JP7234818B2 - water treatment system - Google Patents

Description

The present invention relates to water treatment systems.

High-purity pure water containing no impurities is used in the manufacturing process of semiconductors, cleaning of electronic parts and medical equipment, and the like. This kind of pure water is generally produced by reverse osmosis membrane module (hereinafter also referred to as "RO membrane module") as a membrane separation device from raw water such as groundwater and tap water (furthermore, "supply water"). Manufactured by permeation membrane treatment.

Conventionally, there has been proposed a water treatment system for producing pure water by treating supplied water with an RO membrane module and an electrodeionization device (see, for example, Patent Documents 1 and 2). Also known is a water treatment system in which supplied water is treated by two RO membrane modules connected in series to produce pure water (see, for example, Patent Document 3).

JP-A-2001-259376 JP 2006-255650 A Japanese Patent No. 6056370

In a water treatment system that directly connects two pure water units such as reverse osmosis membrane modules, constant flow rate feedback control is performed during initial blowing in the preceding pure water unit. When starting up, it is necessary to switch the control of the pure water unit in the previous stage to constant pressure feedback control.

Although the details will be described later, when a treated water three-way valve is provided between the preceding pure water unit and the latter pure water unit, this treated water three-way valve moves from the standby open blow side to the latter pure water unit side. If the control is not switched at the appropriate timing, the frequency will increase or decrease unnecessarily. When the frequency rises, the treated water pressure rises and there is a possibility that the membrane may be damaged due to the back pressure. When the frequency decreases, the pressure cannot catch up with the acceleration of the subsequent pump, resulting in a negative pressure, which may damage equipment such as the pump.

The present invention provides a water treatment system that, when directly operating two pure water units, can safely and quickly start up the latter pure water unit after the initial blowing of the preceding pure water unit. intended to

The present invention provides a first pure water unit that produces a first permeated water from a supply water, a first pump that discharges the supply water toward the first pure water unit, and the first pure water unit that discharges the water. A first pressure detecting means for outputting the pressure of the first permeated water as a first detected pressure value, and a first flow rate for outputting the flow rate of the first permeated water discharged from the first pure water unit as a first detected flow rate value. a detection means, a second pure water unit that produces second permeated water from the first permeated water produced in the first pure water unit, and a supply destination of the first permeated water that is set to the second pure water unit side a second pump that discharges the first permeated water toward the second pure water unit; and a second pure water unit downstream of the supply destination switching means. a second pressure detecting means for outputting the pressure of the first permeated water produced in the second pure water unit as a second detected pressure value; 2 flow rate detection means, a first pump control section that drives the first pump, a second pump control section that drives the second pump, a switching means control section that switches the supply destination switching means, and the second When the pure water unit is started up, the switching means control unit operates the first pump so that the first detected flow rate value becomes the first target flow rate value in a state in which the supply destination switching means is set to the blow side. a first step of causing the control section to drive the first pump; causing the switching means control section to switch the supply destination switching means to the second pure water unit side; The first pump control unit drives the first pump so that the second detected pressure value reaches the second target pressure value, and the second detected flow rate value reaches the second target flow rate. and a start-up control unit for sequentially executing a second step of causing the second pump control unit to control the second pump so as to obtain a value.

Further, in the above water treatment system, the start-up control unit controls the second pump control when the second detected pressure value falls below a predetermined value during execution of the second step. It is preferable to cause the part to stop accelerating the second pump.

According to the present invention, when two pure water units are directly connected and operated, it is possible to safely and quickly start up the latter pure water unit after the initial blowing of the former pure water unit.

It is a figure showing the whole water treatment system composition concerning the embodiment of the present invention. It is a figure which shows the relationship of the pressure and flow volume which concern on the flow control valve used by embodiment of this invention. It is a functional block diagram of the control part with which the water treatment system concerning the embodiment of the present invention is equipped. It is a figure which shows the transition of the operation mode of the water treatment system which concerns on embodiment of this invention. It is a figure which shows the transition of the operation mode of the water treatment system which concerns on embodiment of this invention. It is a figure which shows the transition of the operation mode of the water treatment system which concerns on embodiment of this invention. It is a flow chart which shows operation of a water treatment system concerning an embodiment of the present invention. It is a figure which shows the transition of the operation mode of the water treatment system which concerns on a prior art. It is a figure which shows the transition of the operation mode of the water treatment system which concerns on a prior art. It is a figure which shows the transition of the operation mode of the water treatment system which concerns on a prior art. It is a figure which shows the transition of the operation mode of the water treatment system which concerns on a prior art. It is a figure which shows the transition of the operation mode of the water treatment system which concerns on a prior art.

Hereinafter, a water treatment system 1 according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 5. FIG.

