JP6427914B2 - 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 with 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, in the water treatment unit of Patent Document 1, water flows in the order of the inflow path, the treatment tank, and the outflow path, and the sterilization process is performed only once in the treatment tank. At this time, a bactericidal factor is produced in water, but there is a limit to the amount of bactericidal factor produced by one sterilization treatment. Therefore, the water treatment unit of Patent Document 1 has room for improvement in that it is difficult to generate water having a sufficiently high bactericidal factor concentration.

  This invention is made | formed in view of this point, The objective is to make it possible to produce | generate water with a sufficiently high bactericidal factor density | concentration.

  The first invention is directed to the water treatment unit (10). The first invention includes a treatment tank (11) for storing water, an auxiliary water tank (50) into which treated water that has flowed out of the treatment tank (11) flows, and the water in the treatment tank (11). The discharge unit (31 to 34) that generates a discharge so as to generate a sterilizing factor, and the water flowing out from the treatment tank (11) is dropletized and supplied to the auxiliary water tank (50) and the auxiliary water tank (50 ) Is supplied as droplets to the treatment tank (11) to electrically insulate the water in the treatment tank (11) from the water in the auxiliary water tank (50). ), And discharging the discharge part (31-34) while circulating water between the treatment tank (11) and the auxiliary water tank (50), thereby increasing the concentration of bactericidal factors in water The operation and the supply operation of supplying the treated water in the auxiliary water tank (50) to the outside after the circulation discharge operation is completed. Auxiliary partition plate (51) provided in the auxiliary water tank (50) and configured to divide the internal space of the auxiliary water tank (50) into a high concentration region (53) and a low concentration region (54) When the circulation discharge operation is performed, water is circulated between the treatment tank (11) and the high concentration region (53) of the auxiliary water tank (50), while in the supply operation, the high concentration The water of the region (53) and the water of the low concentration region (54) are mixed and supplied to the outside.

  In the first invention, the circulating discharge operation and the supply operation are performed. In the circulating discharge operation, a sterilizing factor is generated in the water of the treatment tank (11) by the discharge of the discharge parts (31 to 34). Then, water is circulated between the treatment tank (11) and the auxiliary water tank (50) while generating a sterilizing factor in the treatment tank (11). Thereby, the sterilizing factor concentration of the water circulating between the treatment tank (11) and the auxiliary water tank (50) increases while the circulating discharge operation is performed. Therefore, the disinfection factor density | concentration of the water after a process can be raised suitably by adjusting the time which performs a circulation discharge operation. The treated water is supplied from the auxiliary water tank (50) to the outside by a supply operation.

  In the first invention, since the water moving between the treatment tank (11) and the auxiliary water tank (50) becomes droplets, air is interposed between the droplets. Thereby, the electrical resistance between a processing tank (11) and an auxiliary water tank (50) becomes high, and the water of a processing tank (11) and the water of an auxiliary water tank (50) are electrically insulated.

  Furthermore, in 1st invention, the disinfection factor density | concentration of water is raised in the high concentration area | region (53) of a processing tank (11) and an auxiliary water tank (50). On the other hand, the bactericidal factor concentration of the water in the low concentration region (54) of the auxiliary water tank (50) is substantially constant. Then, water having a high bactericidal factor concentration in the high concentration region (53) and water having a low bactericidal factor concentration in the low concentration region (54) are mixed to produce sterilizing water having a predetermined bactericidal factor concentration. The produced sterilizing water is supplied to the outside.

  Here, the advantage of dividing the internal space of the auxiliary water tank (50) into the high concentration region (53) and the low concentration region (54) will be described.

  The bactericidal factor can change to hydrogen peroxide in water. That is, in the circulating discharge operation, the sterilization factor generated in the treatment tank (11) due to the discharge of the discharge parts (31 to 34) may be changed to hydrogen peroxide in the auxiliary water tank (50) or the like. On the other hand, when a discharge is applied to hydrogen peroxide, a bactericidal factor is generated from the hydrogen peroxide. That is, even if the sterilization factor generated in the treatment tank (11) is changed to hydrogen peroxide, the sterilization factor can be generated again by sending the hydrogen peroxide to the treatment tank (11) and causing the discharge to act. it can. Therefore, if the amount of sterilizing factor generated per unit time by the discharge of the discharge part (31 to 34) is constant, the more hydrogen peroxide contained in the water flowing into the treatment tank (11) from the auxiliary water tank (50) As a whole, many bactericidal factors are produced. That is, by circulating water containing more hydrogen peroxide, the concentration of the bactericidal factor in the water can be increased more quickly as the entire water treatment unit (10).

