JP6394028B2 - Water treatment unit - Google Patents

Description

  The present invention relates to a water treatment unit, and more particularly to a water treatment unit capable of producing water having a high bactericidal factor concentration.

  Conventionally, a water treatment unit for sterilizing water has been known. For example, Patent Document 1 discloses a processing tank that stores water, an inflow path that allows water to flow into the processing tank, an outflow path that allows water to flow out of the processing tank, and an electrode pair provided inside the processing tank. A water treatment unit is disclosed. When this water treatment unit operates, water flows in the treatment tank from the inflow path toward the outflow path. At the same time, a predetermined voltage is applied to the electrode pair in water to cause discharge, thereby generating a bactericidal factor in water. The sterilizing factor thus generated sterilizes the water flowing through the processing tank, or sterilizing water (referred to as water containing the sterilizing factor; hereinafter the same) is generated in the processing tank.

JP2013-150975A

  By the way, when the water treatment unit of Patent Document 1 is operated, a discharge is caused in a state where water continuously flows in the storage tank to generate a sterilizing factor. That is, while the sterilization factor continues to be generated by the discharge, water that does not contain the sterilization factor continues to flow into the storage tank. At the same time, water containing sterilizing factors continues to flow out of the reservoir. In this way, the discharge that acts to increase the concentration of the sterilizing factor of the sterilizing water and the inflow and outflow of water that acts to decrease the concentration of the sterilizing factor of the sterilizing water are performed simultaneously. Therefore, the bactericidal factor concentration of the sterilizing water is determined according to the relationship between the water flow rate and the discharge intensity. Therefore, the water treatment unit of Patent Document 1 has room for improvement in that it is difficult to generate sterilized water having an arbitrary sterilizing factor concentration.

  This invention is made | formed in view of this point, The objective is to enable it to produce | generate the sterilization water of arbitrary sterilization factor density | concentrations, especially sterilization water with a high sterilization factor density | concentration.

  1st invention is a water provided with the process tank (11) which stores water, and the discharge part (31,32,34) which produces discharge so that a disinfection factor may be produced in the water of this process tank (11) Intended for processing unit (10).

And in 1st invention, in the state which the inflow of the water to the said processing tank (11) and the outflow of the water from the said processing tank (11) stopped, the said discharge part (31,32,34) discharges. A concentration raising operation is performed to increase the concentration of the sterilizing factor in the water in the treatment tank (11), and after the concentration raising operation is finished, water flows into the treatment tank (11) and from the treatment tank (11). The treatment tank (11) is configured to perform a flow operation in which the treated water flows out , and a plurality of flow paths (21 to 23) are formed in the treatment tank (11). The discharge section (31, 32, 34) is provided, and is configured to perform the concentration increasing operation and the circulation operation in each of the flow paths (21 to 23). 32, 34) that is switchably connected and applies a predetermined voltage to any one of the discharge parts (31, 32, 34) to cause a discharge in the discharge part (31, 32, 34). A source part (33), and when the concentration increasing operation in one of the flow paths (21-23) is completed, the concentration increasing operation in the next flow path (21-23) is started. By sequentially switching the discharge sections (31, 32, 34) to which a voltage is applied by the power supply section (33), the flow paths (21 to 23) for performing the concentration increasing operation are sequentially switched, and the discharge sections ( 31, 32, 34) stops the discharge while stopping the concentration increasing operation in the flow path (21 to 23) provided with the discharge part (31, 32, 34), When the flow operation in 21 to 23) is completed, the flow channels (21 to 23) for performing the flow operation are sequentially switched so that the flow operation in the next flow channel (21 to 23) starts. It is characterized by.