[1 Configuration of Embodiment]
FIG. 1 is an overall configuration diagram of a water treatment system 1 according to this embodiment.
As shown in FIG. 1 , the water treatment system 1 includes a first membrane treatment device D1, a second membrane treatment device D2, and a controller 30. As shown in FIG.
The first membrane treatment apparatus D1 includes a water supply pump 2, a water supply side inverter 3, a water supply pressure regulating valve 4, a first pressure sensor PS1, a first pressure pump 5 (first pump), and a first Pressurization side inverter 6 (first inverter), second pressure sensor PS2, third pressure sensor PS3, first reverse osmosis membrane module 7 (first pure water unit), first flow control valve 8, and drainage A flow control valve 9 , a first flow sensor FM<b>1 , a second flow sensor FM<b>2 , and a first three-way valve 10 are provided. The water supply pump 2 and the water supply side inverter 3 may be provided outside the first membrane treatment apparatus D1. shows the form provided in

The first membrane treatment apparatus D1 includes, as lines, a water supply line L1, a first supply water line L2, a first concentrated water line L3, a circulating water line L4, a concentrated waste water line L5, and a first permeated water. line L6. "Line" is a generic term for lines such as channels, routes, and pipelines through which fluid can flow. In addition, regardless of the origin (source) or quality of the water, the water flowing through the water supply line L1, the first concentrated water line L3, or the circulating water line L4 is also referred to as "water supply". The water flowing through the line L4 or the concentrated drainage line L5 is also called "concentrated water".

The water supply line L1 is a line that supplies the water supply W1 to the connection portion J1 that is the confluence portion with the first supply water line L2. The upstream end of the water supply line L1 is connected to a supply source (not shown) of the water supply W1. The water supply line L1 is provided with a water supply pump 2, a water supply pressure regulating valve 4, and a connection portion J1 in this order from the upstream side to the downstream side.

The water supply W1 flowing through the water supply line L1 is not limited to water supplied directly from a supply source (not shown) of the water supply W1. etc.), water softeners and other pretreatment devices.

The water supply pump 2 is a device that sucks the water supply W1 flowing through the water supply line L1 and pressure-feeds (discharges) it toward the first pressure pump 5 as the first supply water W2. The water supply pump 2 is supplied with drive power whose frequency has been converted from the water supply side inverter 3 . The water supply pump 2 is driven at a rotational speed corresponding to the frequency of the supplied (input) driving power (hereinafter also referred to as "driving frequency").

The water supply side inverter 3 is an electric circuit (or a device having such a circuit) that supplies the water supply pump 2 with drive power whose frequency has been converted. The water supply side inverter 3 is electrically connected to the controller 30 . A command signal is input to the water supply side inverter 3 from the control unit 30 . The water supply-side inverter 3 outputs to the water supply pump 2 drive power having a drive frequency corresponding to the command signal (current value signal or voltage value signal) input from the control unit 30 .

The water supply pressure regulating valve 4 is a valve that adjusts the pressure of the water supply W1 flowing through the water supply line L1. The water supply pressure regulating valve 4 is electrically connected to the controller 30 . The opening degree of the water supply pressure regulating valve 4 is controlled by the controller 30 . The water supply pressure regulating valve 4 may be, for example, an electromagnetic valve.
Especially in this embodiment, the opening degree of the water supply pressure regulating valve 4 is adjusted so that the pressure value of the first supply water W2 measured by the first pressure sensor PS1, which will be described later, becomes a constant value.

The first supply water line L2 is a line that supplies the feed water W1 to the first reverse osmosis membrane module 7 as the first supply water W2. The upstream end of the first water supply line L2 is connected to the connecting portion J1. The downstream end of the first water supply line L2 is connected to the primary inlet port of the first reverse osmosis membrane module 7 . The first water supply line L2 has a connection J1, a first pressure sensor PS1, a first pressure pump 5, a second pressure sensor PS2, and a first reverse osmosis membrane module 7 in this order from the upstream side to the downstream side. is provided.

The first pressure sensor PS1 is a device that detects the pressure of the water supply W1 from the connection J1 to the first pressure pump 5 in the first water supply line L2. The pressure of the first supply water W2 detected by the first pressure sensor PS1 is transmitted to the controller 30 as a detection signal.

The 1st pressurization pump 5 is provided in the 1st supply water line L2. The first pressurizing pump 5 is a device that sucks the feed water W1 in the first feed water line L2 and pumps (discharges) it toward the first reverse osmosis membrane module 7 as the first feed water W2. The first pressurizing pump 5 is supplied with driving power whose frequency has been converted from the first pressurizing inverter 6 . The first pressurizing pump 5 is driven at a rotational speed corresponding to the frequency of the supplied (input) driving power (hereinafter also referred to as “driving frequency”).

The first pressurization-side inverter 6 is an electric circuit (or a device having such a circuit) that supplies drive power whose frequency is converted to the first pressurization pump 5 . The first pressure-side inverter 6 is electrically connected to the controller 30 . A command signal is input from the control unit 30 to the first pressure-side inverter 6 . The first pressurization inverter 6 outputs to the first pressurization pump 5 drive power having a drive frequency corresponding to the command signal (current value signal or voltage value signal) input from the control unit 30 .

The second pressure sensor PS2 is a device that detects the pressure of the first supply water W2 from the first pressure pump 5 to the first reverse osmosis membrane module 7 in the first supply water line L2. The pressure of the first supply water W2 detected by the second pressure sensor PS2 is transmitted to the controller 30 as a detection signal.