  If the internal space of the auxiliary water tank (50) is not divided, water circulates between the treatment tank (11) and the entire auxiliary water tank (50), so that hydrogen peroxide diffuses throughout the auxiliary water tank (50). To do. On the other hand, when the auxiliary water tank (50) is divided into a high concentration area (53) and a low concentration area (54), water circulates between the treatment tank (11) and the high concentration area (53). Most of the hydrogen peroxide remains in the high concentration region (53). Therefore, in the water treatment unit (10) of the present invention, water containing more hydrogen peroxide flows from the auxiliary water tank (50) into the treatment tank (11) than when the internal space of the auxiliary water tank (50) is not divided. Can be made.

  As mentioned above, according to this invention, compared with the case where water is circulated between the processing tank (11) and the whole auxiliary water tank (50), as a whole water treatment unit (10), the disinfection factor density | concentration in water more rapidly. Is increased.

According to a second aspect of the present invention, in the first aspect of the invention, the generation of ultrasonic waves that increases the concentration of a bactericidal factor in water by irradiating at least one water of the treatment tank (11) or the auxiliary water tank (50) with ultrasonic waves. It is provided with a part (62).

In 2nd invention, the bactericidal factor density | concentration in water is raised by the ultrasonic wave generation part (62). This utilizes the fact that when water containing hydrogen peroxide is irradiated with ultrasonic waves, the hydrogen peroxide changes to a bactericidal factor. In the water of the treatment tank (11) or the auxiliary water tank (50), the bactericidal factor generated by the discharge of the discharge parts (31 to 34) may change to hydrogen peroxide. In the present invention, the concentration of the bactericidal factor in the water is increased by irradiating the water in the treatment tank (11) or the auxiliary water tank (50) containing hydrogen peroxide with ultrasonic waves to generate the bactericidal factor.

  According to the present invention, the concentration of the sterilizing factor of the treated water can be appropriately increased by adjusting the time for performing the circulating discharge operation. That is, water having a sufficiently high bactericidal factor concentration can be generated. Moreover, according to this invention, the water of a processing tank (11) and the water of an auxiliary water tank (50) can be reliably electrically insulated by the simple method of making water into droplets. Furthermore, according to the present invention, water is circulated between the treatment tank (11) and the high concentration region (53) of the auxiliary water tank (50), so that the water treatment unit (10) as a whole can be more quickly. In addition, the concentration of water sterilizing factor can be increased. That is, water having a sufficiently high bactericidal factor concentration can be generated more quickly.

In addition, according to the second aspect of the invention, since the ultrasonic generator (62) for increasing the concentration of the bactericidal factor in water is additionally provided to the discharge unit (31 to 34), water having a sufficiently high bactericidal factor concentration is provided. It can be generated more quickly.

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 a voltage waveform generated by the high voltage generation unit according to the embodiment. FIG. 4 is an enlarged view showing a part of the discharge unit according to 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 spray device (40), an auxiliary water tank (50), and a control unit ( 60). An inflow pipe (43) is connected to the spray device (40), and an outflow pipe (44) and an auxiliary outflow pipe (45) are connected to the auxiliary water tank (50). The water treatment unit (10) allows water to flow from the inflow pipe (43) to the treatment tank (11) via the spray device (40), and into the water by the discharge unit (30a to 30c) in the treatment tank (11). A sterilizing factor is generated to generate sterilizing water, and the generated sterilizing water is discharged from the outflow pipe (44) or the auxiliary 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 processing tank (11) has a bottom (12) formed in a substantially rectangular flat plate in plan view, and a horizontally long substantially rectangular flat plate, and in the width direction of the bottom (12). Side wall portions (13) extending upward from both opposing sides (that is, both sides extending in the left-right direction in FIG. 1), and the side wall portions (13) of the bottom (12) formed on a horizontally long substantially rectangular flat plate. And 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).