In 1st invention, the disinfection factor density | concentration of the sterilization water produced | generated in a processing tank (11) rises, so that time to perform density | concentration raise operation | movement is lengthened. That is, sterilizing water having an arbitrary sterilizing factor concentration can be generated by adjusting the time for performing the concentration increasing operation. Further, by performing the concentration increasing operation for a long time, sterilized water having a high concentration of the sterilizing factor is generated. By performing the distribution operation following the concentration increasing operation, the generated sterilized water flows out of the treatment tank (11).
In the first invention, the discharge units (31, 32, 34) to which a voltage is applied by the power source unit (33) are sequentially switched, and only one discharge unit (31, 32, 34) is provided at an arbitrary time. Causes a discharge. In this way, the power supply unit (33) is shared by all the discharge units (31, 32, 34), and there is no need to provide a power supply unit for each discharge unit (31, 32, 34). ).
Here, when it is going to perform discharge operation and distribution operation by a discharge part (31, 32, 34) in each flow path (21-23) simultaneously, each flow path (21-23) and an inflow source of water And between each flow path (21-23) and the sterilization water outflow destination, in order to prevent leakage from the flow path (21-23) to the inflow source and the outflow destination, It is necessary to provide insulation means. On the other hand, in the first invention, the concentration increasing operation and the distribution operation are performed at different timings in each of the flow paths (21 to 23). That is, in each flow path (21-23), the discharge operation and the distribution operation by the discharge part (31, 32, 34) are not performed simultaneously. For this reason, it is not necessary to provide an insulating means between each flow path (21-23) and the inflow source of water, and between each flow path (21-23) and the outflow destination of sterilization water, and thus water treatment. The configuration of the unit (10) can be simplified.
According to a second invention, in the first invention, a concentration sensor (61) for detecting a concentration of a sterilizing factor of water flowing out of the treatment tank (11), and a detection value of the concentration sensor (61) are a predetermined target. A control unit (60) for adjusting the time for performing the concentration increasing operation and the time for performing the distribution operation so as to approach a value, and performs the distribution operation when the detected value is lower than the target value. While shortening time, when the said detected value is higher than the said target value, the control part (60) which lengthens the time which performs the said distribution operation | movement is provided.

In the second invention, when a predetermined target value is set, the control unit (60) sets the time for performing the concentration increasing operation and the distribution operation so that the detection value of the concentration sensor (61) approaches the target value. Adjust the time to do. In particular, the control unit (60) decreases the sterilizing factor concentration of the sterilizing water by increasing the time for performing the circulation operation, or increases the sterilizing factor concentration of the sterilizing water by shortening the time for performing the distribution operation. Thereby, the sterilization water of the sterilization factor density | concentration set as target value is produced | generated, and flows out from a processing tank (11).

A third invention is characterized in that, in the second invention, the concentration raising operation and the circulation operation are alternately performed once each.

In the third invention, the concentration increasing operation and the distribution operation are alternately performed once. For example, since the concentration increasing operation is not performed a plurality of times for one circulation operation, the detection value of the concentration sensor (61) approaches the target value relatively quickly, and sterilizing water can be efficiently generated.

According to the present invention, sterilizing water having an arbitrary sterilizing factor concentration can be generated by adjusting the time for performing the concentration increasing operation. Further, by performing the concentration increasing operation for a long time, it is possible to generate sterilized water having a high concentration of sterilizing factor. Furthermore, the cost of the water treatment unit (10) can be reduced by sharing the power supply unit (33), and the configuration of the water treatment unit (10) can be simplified by eliminating the need for insulating means.

Moreover, according to the said 2nd or 3rd invention, the sterilization water of arbitrary sterilization factor density | concentrations can be produced | generated by setting a predetermined target value.

Drawing 1 is a perspective view showing the outline of the water treatment unit concerning an embodiment. FIG. 2 is a schematic cross-sectional view showing the discharge unit according to the embodiment. FIG. 3 is a diagram illustrating voltage waveforms generated by the power supply unit according to the embodiment. FIG. 4 is an enlarged view showing a part of the discharge unit according to the embodiment. FIG. 5 is a time chart showing the operation of the water treatment unit of the embodiment.

  Embodiments of the present invention will be described in detail with reference to the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

  1 to 4 show an embodiment of a water treatment unit according to the present invention. The water treatment unit (10) according to the present invention is used for washing vegetables, for example.

  As shown in FIG. 1, the water treatment unit (10) includes a treatment tank (11), a plurality of discharge units (30a to 30c), a power supply unit (33), a spray device (40a to 40c), an auxiliary A water tank (50) and a control unit (60) are provided. An inflow pipe (43a-43c) is connected to the spray device (40a-40c), and an outflow pipe (45) is connected to the auxiliary water tank (50). The water treatment unit (10) allows water to flow from the inflow pipe (43a to 43c) to the treatment tank (11) via the spray device (40a to 40c), and in this treatment tank (11), the discharge unit (30a to 30c) ) To produce a sterilizing factor in the water to produce sterilizing water, and the produced sterilizing water flows out from the outflow pipe (45) through the auxiliary water tank (50).