The first reverse osmosis membrane module 7 divides the first feed water W2 discharged from the first pressure pump 5 into a first permeate water W6 from which dissolved salts have been removed and a first concentrated water W3 from which dissolved salts have been concentrated. It is a facility for membrane separation treatment. The first reverse osmosis membrane module 7 includes single or multiple RO membrane elements (not shown). The first reverse osmosis membrane module 7 membrane-separates the first feed water W2 using these RO membrane elements to produce a first concentrated water W3 and a first permeated water W6.

The first concentrated water line L3 is a line through which the first concentrated water W3 separated by the first reverse osmosis membrane module 7 is delivered. The upstream end of the first concentrated water line L3 is connected to the primary outlet port of the first reverse osmosis membrane module 7 . Further, the downstream side of the first concentrated water line L3 is branched into a circulating water line L4 and a concentrated waste water line L5 at the connection J2. The first concentrated water line L3 is provided with a first flow control valve 8 and a connecting portion J2 in order from the upstream side toward the downstream side.

The first flow rate regulating valve 8 has a constant flow element that circulates the first concentrated water W3 at a substantially constant flow regardless of the differential pressure in the first flow rate regulating valve 8, and the difference in the first flow rate regulating valve 8. and a proportional element that increases the flow rate of the first concentrated water W3 substantially in proportion to the pressure. The differential pressure at the first flow control valve 8 is specifically the differential pressure between the water pressures in the lines before and after the first flow control valve 8 . A constant flow element maintains a constant flow value without the need for auxiliary power or external manipulation, and may be used, for example, under the name of a water governor. As the proportional element, for example, an element called an orifice may be used.

FIG. 2 is a graph showing an example of the relationship between the inlet pressure of the first reverse osmosis membrane module 7 and the flow rate of concentrated water flowing through the first flow control valve 8 . Since the first flow control valve 8 has a constant flow rate element, the flow rate of the concentrated water flowing through the first flow control valve 8 rises to point A at once when the inlet pressure is generated. That is, approximately, the flow rate of the height of point A flows into the first flow control valve 8 at the same time as the inlet pressure is generated. At the same time, since the first flow control valve 8 has a proportional element, the flow rate of the concentrated water flowing through the first flow control valve 8 increases linearly as the inlet pressure rises.

In addition, in the first flow control valve 8, the constant flow rate element and the proportional element may be configured integrally or may be configured separately. When integrally configured, for example, the flow direction of the proportional element coincides with the longitudinal direction of the first flow rate control valve 8, and the flow direction of the constant flow rate element coincides with the longitudinal direction of the first flow rate control valve 8. You may comprise so that it may be orthogonal to a direction. Alternatively, the flow direction of the proportional element may be orthogonal to the long axis direction of the first flow rate control valve 8 and the flow direction of the constant flow rate element may coincide with the long axis direction of the first flow rate control valve 8 . Alternatively, both the flow direction of the constant flow rate element and the flow direction of the proportional element may be configured to coincide with the longitudinal direction of the first flow rate control valve 8 .

The circulating water line L4 is a line that is connected to the first concentrated water line L3 and returns concentrated water (circulating water W4) as water supply to the water supply line L1. In the present embodiment, the circulating water line L4 uses the first concentrated water W3 flowing through the first concentrated water line L3 as the circulating water W4, and is located upstream of the first pressure pump 5 in the first supply water line L2. This is the line for returning (circulating). The upstream end of the circulating water line L4 is connected to the first concentrated water line L3 at the connection J2. Further, the downstream end of the circulating water line L4 is connected to the water supply line L1 and the first water supply line L2 at the connection J1.

The concentrated waste water line L5 is a line that is connected to the first concentrated water line L3 and discharges the concentrated water as the concentrated waste water W5 to the outside of the system. In the present embodiment, the concentrated waste water line L5 is connected to the first concentrated water line L3 at the connection part J2, and the first concentrated water W3 separated by the first reverse osmosis membrane module 7 is transferred outside the apparatus as the concentrated waste water W5. This is the line for discharging to (outside the system). A first flow rate sensor FM1 and a waste water flow rate control valve 9 are provided in the concentrated waste water line L5.

The first flow rate sensor FM1 is a device that detects the flow rate of the concentrated waste water W5 flowing through the concentrated waste water line L5. The first flow rate sensor FM1 is connected to the concentrated waste water line L5. The first flow rate sensor FM1 is electrically connected to the controller 30 . A first detected flow rate value of the concentrated waste water W5 detected by the first flow rate sensor FM1 is transmitted to the control section 30 as a detection signal. As the first flow rate sensor FM1, for example, a pulse transmission type flow rate sensor in which an axial flow impeller or a tangential impeller (not shown) is arranged in a flow path housing can be used.

