modules is set as the first RO membrane. It is defined as a circulation ratio R1 in the module 11. Further, the ratio of the flow rate of the second concentrated water W5 to the flow rate of the second permeated water W4 separated by the second RO membrane module 12 located at the last stage of the plurality of reverse osmosis membrane modules is determined as the circulation ratio in the second RO membrane module 12. It is defined as R2. Then, the flow rate of the raw water W1 (feed water), the flow rate of the first permeated water W2, the flow rate of the first concentrated water W3, so that the ratio R2 / R1 is in the range of 0.08 ≦ R2 / R1 ≦ 0.12. The flow rate of the second permeated water W4 and the flow rate of the second concentrated water W5 are set. For this reason, the two circulation ratios R1 and R2 are maintained at the same level by driving the pressurizing pump 5 while suppressing the circulation ratio R2 of the last stage to 8 to 12% of the circulation ratio R1 of the foremost stage. As compared with the above, the driving power of the pressurizing pump 5 can be suppressed. As a result, energy saving can be achieved when the pressure pump 5 is driven.

  In addition, the pure water production apparatus 1 includes an EDI stack 20 that desalinates the second permeated water W4 from the plurality of reverse osmosis membrane modules including the first RO membrane module 11 and the second RO membrane module 12 to obtain the desalted water W6. Prepare. For this reason, it is possible to produce pure water with higher purity while saving energy when the pressure pump 5 is driven.

  The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the above-described embodiments, and can be implemented in various forms. For example, the flow rate of the raw water W1 (supply water), the flow rate of the first permeated water W2, the flow rate of the first concentrated water W3, the flow rate of the second permeated water W4, and the flow rate of the second concentrated water W5 are as described above. It is not limited to the value of the flow rate in the form. That is, each flow rate may be set so that the ratio R2 / R1 of the circulation ratio R2 to the circulation ratio R1 is in the range of 0.08 ≦ R2 / R1 ≦ 0.12.

  In the embodiment, the raw water W1 (supply water), the flow rate of the first permeated water W2, the flow rate of the first concentrated water W3, the flow rate of the second permeated water W4, and the flow rate of the second concentrated water W5 are set simultaneously. Although the case has been described, the present invention is not limited to this. That is, not all of these five flow rates need to be set, and the raw water W1 (feed water), the flow rate of the first permeate water W2, the flow rate of the first concentrated water W3, the flow rate of the second permeate water W4, and the second concentration. At least one of the flow rates of the water W5 may be set.

  Moreover, although the pure water manufacturing apparatus 1 was provided with the EDI stack 20, it is not limited to this. The pure water production apparatus 1 may not include the EDI stack 20.

  Moreover, in embodiment, the pure water manufacturing apparatus 1 has the structure by which the 1st RO membrane module 11 and the 2nd RO membrane module 12 are arrange | positioned in two steps | paragraphs in series so that the permeated water of a front | former stage may turn into a feed water of a back | latter stage. However, it is not limited to this. For example, the pure water production apparatus 1 may be configured such that three or more reverse osmosis membrane modules are connected in series.

DESCRIPTION OF SYMBOLS 1 Pure water manufacturing apparatus 5 Pressure pump 11 1st RO membrane module (reverse osmosis membrane module)
12 Second RO membrane module (reverse osmosis membrane module)
20 EDI stack (Electrodeionization stack)
W1 Raw water (supply water)
W2 First permeated water W3 First concentrated water W4 Second permeated water W5 Second concentrated water W6 Demineralized water

Claims (2)

A plurality of reverse osmosis membrane modules that separate supply water into permeate and concentrated water, and the permeate separated by one reverse osmosis membrane module is separated into permeate and concentrate by another reverse osmosis membrane module A plurality of reverse osmosis membrane modules connected in series,
A pressure pump that discharges supply water toward the foremost stage of the plurality of reverse osmosis membrane modules connected in series,
When the ratio of the flow rate of concentrated water to the flow rate of permeated water separated by the reverse osmosis membrane module is the circulation ratio in the reverse osmosis membrane module, the circulation ratio R1 in the reverse osmosis membrane module located in the foremost stage, The flow rate of feed water, the flow rate of permeated water, and the ratio R2 / R1 of the circulation ratio R2 in the reverse osmosis membrane module located at the last stage are in the range of 0.08 ≦ R2 / R1 ≦ 0.12. A pure water production apparatus in which at least one of the flow rates of concentrated water is set.   The pure water manufacturing apparatus of Claim 1 provided with the electrodeionization stack | stuck which demineralizes the permeated water from these reverse osmosis membrane modules, and obtains demineralized water.

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