  The treatment tank (11) is a box-shaped water tank formed in a substantially rectangular shape in plan view. Specifically, the treatment tank (11) is formed in a horizontally long and substantially rectangular flat plate and is opposed to the bottom (12) in the width direction of the bottom (12). Side walls (13) extending upward from both sides (that is, both sides extending in the left-right direction in FIG. 1), and the side walls (13) of the bottom (12) formed on a horizontally long substantially rectangular flat plate. It is formed by end walls (14a, 14b) extending upward from both sides orthogonal to each other (that is, both sides extending in the depth direction in FIG. 1). The end wall portion (14b) on one end side (that is, the water outflow side) of the treatment tank (11) in the water flow direction has a height that is the other end side (that is, the water flow direction of the treatment tank (11)). The end wall (14a) and the side wall (13) on the water inflow side are formed lower. Thereby, the outflow port part (17) is formed above the end wall part (14b) of the one end side. On the upper end of the end wall portion (14b) on the one end side, a slope (18) for dropping the water flowing out from the outlet portion (17) is provided so as to extend obliquely downward.

  Inside the treatment tank (11), a plurality of partition plates (15, 15a) are arranged at predetermined intervals in the width direction. Each partition plate (15, 15a) is formed in a horizontally long, substantially rectangular flat plate, and is arranged along the water flow direction so that the inside of the treatment tank (11) is divided into a plurality of lanes (21a, 21b, 22a, 22b). 23a, 23b). Each partition plate (15, 15a) is formed of a material having electrical insulation. In addition, an opening (16) is formed in each of the partition plates (15a) disposed in the first flow path (21), the second flow path (22), and the third flow path (23) described later. Yes. In the treatment tank (11), first to sixth lanes (21a, 21b, 22a, 22b, 23a, 23b) are formed in order from the front side in FIG. 1 by the partition plates (15, 15a). In addition, the number of lanes (21a, 21b, 22a, 22b, 23a, 23b) formed in the treatment tank (11) is an example, and may be arbitrarily changed according to the amount of water flowing in the treatment tank (11). Can do.

  The first lane (21a) and the second lane (21b) are paired to form the first flow path (21), and the third lane (22a) and the fourth lane (22b) are paired to form the first lane (21b). Two flow paths (22) are formed, and the fifth lane (23a) and the sixth lane (23b) are paired to form a third flow path (23). That is, the partition plate (15) between the second lane (21b) and the third lane (22a) and the partition plate (15) between the fourth lane (22b) and the fifth lane (23a) are The internal space of the processing tank (11) is partitioned into a plurality of flow paths (21 to 23).

  As shown in FIG. 2, the plurality of discharge units (30a to 30c) includes a first discharge unit (30a), a second discharge unit (30b), and a third discharge unit (30c). Each discharge unit (30a-30c) is provided for each of the flow paths (21-23) described above.

  A 1st discharge unit (30a) produces a disinfection factor in the water of a 1st flow path (21). The first discharge unit (30a) includes an electrode pair (31, 32) and a partition plate (15a) in which the opening (16) described above is formed. The partition plate (15a) is provided with a discharge member (34). The electrode pair (31, 32) and the discharge member (34) constitute a discharge part of the present invention. In addition, a 2nd discharge unit (30b) produces a disinfection factor in the water of a 2nd flow path (22). The third discharge unit (30c) generates a sterilizing factor in the water of the third flow path (23). Since the specific configuration of the second discharge unit (30b) and the third discharge unit (30c) is the same as that of the first discharge unit (30a), description thereof is omitted. One power source section (33) described later is connected to the electrode pair (31, 32) of the first to third discharge units (30a to 30c) via a changeover switch (62).

  The electrode pair (31, 32) is for generating discharge in water, and includes a hot-side electrode (31) and a neutral-side electrode (32). The hot-side electrode (31) is formed in a flat shape and is disposed in the first lane (21a). The hot side electrode (31) is connected to the power source section (33) via the changeover switch (62). The neutral side electrode (32) is formed in a flat shape and is disposed in the second lane (21b). The neutral side electrode (32) is connected to the power source section (33) via the changeover switch (62). The hot-side electrode (31) and the neutral-side electrode (32) are disposed so as to be substantially parallel to each other. These electrodes (31, 32) are made of, for example, a metal material having high corrosion resistance.