The waste water flow rate adjustment valve 9 is a valve that adjusts the flow rate of the concentrated waste water W5 discharged outside the apparatus from the concentrated waste water line L5. The drainage flow rate adjustment valve 9 is electrically connected to the controller 30 . The valve opening degree of the drainage flow rate adjustment valve 9 is controlled by a drive signal transmitted from the control section 30 . By transmitting a current value signal (eg, 4 to 20 mA) from the control unit 30 to the waste water flow rate adjusting valve 9 to control the valve opening, the waste water flow rate of the concentrated waste water W5 can be adjusted.
In particular, in the present embodiment, the opening degree of the waste water flow rate adjustment valve 9 is adjusted so that the flow rate value of the concentrated waste water W5 measured by the first flow rate sensor FM1, which will be described later, becomes a constant value.

The first permeated water line L6 is a line for sending out the first permeated water W6 separated (manufactured) by the first reverse osmosis membrane module 7 . The upstream end of the first permeate line L6 is connected to the secondary port of the first reverse osmosis membrane module 7 . A downstream end of the first permeated water line L6 is connected to the first three-way valve 10 . A third pressure sensor PS3 and a second flow rate sensor FM2 are installed in the first permeated water line L6.

The third pressure sensor PS3 (hereinafter also referred to as "first pressure detection means") detects the pressure of the first permeated water W6 from the first reverse osmosis membrane module 7 to the first three-way valve 10 in the first permeated water line L6. It is a device that detects pressure. The pressure of the first permeated water W6 detected by the third pressure sensor PS3 (hereinafter also referred to as "first detected pressure value") is transmitted to the controller 30 as a detection signal.

The second flow rate sensor FM2 (hereinafter also referred to as "first flow rate detection means") detects the flow rate of the first permeated water W6 flowing through the first permeated water line L6 (hereinafter also referred to as "first detected flow rate value" ). The second flow rate sensor FM2 is connected to the first permeated water line L6. The second flow rate sensor FM2 is electrically connected to the controller 30 . A second detected flow rate value of the first permeated water W6 detected by the second flow rate sensor FM2 is transmitted to the controller 30 as a detection signal. As the second flow rate sensor FM2, for example, a pulse transmission type flow rate sensor having an axial flow impeller or a tangential impeller (not shown) arranged in the flow path housing can be used.

The first three-way valve 10 (hereinafter also referred to as "supply destination switching means") supplies the second feed water W8 to the first permeate line L6, the first permeate drainage line L7, and the second membrane treatment device D2. It connects with the 2nd water supply line L8 which carries out. The first three-way valve 10 switches the supply destination of the first permeated water W6 flowing through the first permeated water line L6 between the first permeated water line L7 and the second membrane treatment apparatus D2. That is, in a state in which the flow path from the first permeate line L6 to the first permeate drainage line L7 is closed by the first three-way valve 10, the total amount of the first permeate W6 flowing through the first permeate line L6 is 2 flows to the supply water line L8 side. When the first three-way valve 10 switches the flow path, in a state where the first three-way valve 10 closes the flow path from the first permeate line L6 to the second supply water line L8, the first permeate line L6 is circulated. The entire amount of the first permeated water W6 flows to the first permeated water discharge line L7 side. Thus, the first three-way valve 10 switches the flow path between the first permeate drainage line L7 and the second feed water line L8.

The second membrane processing apparatus D2 includes a fourth pressure sensor PS4, a second pressure pump 11 (second pump), a second pressure side inverter 12 (second inverter), and a second reverse osmosis membrane module 13 (second 2 pure water unit), a constant flow valve 14, a third flow sensor FM3, a second three-way valve 15, and a fourth flow sensor FM4.

Further, the second membrane treatment apparatus D2 includes, as lines, a second feed water line L8, a second concentrated water line L9, a second permeated water line L10, a second permeated water discharge line L11, and a third permeated water line. L12.

The second supply water line L8 is a line that supplies the second supply water W8 to the second reverse osmosis membrane module 13 . The upstream end of the second water supply line L8 is connected to the first three-way valve 10 . The downstream end of the second water supply line L8 is connected to the primary inlet port of the second reverse osmosis membrane module 13 . The second water supply line L8 is provided with a fourth pressure sensor PS4 and a second pressure pump 11 in this order from upstream to downstream.

A fourth pressure sensor PS4 (hereinafter also referred to as "second pressure detection means") detects the pressure of the second supply water W8 from the first three-way valve 10 to the second pressure pump 11 in the second supply water line L8. It is a device that detects The pressure of the second supply water W8 detected by the fourth pressure sensor PS4 (hereinafter also referred to as "second detected pressure value") is transmitted to the control section 30 as a detection signal.

The second pressurizing pump 11 is a device that sucks the second supply water W8 in the second supply water line L8 and pumps (discharges) it toward the second reverse osmosis membrane module 13 . The second pressurizing pump 11 is supplied with driving power whose frequency has been converted from the second pressurizing inverter 12 . The second pressurizing pump 11 is driven at a rotational speed corresponding to the frequency of the supplied (input) driving power (hereinafter also referred to as “driving frequency”).

