JP6048142B2 - Water treatment equipment - Google Patents

Description

  The present invention relates to a water treatment apparatus, and more particularly to an insulating structure of a water treatment apparatus.

  Conventionally, as a water treatment apparatus, an apparatus for purifying water by performing discharge in water stored in a treatment tank is known.

  For example, in Patent Document 1, a positive electrode and a negative electrode are arranged in a processing tank, a pulsed high voltage is applied between the positive electrode and the negative electrode, and the process target flows between the positive electrode and the negative electrode. A liquid treatment apparatus (water treatment apparatus) for treating a liquid is disclosed.

JP 2000-93972 A

  By the way, in the liquid treatment device (water treatment device) disclosed in Patent Document 1, since the positive electrode and the negative electrode are arranged in the middle of the flow of water, the inflow side and the outflow of the treatment tank (water treatment unit). There was a problem of electricity flowing into the water on the side.

  This invention is made | formed in view of this point, The place made into the objective is to prevent the electricity from a water treatment part from flowing especially in the inflow side of a water treatment part.

  In order to achieve the above object, according to the present invention, in the inflow-side insulating portion (40), the vertical distance from the tip of the nozzle (42) to the water surface of the water treatment portion (10) is greater than the tip of the nozzle (42). A distance extending means (43a, 43b) for increasing the distance of water movement to the water surface of the water treatment section (10) is provided.

1st invention is provided in the middle of the water channel (3) through which water flows, and it is respectively in the water treatment part (10) which electrically processes water, and the inflow side and the outflow side of the said water treatment part (10), respectively A water treatment device provided with an insulating portion (40, 50) for electrically insulating water from the water treatment portion (10) and the water passage (3), The insulating part (40) is provided above the water treatment part (10) and supplies the water treatment part (10) with water in the water passage (3), and the nozzle (42) Distance extending means (43a, 43b) that makes the water moving distance from the tip of the nozzle (42) to the water surface of the water treatment unit (10) longer than the vertical distance from the tip to the water surface of the water treatment unit (10) ) and provided with said distance extension means (43a) comprises a reflector (43a) der that by colliding the water supplied from the nozzle (42) to drop into the water treatment section (10) It is characterized in.

  In the first invention, the distance between the insulating part (40) provided on the inflow side of the water treatment part (10) in order to electrically insulate the water treatment part (10) and the water in the water passage (3). The extension means (43a, 43b) move water from the tip of the nozzle (42) to the water surface of the water treatment unit (10) rather than the vertical distance from the tip of the nozzle (42) to the water surface of the water treatment unit (10). Since it is configured to increase the distance, electrical insulation at the inflow-side insulation (40) is improved compared to when water in the water passage (3) is supplied vertically downward from the nozzle (10). To do. This improves the electrical insulation between the water treatment section (10) and the water in the water passage (3) on the inflow side, so that the water treatment section (10) particularly on the inflow side of the water treatment section (10). Can prevent electricity from flowing through.

In the first invention, the distance extending means (43a) is the reflector (43a) that collides the water supplied from the nozzle (42) and drops it onto the water treatment section (10). Due to the reflection of water, the moving distance of water from the tip of the nozzle (42) to the water surface of the water treatment unit (10) is longer than the vertical distance from the tip of the nozzle (42) to the water surface of the water treatment unit (10). In addition, the water supplied from the nozzle (42) is granulated due to the collision of water at the reflector (43a), and air is interposed between the water particles. ) And the water in the water passage (3) on the inflow side can be improved.

According to a second aspect , in the first aspect, the water collision surface of the reflector (43a) has water repellency.

In the second aspect of the invention, since the water collision surface of the reflector (43a) has water repellency, it becomes difficult to form a water film on the surface of the reflector (43a), and the water supplied from the nozzle (42). Can be effectively granulated with a reflector (43a).

According to a third invention, in the first or second invention, the nozzle (42) is configured such that the direction of the supplied water is obliquely upward with respect to a horizontal plane. It is.

In the said 3rd invention, while the nozzle (42) is comprised so that the direction of the water supplied to a water treatment part (10) may become diagonally upward with respect to a horizontal surface, it is supplied from a nozzle (42). Since water is configured to be reflected by the reflector (43a), the moving distance of water from the tip of the nozzle (42) to the water surface of the water treatment unit (10) is from the tip of the nozzle (42) to the water treatment unit ( Not only is it longer than the vertical distance to the water surface in 10), but also the air collides with each particle of water supplied from the nozzle (42) due to the collision of water at the reflector (43a). In addition, the electrical insulation between the water treatment section (10) and the water in the water passage (3) on the inflow side can be improved.