  The power supply unit (33) applies a predetermined voltage to the electrode pair (31, 32) of each flow path (21-23). The power supply unit (33) has one terminal connected to the hot side electrode (31) via the changeover switch (62) and the other terminal connected to the neutral side electrode (32) via the changeover switch (62). It is connected. The power supply unit (33) is connected to the electrode pair (31, 32) of any one flow path (21-23) by the changeover switch (62) controlled by the control unit (60), and the electrode pair (31 , 32) is applied with a predetermined voltage. In the present embodiment, for example, as shown in FIG. 3, the power supply unit (33) is configured to apply an alternating waveform voltage in which positive and negative are switched to the electrode pair (31, 32). The duty of this alternating waveform (square wave) is adjusted so that the ratios of the positive electrode side and the negative electrode side are equal. The voltage applied to the electrode pair (31, 32) is an example, and is not limited to a square wave but may be a sine wave or the like as long as it is an alternating voltage.

  The discharge member (34) is a plate-like insulating member. The discharge member (34) is made of an electrically insulating material such as ceramics. The ceramic is aluminum nitride, silicon nitride, zirconia or alumina. The discharge member (34) includes an opening (16) formed in a partition plate (15a) that partitions the first lane (21a) and the second lane (21b), and the third lane (22a) and the fourth lane. The opening (16) formed in the partition plate (15a) and the opening (16) formed in the partition plate (15a) partitioning the fifth lane (23a) and the sixth lane (23b) are closed. Are arranged as follows. The discharge member (34) is formed with a small discharge hole (35) at substantially the center thereof. The discharge hole (35) is designed, for example, to have an electric resistance of several MΩ. The discharge hole (35) forms a current path between the hot side electrode (31) and the neutral side electrode (32). The discharge hole (35) as described above serves as a current density concentration portion that increases the current density of the current path between the electrode pair (31, 32).

  As shown in FIG. 4, when a voltage is applied between both electrodes (31, 32), the current density in the current path increases in the discharge hole (35) of the discharge member (34), so that water is discharged. Bubbles (C) are formed by vaporization by Joule heat. As a result, the electrodes (31, 32) and water have the same potential, and the interface between the bubbles (C) and water serves as an electrode to generate discharge (spark discharge). That is, in this discharge, since both electrodes (31, 32) do not become discharge electrodes, it is possible to suppress deterioration of the electrodes (31, 32) due to discharge.

  The spraying devices (40a to 40c) include a first spraying device (40a), a second spraying device (40b), and a third spraying device (40c). A first inflow pipe (43a) is connected to the first spray device (40a), a second inflow pipe (43b) is connected to the second spray device (40b), and a first inflow pipe (43c) is connected to the third spray device (40c). Three inflow pipes (43c) are connected. Each spray device (40a-40c) sprays the water supplied from each inflow pipe (43a-43c), and makes it flow into a processing tank (11).

  Each inflow pipe (43a to 43c) is provided with an electromagnetic valve (44a to 44c) that can be switched between an open state and a closed state. Specifically, a first electromagnetic valve (44a) is provided in the first inflow pipe (43a), a second electromagnetic valve (44b) is provided in the second inflow pipe (43b), and a third inflow pipe (43c) is provided. A third solenoid valve (44c) is provided. Water is supplied from the first inlet pipe (43a) to the first spraying device (40a) only when the first electromagnetic valve (44a) is in the open state. Water is supplied from the second inflow pipe (43b) to the second spray device (40b) only when the second electromagnetic valve (44b) is in the open state. Water is supplied from the third inlet pipe (43c) to the third spray device (40c) only when the third electromagnetic valve (44c) is in the open state.

  Each spray device (40a-40c) includes a nozzle header (41a-41c) and a plurality of spray nozzles (42a-42c) corresponding to each lane (21a, 21b, 22a, 22b, 23a, 23b). Yes.