The second pressurization inverter 12 is an electric circuit (or a device having such a circuit) that supplies the second pressurization pump 11 with frequency-converted drive power. The second pressure-side inverter 12 is electrically connected to the controller 30 . A command signal is input from the control unit 30 to the second pressure-side inverter 12 . The second pressure-side inverter 12 outputs to the second pressure pump 11 drive power having a drive frequency corresponding to the command signal (current value signal or voltage value signal) input from the control section 30 .

The second reverse osmosis membrane module 13 divides the second feed water W8 discharged from the second pressurizing pump 11 into a second permeated water W10 from which dissolved salts have been removed and a second concentrated water W9 from which dissolved salts have been concentrated. It is a facility for membrane separation treatment. The second reverse osmosis membrane module 13 includes single or multiple RO membrane elements (not shown). The second reverse osmosis membrane module 13 membrane-separates the second feed water W8 using these RO membrane elements to produce a second concentrated water W9 and a second permeated water W10.

The second concentrated water line L9 is a line through which the second concentrated water W9 separated by the second reverse osmosis membrane module 13 is delivered. The upstream end of the second concentrated water line L9 is connected to the primary outlet port of the second reverse osmosis membrane module 13 . The second concentrated water line L9 is provided with a constant flow valve 14 and a third flow sensor FM3 in this order from upstream to downstream.

The constant flow valve 14 includes a constant flow element that allows the second concentrated water W9 to flow at a substantially constant flow regardless of the differential pressure in the constant flow valve 14 .

The third flow rate sensor FM3 is a device that detects the flow rate of the second concentrated water W9 flowing through the second concentrated water line L9. The third flow rate sensor FM3 is electrically connected to the controller 30 . A third detected flow rate value of the second concentrated water W9 detected by the third flow rate sensor FM3 is transmitted to the controller 30 as a detection signal. As the third flow rate sensor FM3, for example, a pulse transmission type flow rate sensor in which an axial flow impeller or a tangential impeller (not shown) is arranged in the flow path housing can be used.

The second permeated water line L10 is a line for sending out the second permeated water W10 separated (manufactured) by the second reverse osmosis membrane module 13 . The upstream end of the second permeate line L10 is connected to the secondary port of the second reverse osmosis membrane module 13 . A downstream end of the second permeated water line L10 is connected to the second three-way valve 15 . A fourth flow rate sensor FM4 is provided in the second permeated water line L10.

The fourth flow rate sensor FM4 (hereinafter also referred to as "second flow rate detection means") detects the flow rate of the second permeated water W10 flowing through the second permeated water line L10 (hereinafter also referred to as "second detected flow rate value" ). The fourth flow rate sensor FM4 is electrically connected to the controller 30 . A second detected flow rate value of the second permeated water W10 detected by the fourth flow rate sensor FM4 is transmitted to the controller 30 as a detection signal. As the fourth flow rate sensor FM4, for example, a pulse transmission type flow rate sensor in which an axial flow impeller or a tangential impeller (not shown) is arranged in the flow path housing can be used.

The second three-way valve 15 connects the second permeated water line L10, the second permeated water discharge line L11, and the third permeated water line L12. The second three-way valve 15 switches the supply destination of the second permeated water W10 flowing through the second permeated water line L10 between the second permeated water discharge line L11 and the third permeated water line L12. That is, in a state where the flow path from the second permeate line L10 to the second permeate drainage line L11 is closed by the second three-way valve 15, the total amount of the second permeate W10 flowing through the second permeate line L10 is 3 flows to the permeated water line L12 side. When the second three-way valve 15 switches the flow path, in a state where the flow path from the second permeate line L10 to the third permeate line L12 is closed by the second three-way valve 15, the second permeate line L10 is circulated. The entire amount of the second permeated water W10 flows to the second permeated water discharge line L11 side. Thus, the second three-way valve 15 switches the flow path between the second permeate drainage line L11 and the third permeate water line L12.

The third permeated water line L12 is a line that sends out the third permeated water W12 separated by the second three-way valve 15 . The upstream end of the third permeated water line L12 is connected to the second three-way valve 15 . A downstream end of the third permeated water line L12 is connected to a device or the like at a demand point.

The control unit 30 is configured by a microprocessor (not shown) including a CPU and memory. In the control unit 30, the CPU of the microprocessor executes various controls related to the water treatment system 1 according to a predetermined program read from the memory. A part of the functions of the control unit 30 will be described below.

FIG. 3 shows functional blocks of the control unit 30. As shown in FIG. The control unit 30 includes a first pump control unit 301 , a second pump control unit 302 , a switching means control unit 303 and a startup control unit 304 .

The first pump control section 301 drives the first pressure pump 5 . More specifically, the first pump control unit 301 controls the rotation speed such that the first detected flow rate value detected by the second flow rate sensor FM2 becomes the first target flow rate value when the second membrane processing apparatus D2 is started up. , the first pressure pump 5 is driven. Further, after the first three-way valve 10 switches the supply destination of the first permeate W6 to the second membrane treatment apparatus D2 side, the first pump control unit 301 controls the first detection detected by the third pressure sensor PS3. The first pressurizing pump 5 is driven at a rotational speed such that the pressure value becomes the first target pressure value.