4th invention is provided in the middle of the water passage (3) through which water flows, and is respectively provided in the inflow side and outflow side of the water treatment part (10) which electrically processes water, and the said water treatment part (10). A water treatment device provided with an insulating portion (40, 50) for electrically insulating water from the water treatment portion (10) and the water passage (3), The insulating part (40) is provided above the water treatment part (10) and supplies the water treatment part (10) with water in the water passage (3), and the nozzle (42) Distance extending means (43a, 43b) that makes the water moving distance from the tip of the nozzle (42) to the water surface of the water treatment unit (10) longer than the vertical distance from the tip to the water surface of the water treatment unit (10) ) and provided with said nozzle (42) is configured to spray water from the water passage (3), spraying by the distance extension means (43a, 43 b), said nozzle (42) The center line is configured to face in a direction other than the vertically downward direction.

In the fourth aspect of the invention, the nozzle (42) is configured to spray water from the water passage (3), and the distance extension means (43a, 43b) has a center line of spraying by the nozzle (42). Since it is configured to face in a direction other than the vertically downward direction, not only air is interposed between each particle of water supplied from the nozzle (42) but also a water treatment unit ( The water travel distance from the tip of the nozzle (42) to the water surface of the water treatment section (10) is longer than the vertical distance to the water surface of 10), and the electricity in the insulative section (40) on the inflow side Insulation can be improved.

In a fifth aspect based on the fourth aspect , the water treatment section (10) has a treatment tank (11) for containing water supplied from the water passage (3), and the distance extension means ( 43b) is characterized in that water from the nozzle (42) collides with the wall surface in the treatment tank (11) and is dropped into the water treatment section (10). is there.

In the fifth aspect , the distance extending means (43b) is configured to cause water from the nozzle (42) to collide with the wall surface in the treatment tank (11) and drop it onto the water treatment section (10). Because of the reflection of water on the wall surface in the treatment tank (11), the water movement distance from the tip of the nozzle (42) to the water surface of the water treatment unit (10) is changed from the tip of the nozzle (42) to the water treatment unit. In addition to being longer than the vertical distance to the water surface of (10), the water droplets supplied from the nozzle (42) are reduced by the collision of water on the wall surface in the treatment tank (11), and the water As a result, air further intervenes between the particles, and the electrical insulation between the water treatment section (10) and the water in the water passage (3) on the inflow side can be improved.

  In the insulating part (40) on the inflow side, water from the tip of the nozzle (42) to the water surface of the water treatment unit (10) is more than the vertical distance from the tip of the nozzle (42) to the water surface of the water treatment unit (10). Since the distance extending means (43a, 43b) for increasing the moving distance is provided, it is possible to prevent the electricity from the water treatment unit (10) from flowing particularly on the inflow side of the water treatment unit (10). .

1 is a piping system diagram of a water treatment device according to Embodiment 1. FIG. It is a perspective view which shows the water treatment part provided with the insulation part which comprises the water treatment apparatus which concerns on Embodiment 1. FIG. It is sectional drawing which shows the distance extension means which comprises the insulation part of the water treatment apparatus which concerns on Embodiment 1. FIG. It is a figure which shows typically the water treatment apparatus which concerns on Embodiment 1. FIG. It is sectional drawing which shows schematically the discharge unit which comprises the water treatment part of the water treatment apparatus which concerns on Embodiment 1. FIG. It is sectional drawing which expands and shows the area | region X in FIG. It is a voltage waveform generated with the high voltage generation part which comprises the discharge unit of the water treatment part of the water treatment apparatus which concerns on Embodiment 1. FIG. It is sectional drawing which shows the distance extension means which comprises the insulation part of the water treatment apparatus which concerns on Embodiment 2. FIG.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The present invention is not limited to the following embodiments.

Embodiment 1 of the Invention
1-7 has shown Embodiment 1 of the water treatment apparatus which concerns on this invention.

  As shown in FIG. 1, the water treatment device (1a) circulates and stirs the water tank (2) for storing water (including hot water, the same shall apply hereinafter) and the water in the water storage tank (2). And a water circulation circuit (1).

  As shown in FIG. 1, both ends of the water circulation circuit (1), one end of the first flow path pipe (6), and one end of the second flow path pipe (7) are connected to the water storage tank (2). .

  As shown in FIG. 1, the water circulation circuit (1) includes a water pipe (3) provided as a water passage through which water flows and two open / close valves (4a, 4) provided in the middle of the water pipe (3). 4b), provided in the middle of the water pipe (3), provided in the middle of the water pipe (3) and the pump (5a) arranged between the water storage tank (2) and the open / close valve (4a), 2 A water treatment unit (10) and a pump (5b) are sequentially arranged between the two open / close valves (4a, 4b).

  As shown in FIG. 1, one end of the water pipe (3) is connected to the left side of the water tank (2), and the other end is connected to the right side of the water tank (2). It is connected.