  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 high voltage generator (33) connected to the electrode pair (31, 32) and applying a predetermined voltage to the 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), the high voltage generator (33), 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.

  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 electrode (31) is connected to the high voltage generator (33). 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 high voltage generator (33). 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 high voltage generator (33) is configured by a power source that applies a predetermined voltage to the electrode pair (31, 32). In the present embodiment, as shown in FIG. 3, for example, the high voltage generator (33) is configured to apply an alternating waveform voltage in which positive and negative are switched to the electrode pair (31, 32). Yes. 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 spray device (40) sprays the water supplied from the inflow pipe (43) and flows it into the treatment tank (11). The inflow pipe (43) is provided with a first electromagnetic valve (47a) that can be switched between an open state and a closed state, and the spray device is used only when the first electromagnetic valve (47a) is in the open state. Water is supplied to (40). The spraying device (40) includes a nozzle header (41) and a plurality of spray nozzles (42) corresponding to the lanes (21a, 21b, 22a, 22b, 23a, 23b).

  The nozzle header (41) is formed in an elongated tubular shape, and an inflow pipe (43) is connected to a side surface thereof, and water from the inflow pipe (43) is diverted to each spray nozzle (42).

  A plurality of spray nozzles (42) are provided at predetermined intervals in the longitudinal direction of the nozzle header (41). The spray nozzle (42) is provided corresponding to each lane (21a, 21b, 22a, 22b, 23a, 23b). The water that has flowed through the inflow pipe (43) flows into the nozzle header (41), becomes granular (droplets) from the spray nozzle (42), and corresponds to the lanes (21a, 21b, 22a, 22b, 23a, 23b). ) Is sprayed. At this time, the water sprayed from the spray nozzle (42) becomes granular (formed into droplets), so that air is interposed between the particles (between the droplets), and the electrical resistance is increased. By doing so, the water flowing through the inflow pipe (43) and the water in the treatment tank (11) are electrically insulated. The electrical resistance between the inflow pipe (43) and the treatment tank (11) is several hundred MΩ or more.

  Here, when performing the circulation discharge operation | movement mentioned later, the water which flowed out from the auxiliary water tank (50) flows through an inflow pipe (43), and is supplied to a spraying apparatus (40). Moreover, as above-mentioned, a spraying apparatus (40) electrically insulates the water which flows through an inflow pipe (43), and the water of a processing tank (11). Therefore, the water flowing out from the auxiliary water tank (50) and the water in the treatment tank (11) are electrically insulated by the spray device (40). Thus, the spray device (40) constitutes the insulating part (70) of the present invention.

  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. As will be described later, the internal space of the auxiliary water tank (50) is divided into a high concentration region (53) and a low concentration region (54). The treated water that has flowed out from the outlet (17) of the treatment tank (11) flows into the high concentration region (53) of 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 that flows into the auxiliary water tank (50) becomes soot (granulated or formed into droplets), so that air is interposed between the particles (between the droplets) and the electrical resistance is increased. 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. The outlet part (17) constitutes the insulating part (70) of the present invention.

  The auxiliary water tank (50) is provided with an auxiliary partition plate (51) for dividing the internal space of the auxiliary water tank (50) into a high concentration region (53) and a low concentration region (54). The auxiliary partition plate (51) is a flat plate-like member extending in a direction (depth direction in FIG. 1) orthogonal to the water flow direction in the treatment tank (11). The auxiliary partition plate (51) has both sides in the longitudinal direction in contact with the inner surface of the auxiliary water tank (50), and the lower side in contact with the bottom surface of the auxiliary water tank (50). The auxiliary partition plate (51) is provided closer to the treatment tank (11) than the central part of the auxiliary water tank (50). One communication hole (52) is formed in the central portion of the auxiliary partition plate (51). The communication hole (52) is a small circular hole that penetrates the auxiliary partition plate (51) in the thickness direction. The communication holes (52) may be holes having other shapes such as an elliptical shape or a polygonal shape, or a plurality of holes may be formed, or other than the central portion of the auxiliary partition plate (51). It may be formed in this part.