The second pump control section 302 drives the second pressure pump 11 . More specifically, as described above, the first pump control unit 301 drives the first pressurization pump 5 at a rotational speed such that the pressure value detected by the third pressure sensor PS3 becomes the target pressure value. After that, when the second detected pressure value detected by the fourth pressure sensor PS4 becomes the second target pressure value, the second detected flow rate value detected by the fourth flow rate sensor FM4 becomes the second target flow rate value. The second pressurizing pump 11 is driven at a constant rotational speed.

The switching means control unit 303 causes the first three-way valve 10 as the supply destination switching means to switch the supply destination of the first permeate W6 between the second membrane treatment apparatus D2 side and the blow side. More specifically, when the second membrane treatment apparatus D2 is started up, the first three-way valve 10 is supplied with the first permeate W6 to the blow side. Thereafter, as described above, after the first pump control unit 301 drives the first pressurization pump 5 at a rotational speed at which the first detected flow rate value becomes the first target flow rate value, the switching means control unit 303 2, the supply destination of the first permeate W6 is set to the second membrane treatment apparatus D2 side with respect to the first three-way valve 10 as the supply destination switching means.

The start-up control unit 304 controls the operation during start-up by changing the operation mode of the water treatment system 1 .
More specifically, as a first step, the start-up control unit 304 instructs the switching means control unit 303 to specify the supply destination of the first permeate W6 by the first three-way valve 10 when starting up the second membrane processing apparatus D2. In the blow side state, the first pump control unit 301 drives the first pressure pump 5 so that the first detected flow rate value becomes the first target flow rate value.
In addition, as a second step, the start-up control unit 304 causes the switching means control unit 303 to switch the supply destination of the first permeated water W6 by the first three-way valve 10 to the second membrane treatment apparatus D2 side, and the third pressure The first pressure pump 5 is driven by the first pump control unit 301 so that the first detected pressure value detected by the sensor PS3 becomes the first target pressure value, and the second pressure value detected by the fourth pressure sensor PS4 is controlled. From the time when the detected pressure value reaches the second target pressure value, the second pump control unit 302 performs the second pressure adjustment so that the second detected flow rate value detected by the fourth flow rate sensor FM4 reaches the second target flow rate value. The pressure pump 11 is driven.
In this embodiment, the start-up control unit 304 causes the second pump control unit 302 to stop accelerating the second pressure pump 11 when the second detected pressure value falls below a predetermined value during execution of the second step. Let

[2 Operation of Embodiment]
Hereinafter, the operation of the water treatment system 1 according to this embodiment will be described with reference to FIGS. 4A, 4B, and 5. FIG. As a premise, the problems in the prior art will be described in detail with reference to FIGS. 6A to 6C and FIGS. 7A to 7B.
6A to 6C and 7A to 7B show the configuration of the water treatment system 1A according to the prior art, but the configuration is basically the same as the water treatment system 1 according to the present embodiment. Therefore, the description of each component is omitted. The water treatment system 1A differs from the water treatment system 1 in that it includes a control unit 30A instead of the control unit 30. The control unit 30A includes a first pump control unit 301 and a second pump control unit provided in the control unit 30. 302 , switching means control unit 303 and start-up control unit 304 are not provided.

6A to 6C show changes in operation when constant pressure feedback control is performed during switching of the first three-way valve 10 in the conventional water treatment system 1A.

As a first step, as shown in FIG. 6A, an initial blow of the first film processing apparatus D1 is performed. During this time, the first three-way valve 10 causes the entire amount of the first permeated water W6 flowing through the first permeated water line L6 to flow to the blow side, that is, to the first permeated water drainage line L7 side. At this time, the pressure of the treated water, that is, the detected pressure value detected by the third pressure sensor PS3 cannot be used. Constant flow feedback control. Note that "feedback" may be abbreviated as "FB".

As a second step, as shown in FIG. 6B, the first three-way valve 10 switches the supply destination of the first permeate W6 from the blow side to the second membrane treatment apparatus D2 side. At this time, since the second pressurizing pump 11 provided in the second membrane treatment device D2 is not operating, the pressure loss in the second membrane treatment device D2 is high, and the pressure of the treated water in the first membrane treatment device D1 is the third The detected pressure value detected by the pressure sensor PS3 increases. Furthermore, the frequency (rotational speed) of the first pressure pump 5 is extremely lowered.

As a third step, as shown in FIG. 6C, an initial blow of the second film processing apparatus D2 is performed. Specifically, the second pressure pump 11 starts to operate, but for a while, the pressure value detected by the third pressure sensor PS3, which is the pressure of the treated water in the first membrane treatment apparatus D1, is lower than the target pressure value. Since it is high, the first pressure pump 5 continues to decelerate.
When the detected pressure value detected by the third pressure sensor PS3 falls below the target pressure value and the second pressurizing pump 11 accelerates, the frequency of the first pressurizing pump 5 approaches 0 Hz and the second pressurizing The frequency of the pump 11 is a frequency equal to or higher than a predetermined value. As a result, the acceleration of the first pressurizing pump 5 fails to catch up with the acceleration of the second pressurizing pump 11, resulting in a negative pressure, causing cavitation in the first pressurizing pump 5 and causing damage.