  The on-off valves (4a, 4b) are configured as valves that can open and close the flow path of the water pipe (3). Here, the open / close valve (4a) is provided on the water inflow side of the water treatment section (10), and the open / close valve (4b) is provided on the water outflow side of the pump (5b). The open / close valve (4a, 4b) is configured such that when the valve is opened, the water flows through the water pipe (3), and when the valve is closed, the water inside the water pipe (3) stops. ing.

  As shown in FIGS. 2 and 4, the water treatment section (10) has a first insulating section (40) provided on the inflow section (3 a) side of the water pipe (3) and the outflow of the water pipe (3). The water supplied from the water pipe (3) is provided between the second insulating part (50) provided on the side of the part (3b) and the first insulating part (40) and the second insulating part (50). A treatment tank (11) for accommodating and processing, and a first discharge unit (30a) and a second discharge unit (30b) provided in the treatment tank (11) are provided. Here, as shown in FIGS. 1, 2, and 4, the water treatment unit (10) is configured to allow water introduced from the inflow portion (3a) of the water pipe (3) to pass through the first insulating portion (40). Is supplied to the treatment tank (11), and the supplied water is purified by the sterilization factor generated in the discharge unit (30a, 30b) in the treatment tank (11). 50) through the outflow part (3b) to the water pipe (3).

  The first insulating part (40) is configured to electrically insulate the water treatment part (10) and the water in the water pipe (3) on the inflow part (3a) side. Specifically, as shown in FIGS. 2 and 3, the first insulating portion (40) includes a nozzle header (41) connected to the inflow portion (3a) of the water pipe (3), and a water treatment portion (10). ) In the upper part of the figure in the figure, provided for each lane (21a, 21b, 22a, 22b), which is connected to the nozzle header (41) to supply water from the water pipe (3) to the processing section (10) ( 42) and a reflector (43a) that is provided on the water supply side of each nozzle (42) and causes water supplied from each nozzle (42) to collide and drop into the water treatment section (10). Yes.

  As shown in FIGS. 2 and 3, the nozzle (42) is processed by a distance extension means (43b) that functions in the same manner as the distance extension means (43a) described later, It is comprised so that the direction of the water supplied to a part (10) may become diagonally upward with respect to a horizontal surface. The nozzle (42) is configured to spray or spray water on the reflector (43a).

  As shown in FIG. 3, the reflector (43a) has a water treatment section (10) from the tip of the nozzle (42) rather than a vertical distance (La) from the tip of the nozzle (42) to the water surface of the water treatment section (10). Distance extension means (43a) for increasing the water movement distance (Lba + Lbb) to the water surface. Further, as shown in FIGS. 2 and 3, the reflector (43a) is formed in a triangular prism shape, and the surface on which water collides (collision surface) has water repellency by, for example, Teflon (registered trademark) processing. ing. In the present embodiment, the triangular prism-shaped reflector (43a) is exemplified, but the reflector (43a) may have other shapes such as a plate shape, and the collision surface has a concave curved surface shape or a convex curved surface shape. It may be formed in a shape or the like.

  In the 1st insulation part (40) of the said structure, the water sprayed or sprayed from the nozzle (42) collides with the surface of a reflector (43a), and a particle | grain (droplet) or a particle | grain (droplet) becomes smaller. As a result, air is interposed between the grains (between the droplets), and the electrical resistance is increased. Thereby, the water which flows in from the inflow part (3a) of a water piping (3) and the water which flows through a processing tank (11) are electrically insulated. In addition, in the 1st insulation part (40), even if the vertical distance from the front-end | tip of a nozzle (42) to the water surface of a processing tank (11) is short, the water of the inflow part (3a) of a water pipe (3), and a process The electrical resistance between the water in the tank (11) is several hundred MΩ or more.

  The processing tank (11) is a box-shaped water tank formed in a substantially rectangular shape in plan view as shown in FIG. Specifically, as shown in FIG. 2, the treatment tank (11) has a bottom (12) formed in a substantially rectangular flat plate shape, and a bottom portion (12) formed in a substantially rectangular flat plate shape. Long wall portions (13, 13) extending upward in the drawing from the long sides, and short wall portions (14a, 14a, 14) formed in a substantially rectangular flat plate shape and extending upward from the short sides of the bottom portion (12), respectively. 14b), and three partition plates (15a, 15b, 15a, 21b, 22a, 22b) which are provided to partition the interior into four lanes (21a, 21b, 22a, 22b) along the direction of water flow. 15a) and a flow path adjusting plate (18) provided on the inflow portion (3a) side across the four lanes (21a, 21b, 22a, 22b) and formed in a substantially rectangular flat plate shape. Yes. Here, in the treatment tank (11), as shown in FIG. 2, the short wall portion (14b) on the outflow portion (3b) side is formed lower than the short wall portion (14a) on the inflow portion (3a) side. As a result, the upper end of the short wall portion (14b) in the figure is the outlet portion (17). In the treatment tank (11), as shown in FIG. 2, the first lane (21a) and the second lane (21b) constitute the first flow path (21), and the third lane (22a) and the fourth lane (4). The second flow path (22) is configured by the lane (22b). In this embodiment, the treatment tank (11) having four lanes (21a, 21b, 22a, 22b) is illustrated, but the number of lanes formed in the treatment tank (11) is the amount of water to be purified. It can be arbitrarily changed according to.