  A high concentration area | region (53) is a part (left side part in FIG. 1) near the process tank (11) rather than the auxiliary partition plate (51) among the internal spaces of the auxiliary water tank (50). The low concentration region (54) is a portion of the auxiliary water tank (50) that is farther from the treatment tank (11) than the auxiliary partition plate (51) (right side portion in FIG. 1). The high concentration region (53) and the low concentration region (54) communicate with each other through the communication hole (52). Moreover, since the auxiliary partition plate (51) is provided closer to the treatment tank (11) than the central portion of the auxiliary water tank (50), the high concentration region (53) is smaller than the low concentration region (54).

  An ultrasonic transducer (62) is attached to the lower surface of the auxiliary water tank (50). The ultrasonic vibrator (62) irradiates the water in the auxiliary water tank (50) with ultrasonic waves, thereby changing the hydrogen peroxide contained in the water to a bactericidal factor to increase the bactericidal factor concentration in the water. . The ultrasonic transducer (62) constitutes the ultrasonic generator of the present invention.

  An outflow pipe (44) is connected to one side surface (left side surface in FIG. 1) of the auxiliary water tank (50). One end of the outflow pipe (44) communicates with the high concentration region (53) of the auxiliary water tank (50). The other end of the outflow pipe (44) is configured to supply treated water to the outside. The outflow pipe (44) is provided with a first electric valve (49a), a pump (48), a concentration sensor (61), and a second electromagnetic valve (47b) in this order from the auxiliary water tank (50) side. The first motor operated valve (49a) is adjustable in opening. The pump (48) is driven or stopped. The concentration sensor (61) indirectly detects the concentration of the bactericidal factor of the water by detecting the hydrogen peroxide concentration of the water flowing through the outflow pipe (44). The second solenoid valve (47b) can be switched between an open state and a closed state.

  An auxiliary outflow pipe (45) is connected to the other side surface (right side surface in FIG. 1) of the auxiliary water tank (50). One end of the auxiliary outflow pipe (45) communicates with the low concentration region (54) of the auxiliary water tank (50). The other end of the auxiliary outflow pipe (45) is connected to a portion of the outflow pipe (44) between the first motor operated valve (49a) and the concentration sensor (61). The auxiliary outflow pipe (45) is provided with a second motor operated valve (49b). The second motor operated valve (49b) can be adjusted in opening.

  Between the outflow pipe (44) and the inflow pipe (43), there is provided a circulation water pipe (46) for communicating the two. One end of the circulation water pipe (46) is connected to a portion of the outflow pipe (44) between the pump (48) and the second solenoid valve (47b), and the other end is connected to the first of the inflow pipe (43). 1 It is connected to the portion between the solenoid valve (47a) and the spray device (40). The circulation water pipe (46) is provided with a third electromagnetic valve (47c). The third electromagnetic valve (47c) can be switched between an open state and a closed state.

  The control unit (60) controls the operation of the water treatment unit (10). The control unit (60) includes at least first to third electromagnetic valves (47a to 47c), first and second motor operated valves (49a, 49b), a high voltage generation unit (33), a pump (48), a concentration sensor ( 61) and the ultrasonic transducer (62) are connected by wire or wirelessly. The control unit (60) switches between the open state and the closed state of the first to third electromagnetic valves (47a to 47c). Moreover, a control part (60) adjusts the opening degree of a 1st and 2nd motor operated valve (49a, 49b). Further, the control unit (60) drives or stops the high voltage generation unit (33). The control unit (60) drives or stops the pump (48). Further, the control unit (60) drives or stops the ultrasonic transducer (62). The control unit (60) performs each control described above in response to an input from the density sensor (61).

-Driving action-
The operation of the water treatment unit (10) of this embodiment will be described. In the water treatment unit (10) of the present embodiment, the discharge unit (30a-30c) is discharged while circulating water between the treatment tank (11) and the auxiliary water tank (50), so that the concentration of bactericidal factor in water And a supply operation for supplying the treated water (sterilizing water) of the auxiliary water tank (50) to the outside after the circulation discharge operation is completed. The circulation discharge operation and the supply operation are performed by the control unit (60).

<Circulating discharge operation>
In the water treatment unit (10) of the present embodiment, a circulating discharge operation is performed to generate sterilized water having a sufficiently high sterilizing factor concentration.