  The nozzle headers (41a to 41c) include a first nozzle header (41a), a second nozzle header (41b), and a third nozzle header (41c). Each nozzle header (41a to 41c) is formed in an elongated tubular shape, and an inflow pipe (43a to 43c) is connected to a side surface. Specifically, the first inflow pipe (43a) is connected to the first nozzle header (41a), the second inflow pipe (43b) is connected to the second nozzle header (41b), and the third nozzle header (41c) is connected. A third inflow pipe (43c) is connected. Each nozzle header (41a-41c) distributes the water from a corresponding inflow pipe (43a-43c) to each spray nozzle (42a-42c).

  The spray nozzles (42a to 42c) include a first spray nozzle (42a), a second spray nozzle (42b), and a third spray nozzle (42c). Each of the spray nozzles (42a to 42c) is provided in two at a predetermined interval in the longitudinal direction of the corresponding nozzle header (41a to 41c). Specifically, two first spray nozzles (42a) are provided in the first nozzle header (41a) corresponding to the first lane (21a) and the second lane (21b). Two second spray nozzles (42b) are provided in the second nozzle header (41b) corresponding to the third lane (22a) and the fourth lane (22b). Two third spray nozzles (42c) are provided in the third nozzle header (41c) corresponding to the fifth lane (23a) and the sixth lane (23b). The water flowing through the inflow pipes (43a to 43c) flows into the nozzle headers (41a to 41c) and becomes granular (droplets) from the spray nozzles (42a to 42c), and the corresponding lanes (21a, 21b, 22a). , 22b, 23a, 23b). At this time, since the water sprayed from the spray nozzles (42a to 42c) becomes granular (droplets), air is interposed between the particles (between the droplets), and the electrical resistance is increased. By carrying out like this, the water which flows through an inflow pipe (43a-43c) and the water of a processing tank (11) are electrically insulated. In addition, the electrical resistance between an inflow pipe | tube (43a-43c) and a processing tank (11) will be several hundred M (ohm) or more.

  The auxiliary water tank (50) is a water tank provided below the outlet (17) of the treatment tank (11). The auxiliary water tank (50) is formed in a substantially rectangular box in plan view, and opens upward. The treated water that has flowed out from the outlet (17) of the treatment tank (11) flows into the auxiliary water tank (50). Here, the level of the water stored in the auxiliary water tank (50) is lower by a predetermined distance than the tips of the outlet part (17) or the slope (18). For this reason, when the water of a processing tank (11) flows down from an outflow part (17) to an auxiliary water tank (50), it becomes a ridge. The water flowing into the auxiliary water tank (50) becomes soot (granular or droplets), and air is interposed between the particles (between the droplets), increasing the electrical resistance. By doing so, the water stored in the treatment tank (11) and the water stored in the auxiliary water tank (50) are electrically insulated. The electrical resistance between the treatment tank (11) and the auxiliary water tank (50) is several hundred MΩ or more.

  Inside the auxiliary water tank (50), a concentration sensor (61) for detecting the concentration of the sterilizing factor of water in the auxiliary water tank (50) is provided. The concentration sensor (61) indirectly detects the concentration of the bactericidal factor of the water by detecting the hydrogen peroxide concentration of the water in the auxiliary water tank (50). The detection value of the density sensor (61) is input to the control unit (60).

  An outflow pipe (45) is connected to the side surface of the auxiliary water tank (50), and a pump (46) is provided in the outflow pipe (45). When this pump (46) is driven, the water in the auxiliary water tank (50) flows out from the outflow pipe (45) and is supplied to the outside.

  The control unit (60) controls the operation of the water treatment unit (10). The control unit (60) is wired or connected to at least the solenoid valve (44a to 44c) of the inflow pipe (43a to 43c), the power supply unit (33), the concentration sensor (61), and the pump (46) of the outflow pipe (45). Connected wirelessly. The control unit (60) switches between the open state and the closed state of the solenoid valves (44a to 44c) according to the input from the concentration sensor (61). Further, the control unit (60) drives or stops the power supply unit (33) according to the input from the concentration sensor (61). Further, the control unit (60) drives or stops the pump (46).

-Driving action-
The operation of the water treatment unit (10) of this embodiment will be described with reference to FIG. In the water treatment unit (10) of the present embodiment, the concentration increasing operation for increasing the concentration of the sterilizing factor in the water in the processing tank (11) to generate sterilizing water, and the generated sterilizing water is discharged from the processing tank (11). Distribution operation is performed.