7A and 7B show changes in operation when constant flow rate feedback control is performed during switching of the first three-way valve 10 in the conventional water treatment system 1A.

As a first step, as shown in FIG. 7A, an initial blow of the first film processing apparatus D1 is performed. During this time, the first three-way valve 10 causes the entire amount of the first permeated water W6 flowing through the first permeated water line L6 to flow to the blow side, that is, to the first permeated water drainage line L7 side. At this time, the pressure of the treated water, that is, the detected pressure value detected by the third pressure sensor PS3 cannot be used. Constant flow feedback control.

As a second step, as shown in FIG. 7B, the first three-way valve 10 switches the supply destination of the first permeate W6 from the blow side to the second membrane treatment apparatus D2 side. At this time, since the second pressure pump 11 provided in the second membrane treatment device D2 is not operating, the pressure loss in the second membrane treatment device D2 is high, and the first permeated water which is the treated water of the first membrane treatment device D1 The flow rate of W6 decreases. The first pressurizing pump 5 continues to increase the frequency in an attempt to flow the target flow rate, and the detected pressure value detected by the third pressure sensor PS3, which is the treated water pressure of the first membrane treatment apparatus D1, continues to increase. As a result, a reverse pressure is generated in which the detected pressure value is higher than the membrane outlet pressure of the first reverse osmosis membrane module 7, and the reverse osmosis membrane of the first reverse osmosis membrane module 7 is damaged.

Therefore, in the water treatment system 1 according to the present embodiment, during the initial blow of the second membrane treatment device D2, the second detection pressure detected by the fourth pressure sensor, which is the water supply pressure to the second membrane treatment device D2, is Monitor values. 4A to 4C show the operation of monitoring the second detected pressure value detected by the fourth pressure sensor during the initial blow of the second membrane treatment device D2 in the water treatment system 1 according to the present embodiment. Show transition.

As a first step, as shown in FIG. 4A, an initial blow of the first film processing apparatus D1 is performed. During this time, the first three-way valve 10 causes the entire amount of the first permeated water W6 flowing through the first permeated water line L6 to flow to the blow side, that is, to the first permeated water drainage line L7 side. At this time, the pressure of the treated water, that is, the detected pressure value detected by the third pressure sensor PS3 cannot be used. Constant flow feedback control.

As a second step, as shown in FIG. 4B, the first three-way valve 10 switches the supply destination of the first permeate W6 from the blow side to the second membrane treatment apparatus D2 side. At this time, the control of the first film processing apparatus D1 is switched to constant pressure feedback control. Since the first three-way valve 10 is on the standby open side, the drive frequency of the first pressure pump 5 increases. When the first three-way valve 10 begins to switch to the treated water side, the first pressure value detected by the third pressure sensor PS3, which is the treated water pressure of the first membrane treatment device D1, increases. The driving frequency of the pump 5 is lowered. When the second detected pressure value detected by the fourth pressure sensor PS4 provided in the second membrane processing apparatus D2 exceeds the target pressure, the second membrane processing apparatus D2 starts constant flow rate feedback control. As a result, it is possible to prevent the first detection pressure value detected by the third pressure sensor PS3, which is the pressure of the water treated by the first membrane treatment apparatus D1, from excessively increasing and the frequency of the first pressurizing pump 5 from excessively decreasing. prevent. When the second detection pressure value detected by the fourth pressure sensor PS4, which is the water supply pressure to the second membrane processing device D2, becomes equal to or less than a certain value, the acceleration of the frequency of the second pressurization pump 11 is stopped. prevent pressure.

As a third step, as shown in FIG. 4C, an initial blow of the second film processing apparatus D2 is performed. At this time, basically the same control as in the second step is executed. In addition to this, the second detection pressure value detected by the fourth pressure sensor PS4, which is the water supply pressure to the second membrane processing apparatus D2, is monitored to adjust the acceleration/deceleration of the second pressure pump 11. , negative pressure, and the risk of back pressure is reduced.

FIG. 5 is a flow chart showing the operation of the water treatment system 1 according to this embodiment. The operation of the water treatment system 1 will be described below with reference to FIG.

In step S11, constant flow rate feedback control is started in the first film processing apparatus D1.
In step S12, switching of the first three-way valve 10 is started. More specifically, the first three-way valve 10 starts the operation of switching the supply destination of the first permeated water W6 flowing through the first permeated water line L6 from the blow side to the second membrane treatment device D2 side.
In step S13, constant pressure feedback control is started in the first film processing apparatus D1.

In step S14, when the water supply pressure to the second membrane processing apparatus D2 is equal to or higher than the target value (S14: YES), the process proceeds to step S15. If the water supply pressure is less than the target value (S14: NO), the process proceeds to step S14.

In step S15, constant flow rate feedback control is started in the second film processing apparatus D2.
In step S16, when the switching of the first three-way valve 10 is completed (S16: YES), the process proceeds to step S17. If the switching of the first three-way valve 10 has not yet ended (S16: NO), the process proceeds to step S14.