  Specifically, in the circulation discharge operation, the first electromagnetic valve (47a) and the second electromagnetic valve (47b) are closed, and the inflow of water from the outside and the outflow of water to the outside are stopped. Further, the second motor operated valve (49b) is closed. On the other hand, the first motor-operated valve (49a) is opened and the third electromagnetic valve (47c) is opened.

  After each solenoid valve (47a-47c) and each motorized valve (49a, 49b) are in the above state, the pump (48) is driven and the high concentration region of the treatment tank (11) and auxiliary water tank (50) Water circulates between (53). That is, by the pump (48), the water flowing out from the high concentration region (53) of the auxiliary water tank (50) flows through the outflow pipe (44), the circulation water pipe (46) and the inflow pipe (43) and flows into the spray device (40 ). The water supplied to the spraying device (40) is made into droplets by the spraying device (40) and flows into the treatment tank (11). Further, the water flowing out from the treatment tank (11) is made into droplets and flows into the high concentration region (53) of the auxiliary water tank (50). Thus, in the circulating discharge operation, water circulates between the treatment tank (11) and the high concentration region (53) of the auxiliary water tank (50).

  Further, the high voltage generator (33) is driven, and a square wave voltage is applied from the high voltage generator (33) to the electrode pair (31, 32). In the present embodiment, the application of the square wave voltage is performed in all the discharge units (30a to 30c).

  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 of the treatment tank (11). In the circulation discharge operation, the water is circulated between the treatment tank (11) and the auxiliary water tank (50), and the discharge is performed in each discharge unit (30a-30c). The circulating bactericidal factor concentration increases.

  Here, the bactericidal factor may change to hydrogen peroxide in water. That is, in the circulating discharge operation, the sterilization factor generated in the treatment tank (11) by the discharge of each discharge unit (30a to 30c) may be changed to hydrogen peroxide in the auxiliary water tank (50) or the like. On the other hand, when a discharge is applied to hydrogen peroxide, a bactericidal factor is generated from the hydrogen peroxide. That is, even if the sterilization factor generated in the treatment tank (11) is changed to hydrogen peroxide, the sterilization factor can be generated again by sending the hydrogen peroxide to the treatment tank (11) and causing the discharge to act. it can. Therefore, if the amount of sterilization factor generated per unit time by discharge of the discharge units (30a to 30c) is constant, the more hydrogen peroxide contained in the water flowing into the treatment tank (11) from the auxiliary water tank (50) As a whole, many bactericidal factors are produced. That is, by circulating water containing more hydrogen peroxide, the concentration of the bactericidal factor in the water can be increased more quickly as the entire water treatment unit (10).

  If the internal space of the auxiliary water tank (50) is not divided, water circulates between the treatment tank (11) and the entire auxiliary water tank (50), so that hydrogen peroxide diffuses throughout the auxiliary water tank (50). To do. On the other hand, when the auxiliary water tank (50) is divided into a high concentration area (53) and a low concentration area (54), water circulates between the treatment tank (11) and the high concentration area (53). Most of the hydrogen peroxide remains in the high concentration region (53). Therefore, in the water treatment unit (10) of the present embodiment, water containing more hydrogen peroxide is transferred from the auxiliary water tank (50) to the treatment tank (11) than when the internal space of the auxiliary water tank (50) is not divided. Can flow in.

  Therefore, in the water treatment unit (10) of the present embodiment, the concentration of the bactericidal factor in water can be increased more quickly than in the case where water is circulated between the treatment tank (11) and the entire auxiliary water tank (50). Can do. In addition, the smaller the high concentration region (53), the faster the concentration of bactericidal factor in water can be increased.

  In the circulating discharge operation, the ultrasonic vibrator (62) is driven. Thereby, since the ultrasonic wave is irradiated to the hydrogen peroxide contained in the water of the auxiliary water tank (50) and the hydrogen peroxide is changed to the sterilizing factor, the concentration of the sterilizing factor in the water can be increased.

  The circulating discharge operation ends when, for example, the detection value of the concentration sensor (61) reaches a preset threshold value. The circulating discharge operation may be performed over a predetermined time regardless of the detection value of the concentration sensor (61).