  The concentration raising operation and the distribution operation are performed by the control unit (60). Further, the concentration increasing operation and the distribution operation are sequentially performed in the first flow path (21), the second flow path (22), and the third flow path (23), respectively.

  During the operation of the water treatment unit (10), the pump (46) is always driven by the control unit (60), so that the sterilizing water continues to be supplied from the water treatment unit (10) to the outside.

<Density increase operation>
The concentration increasing operation will be described by taking the first flow path (21) as an example.

  In the concentration increasing operation, as shown in FIG. 5, the control unit (60) closes the first electromagnetic valve (44a) of the first inflow pipe (43a), that is, the first flow path of the processing tank (11). The inflow of water into (21) and the outflow of water from the first flow path (21) are stopped. Then, the power supply unit (33) is driven by the control unit (60) over a predetermined time, and a square wave voltage is applied from the power supply unit (33) to the electrode pair (31, 32) of the first flow path (21). Is applied.

  When a square wave voltage is applied to the electrode pair (31, 32), the current density in the discharge hole (35) of the discharge member (34) increases, and Joule heat is generated in the discharge hole (35). As a result, in the discharge member (34), the vaporization of water is promoted inside the discharge hole (35) and in the vicinity of the entrance / exit to form bubbles (C) as a gas phase. This bubble (C) will be in the state which covers the whole region of the discharge hole (35), as shown in FIG. In this state, the bubble (C) functions as a resistor that prevents conduction between the electrodes (31, 32) via water. Thereby, there is almost no potential difference between the electrode (31, 32) and water, and the interface between the bubble (C) and water becomes the electrode. Then, dielectric breakdown occurs in the bubbles (C), and discharge (spark discharge) occurs.

  As described above, when a discharge is generated in the bubble (C), a bactericidal factor (an active species such as a hydroxyl radical) is generated in the water in the first flow path (21) of the treatment tank (11). . Thereby, the disinfection factor density | concentration of the water of a 1st flow path (21) is raised.

  The concentration increasing operation in the second flow path (22) and the third flow path (23) is the same as the concentration increasing operation in the first flow path (21), and thus description thereof is omitted.

<Distribution>
In the water treatment unit (10) of this embodiment, the distribution operation is performed following the concentration increasing operation. This distribution operation will be described by taking the first flow path (21) as an example.

  In the circulation operation, as shown in FIG. 5, the first electromagnetic valve (44a) of the first inflow pipe (43a) is opened by the control unit (60), and the first flow path ( Water flows into 21) and treated water (that is, sterilized water) flows out of the first flow path (21). While the circulation operation is being performed in the first flow path (21), no voltage is applied from the power source section (33) to the electrode pair (31, 32) of the first flow path (21).

  The voltage is applied to the electrode pair (31, 32) of the first flow path (21) not only during the flow operation but also when the concentration increasing operation is not performed in the first flow path (21). Is not applied. That is, the first discharge unit (30a) pauses the discharge while the concentration increasing operation in the first channel (21) is stopped. The same applies to the second discharge unit (30b) and the third discharge unit (30c).

  The sterilizing water flowing out from the first flow path (21) of the treatment tank (11) flows into the auxiliary water tank (50). The sterilizing water that has flowed into the auxiliary water tank (50) flows out from the outflow pipe (45) by the pump (46) driven by the control unit (60) and is supplied to the outside.

  In addition, since the distribution | circulation operation | movement in a 2nd flow path (22) and a 3rd flow path (23) is the same as the distribution | circulation operation | movement in a 1st flow path (21), description is abbreviate | omitted.

<Switching each operation>
As shown in FIG. 5, in the water treatment unit (10) of the present embodiment, the flow paths (21 to 23) for performing the concentration increasing operation are sequentially switched, and the flow paths (21 to 23) for performing the distribution operation are sequentially switched. .

  At time t1, the concentration increasing operation is started in the first channel (21). While the concentration increasing operation is being performed in the first flow path (21), an alternating voltage is applied from the power source unit (33) to the electrode pair (31, 32) of the first flow path (21). 1 The solenoid valve (44a) is closed.