In step S17, when the water supply pressure to the second membrane processing apparatus D2 is less than the predetermined value (S17: YES), the process proceeds to step S18. If the water supply pressure to the second membrane treatment device D2 is equal to or higher than the predetermined value (S17: NO), the process proceeds to step S18.

In step S18, acceleration of the second pressure pump 11 is stopped. After that, the process moves to step S17.

[3 Effect of Embodiment]
The water treatment system 1 according to this embodiment includes a first pump control unit 301 that drives the first pressure pump 5, a second pump control unit 302 that drives the second pressure pump 11, and a supply destination switching means The switching means control unit 303 for switching the first three-way valve 10, and the first three-way valve 10 as the supply destination switching means in the switching means control unit 303 at the start-up of the second membrane processing apparatus D2 to the blow side state, the first pump control unit 301 drives the first pressure pump 5 so that the first detected flow rate value becomes the first target flow rate value; The first three-way valve 10 as switching means is switched to the second membrane processing apparatus D2 side, and the first pressure pump 5 is operated by the first pump control unit 301 so that the first detected pressure value becomes the first target pressure value. is driven so that the second pressure pump 11 and a start-up control unit 304 for sequentially executing a second step for controlling

As a result, when operating the water treatment system 1 to which the pure water unit such as the reverse osmosis membrane module is directly connected, it is possible to safely start up the subsequent equipment while suppressing the possibility of negative pressure or back pressure. . Also, since the acceleration time of the pump in the latter stage can be shortened, the start-up time can be shortened.

In addition, in the water treatment system 1 according to the present embodiment, the start-up control unit 304 causes the second pump control unit 302 to apply the second pressure when the second detected pressure value falls below a predetermined value during execution of the second step. Acceleration of pressure pump 11 is stopped.

As a result, since the feed water pressure is monitored and the acceleration/deceleration of the subsequent pump is adjusted, the risk of negative or reverse pressure is reduced.

[4 Modifications]
In the above embodiment, the first reverse osmosis membrane module 7 is provided on the first stage and the second reverse osmosis membrane module 13 is provided on the second stage, but the present invention is not limited to this. The water treatment system of the present invention is not limited to having two stages of pure water units. The number of stages may be three or more. The pure water unit may be an electrically regenerative ion exchange device or decarbonation membrane device.

Examples of combinations of the number of stages and pure water units are shown below.
RO: Reverse osmosis membrane module EDI: Electrically regenerative ion exchange device Decarbonation membrane: Decarbonation membrane device

1, 1A Water treatment system 4 Water supply pressure regulating valve 5 First pressure pump (first pump)
6 First pressure side inverter (first inverter)
7 First reverse osmosis membrane module (first pure water unit)
10 first three-way valve (supply destination switching means)
11 Second pressure pump (second pump)
12 second pressure side inverter (second inverter)
13 Second reverse osmosis membrane module (second pure water unit)
30 control unit 301 first pump control unit 302 second pump control unit 303 switching means control unit 304 startup control unit PS1 first pressure sensor PS2 second pressure sensor PS3 third pressure sensor (first pressure detection means)
PS4 fourth pressure sensor (second pressure detection means)
FM1 First flow sensor FM2 Second flow sensor (first flow detection means)
FM3 Third flow sensor FM4 Fourth flow sensor (second flow detection means)
W2 First supply water (supply water)
W6 First permeated water W10 Second permeated water

Claims (2)

a first pure water unit that produces a first permeate from the feed water;
a first pump that discharges supply water toward the first pure water unit;
a first pressure detection means for outputting the pressure of the first permeated water discharged from the first pure water unit as a first detected pressure value;
first flow rate detection means for outputting the flow rate of the first permeated water discharged from the first pure water unit as a first detected flow rate value;
a second pure water unit that produces a second permeated water from the first permeated water produced in the first pure water unit;
a supply destination switching means for switching the supply destination of the first permeated water between the second pure water unit side and the blow side;
a second pump that discharges the first permeated water toward the second pure water unit;
a second pressure detecting means for outputting, as a second detected pressure value, the pressure of the first permeated water supplied to the second pure water unit, which is downstream of the supply destination switching means;
a second flow rate detecting means for outputting the flow rate of the second permeated water produced in the second pure water unit as a second detected flow rate value;
a first pump control unit that drives the first pump;
a second pump control unit that drives the second pump;
a switching means control unit for switching the supply destination switching means;
When the second pure water unit is started up, the switching means control unit controls the switching means so that the first detected flow rate value becomes the first target flow rate value in a state in which the supply destination switching means is set to the blow side. a first step of causing a first pump control unit to drive the first pump;
The switching means control section switches the supply destination switching means to the second pure water unit side, and the first pump control section controls the first 1 pump is driven, and the second pump controller controls the second a second step of controlling the two pumps; 2. The apparatus according to claim 1, wherein the start-up control section causes the second pump control section to stop accelerating the second pump when the second detected pressure value falls below a predetermined value during execution of the second step. A water treatment system as described.

Images