<Supply operation>
In the water treatment unit (10) of the present embodiment, following the circulation discharge operation, a supply operation for supplying the generated sterilized water to the outside is performed.

  Specifically, in the supply operation, the third electromagnetic valve (47c) is closed, and water is prevented from flowing from the auxiliary water tank (50) toward the treatment tank (11). Moreover, it becomes possible to supply the sterilization water which flowed out from the auxiliary | assistant water tank (50) outside by the 2nd solenoid valve (47b) being made into an open state.

  The opening degree of the first motor-operated valve (49a) and the second motor-operated valve (49b) is appropriately adjusted in order to adjust the sterilizing factor concentration of the sterilizing water supplied to the outside. That is, in the supply operation, the water in the high concentration region (53) and the water in the low concentration region (54) are mixed and supplied to the outside. Here, as the opening degree of the first motor-operated valve (49a) is increased, sterilized water containing more water in the high concentration region (53) having a higher concentration of sterilizing factor is supplied to the outside. On the other hand, as the opening degree of the second motor-operated valve (49b) is increased, the sterilizing water containing more water in the low concentration region (54) having a low sterilizing factor concentration is supplied to the outside. That is, as the opening degree of the first motor-operated valve (49a) is larger than the opening degree of the second motor-operated valve (49b), sterilizing water having a higher bactericidal factor concentration is supplied to the outside. The opening degree of the first motor-operated valve (49a) and the second motor-operated valve (49b) is adjusted so that the detection value of the concentration sensor (61) approaches a predetermined target value.

  Then, the pump (48) is driven, and the sterilizing water flows through the outflow pipe (44) and is supplied to the outside. The sterilized water supplied to the outside is used for washing vegetables, for example.

  When a large amount of sterilizing water is required outside, the opening degree of the first motor-operated valve (49a) and the second motor-operated valve (49b) must be increased. At this time, if the opening degree of the second motor-operated valve (49b) is increased, the sterilizing factor concentration of the sterilizing water supplied to the outside is lowered as described above. Therefore, when it is necessary to supply a large amount of sterilizing water to the outside, it is difficult to keep the sterilizing factor concentration of the supplied sterilizing water high.

  In this respect, in the water treatment unit (10) of the present embodiment, since the communication hole (52) is formed in the auxiliary partition plate (51), water is supplied from the low concentration region (54) to the auxiliary outflow pipe (45). When the water flows in, a relatively fast water flow occurs so as to pass through the communication hole (52) from the high concentration region (53) toward the low concentration region (54). Thereby, the bactericidal factor contained in the water of the high concentration region (53) diffuses in the water of the low concentration region (54). Therefore, even if the sterilizing factor concentration of the water flowing out from the auxiliary outflow pipe (45) becomes relatively high and a large amount of sterilizing water needs to be supplied to the outside, the sterilizing water having a relatively high sterilizing factor concentration Can be supplied.

-Effect of the embodiment-
In the water treatment unit (10) of the present embodiment, the concentration of the sterilizing factor of the treated water can be appropriately increased by adjusting the time for performing the circulating discharge operation. That is, by performing the circulating discharge operation for a sufficiently long time, water having a sufficiently high bactericidal factor concentration can be generated.

  Moreover, since the high concentration area | region (53) was formed in the inside of the auxiliary water tank (50) by the auxiliary partition plate (51), compared with the case where an auxiliary partition plate (51) is not provided, water disinfection factor density | concentration is quicker. Can be increased. That is, water having a sufficiently high bactericidal factor concentration can be generated more quickly.

  In addition, both water that flows from the treatment tank (11) into the auxiliary water tank (50) and water that flows from the auxiliary water tank (50) into the treatment tank (11) via the outflow pipe (44), etc. are made into droplets. By doing so, the water of the processing tank (11) and the water of the auxiliary water tank (50) are electrically insulated. In this manner, the water in the treatment tank (11) and the water in the auxiliary water tank (50) can be reliably electrically insulated by a simple method of forming water droplets.