  At time t2, the concentration increasing operation is stopped in the first channel (21), and the concentration increasing operation is started in the second channel (22). At time t2, the distribution operation is started in the first flow path (21). That is, at the time t2, the connection destination of the power supply unit (33) is switched from the electrode pair (31, 32) of the first flow path (21) to the electrode pair (31, 32) of the second flow path (22). The first electromagnetic valve (44a) is opened. Further, the second electromagnetic valve (44b) is closed.

  At time t3, the concentration increasing operation is stopped in the second channel (22), and the concentration increasing operation is started in the third channel (23). At time t3, the distribution operation is stopped in the first channel (21), and the distribution operation is started in the second channel (22). That is, at time t3, the connection destination of the power supply unit (33) is switched from the electrode pair (31, 32) of the second flow path (22) to the electrode pair (31, 32) of the third flow path (23), The second solenoid valve (44b) is opened. Further, the third solenoid valve (44c) is closed.

  At time t4, the concentration increasing operation is stopped in the third channel (23), and the concentration increasing operation is started again in the first channel (21). At time t4, the distribution operation is stopped in the second channel (22), and the distribution operation is started in the third channel (23). That is, at the time t4, the connection destination of the power supply unit (33) is switched from the electrode pair (31, 32) of the third flow path (23) to the electrode pair (31, 32) of the first flow path (21). The third electromagnetic valve (44c) is opened. Further, the first electromagnetic valve (44a) is closed.

  In this embodiment, the duration of the concentration increasing operation in each channel (21-23) and the duration of the circulation operation in each channel (21-23) are both Δt. In addition, it is desirable that the duration time of the concentration increasing operation in each flow path (21 to 23) is equal to each other. On the other hand, the duration of the concentration increasing operation and the duration of the distribution operation in each channel (21 to 23) do not necessarily need to match.

-Effect of the embodiment-
In the water treatment unit (10) of the present embodiment, since the discharge units (30a to 30c) are provided in each of the plurality of flow paths (21 to 23), only one discharge unit (30a to 30c) is provided. More sterilized water can be produced compared to the case where it is used.

  Further, the flow paths (21 to 23) in which the concentration raising operation is performed are sequentially switched, and the flow paths (21 to 23) in which the distribution operation is performed are also sequentially switched. That is, during the operation of the water treatment unit (10), sterilizing water is always generated in any of the flow paths (21 to 23), and sterilizing water is supplied from any of the other flow paths (21 to 23). leak. Thereby, sterilization water can be continuously supplied as the whole water treatment unit (10).

  Moreover, in the water treatment unit (10) of this embodiment, one power supply part (33) applies a voltage in order with respect to the electrode pair (31, 32) of a some flow path (21-23). For this reason, using only one power supply part (33), a bactericidal factor can be generated in several flow paths (21-23), and the bactericidal water of arbitrary bactericidal factor density | concentration can be produced | generated continuously. Therefore, according to the present embodiment, the water treatment unit can minimize the number of power supply units (33) while generating sterilizing water having an arbitrary sterilizing factor concentration using a plurality of flow paths (21 to 23). (10) The increase in manufacturing cost can be suppressed.

  Moreover, since the ratio of the positive electrode side and the negative electrode side is made equal in the voltage waveform generated by the power supply unit (33), elution of the electrode pair (31, 32) can be suppressed. In addition, since the alternating voltage waveform generated by the power supply unit (33) can suppress the deposition of metal or the like from each electrode (31, 32), stable discharge can be performed.

-Modification of the embodiment-
A modification of the embodiment will be described. In the water treatment unit (10) of this variation, the sterilizing factor concentration of the sterilizing water generated in the treatment tank (11) is adjusted by the control unit (60).

  Specifically, first, the hydrogen peroxide concentration (indirectly indicating the bactericidal factor concentration) of the sterilizing water generated by the concentration sensor (61), that is, the auxiliary water tank (50) is detected, and the detected value Is output to the control unit (60). The control unit (60) adjusts the time for performing the concentration increasing operation and the time for performing the distribution operation in each channel (21 to 23) so that the detection value of the concentration sensor (61) approaches the preset target value. To do. When the detection value of the concentration sensor (61) is lower than the target value, the control unit (60) increases the time for performing the concentration increasing operation, shortens the time for performing the distribution operation, or both. Do. On the other hand, when the detected value of the concentration sensor (61) is higher than the target value, the control unit (60) shortens the time for performing the concentration increasing operation, lengthens the time for performing the distribution operation, or Do both.