  In addition, since the ultrasonic vibrator (62) that increases the concentration of the sterilizing factor in water is provided on the lower surface of the auxiliary water tank (50), in addition to the discharge of the discharge units (30a to 30c), sterilization is also performed by ultrasonic irradiation. Factors can be generated. That is, the ultrasonic vibrator (62) can generate water with a high bactericidal factor concentration more quickly.

  Further, since the small communication hole (52) is formed in the auxiliary partition plate (51), water having a relatively high bactericidal factor concentration can be supplied from the auxiliary outflow pipe (45) communicating with the low concentration region (54). For this reason, even when it is necessary to supply a large amount of sterilizing water to the outside, sterilizing water having a relatively high bactericidal factor concentration can be supplied.

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

<< Other Embodiments >>
In the above embodiment, the high concentration region (53) and the low concentration region (54) communicate with each other through the communication hole (52) formed in the auxiliary partition plate (51). The high concentration region (53) and the low concentration region (54) may be communicated with each other by providing a gap between the auxiliary partition plate (51) and the inner surface of the auxiliary water tank (50). Specifically, a gap is provided between the lower side of the auxiliary partition plate (51) and the bottom surface of the auxiliary water tank (50), or both sides of the auxiliary partition plate (51) in the longitudinal direction and the inner surface of the auxiliary water tank (50). It is conceivable to provide a gap between them.

  Moreover, in the said embodiment, although the auxiliary partition plate (51) is provided in the inside of the auxiliary water tank (50), it is not restricted to this and it is not necessary to provide an auxiliary partition plate (51). In this case, the auxiliary outflow pipe (45) and the second motor operated valve (49b) become unnecessary.

  Moreover, in the said embodiment, although the ultrasonic transducer | vibrator (62) is attached to the lower surface of the auxiliary water tank (50), it is not restricted to this, For example, an ultrasonic transducer | vibrator (62) is the inside of an auxiliary water tank (50). It may be provided in the treatment tank (11). Moreover, you may provide an ultrasonic transducer | vibrator (62) in both a processing tank (11) and an auxiliary water tank (50).

  Moreover, in the said embodiment, although the control part (60) controls operation | movement of each element, such as a solenoid valve (47a-47c), according to the detected value of a concentration sensor (61), it is not restricted to this. For example, the operation of each element such as the electromagnetic valves (47a to 47c) may be controlled according to a predetermined control flow without providing the concentration sensor (61).

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

10 Water treatment unit
11 Treatment tank
31 Electrode (discharge part)
32 electrodes (discharge section)
33 High voltage generator (discharge unit)
34 Discharge member (discharge part)
50 Auxiliary tank
51 Auxiliary divider
53 High concentration region
54 Low concentration region
62 Ultrasonic transducer (Ultrasonic generator)
70 Insulation

Claims (2)

Discharge so as to produce a sterilizing factor in the water in the treatment tank (11) for storing water, the auxiliary water tank (50) into which the treated water that has flowed out of the treatment tank (11) flows, and the treatment tank (11) The water discharged from the treatment tank (11) and the water discharged from the treatment tank (11) into droplets are supplied to the auxiliary water tank (50) and the water discharged from the auxiliary water tank (50) is formed into droplets. An insulating part (70) that electrically insulates the water of the processing tank (11) and the water of the auxiliary water tank (50) by supplying to the processing tank (11).
Circulating discharge operation to increase the concentration of bactericidal factor in water by discharging the discharge part (31-34) while circulating water between the treatment tank (11) and the auxiliary water tank (50);
After the end of the circulation discharge operation, the supply operation is performed to supply the water after the treatment of the auxiliary water tank (50) to the outside,
An auxiliary partition plate (51) provided in the auxiliary water tank (50) and dividing the internal space of the auxiliary water tank (50) into a high concentration region (53) and a low concentration region (54);
When performing the circulation discharge operation, while circulating the water between the treatment tank (11) and the high concentration region (53) of the auxiliary water tank (50),
In the supply operation, the water treatment unit is configured to mix and supply the water in the high concentration region (53) and the water in the low concentration region (54) to the outside. Oite to claim 1,
An ultrasonic generator (62) for increasing the concentration of a bactericidal factor in water by irradiating at least one water of the treatment tank (11) or the auxiliary water tank (50) with ultrasonic waves is provided. Water treatment unit.

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