-Effect of modification-
In the water treatment unit (10) of this modification, the control unit (60) adjusts the sterilizing factor concentration of the sterilizing water based on the detection value of the concentration sensor (61). Thereby, the sterilization water of arbitrary sterilization factor density | concentrations can be produced | generated by setting the target value of the detection value of a density | concentration sensor (61).

<< Other Embodiments >>
In the said embodiment, although each discharge unit (30a-30c) discharges only while concentration raising operation is performed in the flow path (21-23) in which this discharge unit (30a-30c) was provided, For example, the discharge may always be performed. In this case, it is necessary to provide one power supply part (33) for each flow path (21 to 23).

  Moreover, in the said embodiment, although the density | concentration sensor (61) is provided in the auxiliary water tank (50), it is not restricted to this, For example, a density | concentration sensor (61) is each flow path (21-23 of a process tank (11)) ). Further, the concentration increasing operation and the distribution operation may be performed over a predetermined time without providing the concentration sensor (61).

  Moreover, in the said embodiment, although the flow path (21-23) which performs density | concentration raise operation | movement and distribution | circulation operation | movement switches sequentially, it is not restricted to this, Concentration raise | lift operation | movement and distribution | circulation are arbitrary in each flow path (21-23). An operation may be performed.

  Moreover, in the said embodiment, although the three flow paths (21-23) are formed in the processing tank (11), not only this but a single flow path is provided in a processing tank (11), You may make it perform a density | concentration raise operation | movement and a distribution | circulation operation alternately in the said flow path. In this case, treated water (sterilizing water) is intermittently supplied to the outside.

  As described above, the present invention is useful for a water treatment unit.

10 Water treatment unit
11 Treatment tank
21 First channel (channel)
22 Second channel (channel)
23 Third flow path (flow path)
31 Electrode (discharge part)
32 electrodes (discharge section)
34 Discharge member (discharge part)
60 Control unit
61 Concentration sensor

Claims (3)

A water treatment unit (10) comprising a treatment tank (11) for storing water and a discharge section (31, 32, 34) for generating discharge so as to produce a sterilizing factor in the water of the treatment tank (11) There,
In a state where the inflow of water into the treatment tank (11) and the outflow of water from the treatment tank (11) are stopped, the discharge part (31, 32, 34) generates a discharge and the treatment tank (11 ) To increase the concentration of bactericidal factors in water
After completion of the concentration increasing operation, the flow is configured to perform a flow operation in which water flows into the treatment tank (11) and the treated water flows out of the treatment tank (11) .
In the processing tank (11), a plurality of flow paths (21 to 23) are formed,
Each of the flow paths (21 to 23) is provided with the discharge part (31, 32, 34),
Each of the flow paths (21 to 23) is configured to perform the concentration increasing operation and the circulation operation,
All the discharge units (31, 32, 34) are switchably connected to each other, and a predetermined voltage is applied to any one of the discharge units (31, 32, 34). ) With a power supply (33) that causes discharge,
When the concentration increasing operation in one of the flow paths (21 to 23) is completed, the voltage is applied by the power source unit (33) so that the concentration increasing operation in the next flow path (21 to 23) is started. By sequentially switching the applied discharge section (31, 32, 34), the flow path (21-23) for performing the concentration increasing operation is sequentially switched,
Each of the discharge parts (31, 32, 34) pauses the discharge during the stop of the concentration increasing operation in the flow path (21-23) provided with the discharge part (31, 32, 34),
When the flow operation in one of the flow paths (21 to 23) is completed, the flow path (21 to 23) that performs the flow operation so that the flow operation in the next flow path (21 to 23) is started. 23) A water treatment unit characterized by sequentially switching . In claim 1 ,
A concentration sensor (61) for detecting the sterilizing factor concentration of water flowing out of the treatment tank (11);
A control unit for adjusting the time that the detected value of the density sensor (61) performs a performing time and the flow behavior of the density raising operation so as to approach a predetermined target value (60), the detection value is the target A control unit (60) that shortens the time for performing the circulation operation when the value is lower than the value, and lengthens the time for the circulation operation when the detected value is higher than the target value. A water treatment unit characterized by In claim 2,
The concentration increasing operation and the circulation operation are alternately performed once each.
A water treatment unit characterized by that.

Images