  The partition plates (15, 15a) are formed of an electrically insulating material. Here, the partition plate (15a) between the first lane (21a) and the second lane (21b) and the partition plate (15a) between the third lane (22a) and the fourth lane (22b) As shown in FIG. 5, a hole (16) penetrating in the thickness direction is formed. And as shown in FIG.2 and FIG.5, the discharge member (34) is provided in the hole (16) of the partition plate (15a) so that the hole (16) may be plugged up. Here, the discharge member (34) is a plate-like insulating member formed of an electrically insulating material such as ceramics.

  As shown in FIGS. 2 and 3, the flow path adjusting plate (18) is provided so that its upper part is arranged behind the water collision surface of the reflector (43a), and its lower part is the surface of the bottom part (12). It is provided so that it may leave | separate, and it is comprised so that the flow of the water of the water piping (3) supplied via a 1st insulation part (40) may be adjusted.

  The first discharge unit (30a) is provided in the first flow path (21) and is configured to purify the water in the first flow path (21).

  The 2nd discharge unit (30b) is provided in the 2nd channel (22), and is constituted so that the water of the 2nd channel (22) may be purified.

  The first discharge unit (30a) and the second discharge unit (30b), that is, the discharge units (30a, 30b), as shown in FIG. 2, FIG. 5, and FIG. 33), a first electrode (31) and a second electrode (32) that are provided so as to face each other in the water in the treatment tank (11), and to which a voltage from the high voltage generator (33) is applied, A minute through hole provided between the first electrode (31) and the second electrode (32) and forming a current path between the first electrode (31) and the second electrode (32) to cause underwater discharge. A partition plate (15a) having the discharge member (34) formed with (35).

  As shown in FIG. 5, the first electrode (31) is provided in the first lane (21a) and the third lane (22a), and is connected to the hot side of the high voltage generator (33), for example.

  As shown in FIG. 5, the second electrode (32) is provided in the second lane (21b) and the fourth lane (22b), and is connected to, for example, the neutral side of the high voltage generator (33).

  The first electrode (31) and the second electrode (32) are formed in a flat plate shape from, for example, a metal material having high corrosion resistance.

  For example, as shown in FIG. 7, the high voltage generator (33) is configured to apply a voltage having an alternating waveform in which positive and negative are switched to the first electrode (31) and the second electrode (32). Yes. Here, the duty ratio of the alternating waveform (square wave) is adjusted so that the ratio between the positive electrode side and the negative electrode side becomes equal, as shown in FIG. In the present embodiment, the voltage waveform applied from the high voltage generator (33) is illustrated as a square waveform, but the voltage waveform applied from the high voltage generator (33) is an alternating type. If it exists, it may be a voltage waveform such as a sine wave.

The through hole (35) formed in the discharge member (34) is designed such that the electric resistance is several MΩ, for example. Here, the through hole (35) serves as a current density concentration portion that increases the current density of the current path between the first electrode (31) and the second electrode (32). Therefore, when a voltage is applied between the first electrode (31) and the second electrode (32), the current in the current path is formed in the through hole (35) of the discharge member (34) as shown in FIG. As the density increases, water is vaporized by Joule heat and bubbles (C) are formed. In the bubbles (C), the interface between the bubbles (C) and water serves as an electrode, and discharge occurs. In this discharge, since the first electrode (31) and the second electrode (32) do not directly discharge, it is possible to prevent the first electrode (31) and the second electrode (32) from being deteriorated by the discharge. can do.

  The second insulating part (50) is configured to electrically insulate the water treatment part (10) and the water in the water pipe (3) on the outflow part (3b) side. Specifically, as shown in FIG. 2, the second insulating portion (50) is provided so as to be connected to the water outflow side of the treatment tank (11), and has four outer wall portions (51a, 51a, 51b, 51c) is a box-shaped water tank. Here, as shown in FIG. 2, the outflow part (3b) of the water pipe (3) is connected to the lower part of the outer wall part (51c). Furthermore, as shown in FIG. 2, the second insulating portion (50) extends from the outlet portion (17) of the treatment tank (11) in a diagonally downward direction to the right in the drawing and drops the water (52a). And the first slope (52a) on the lower right side in the figure, extending from the outer wall (51c) in the lower left direction in the figure and receiving the water that has dropped the first slope (52a) to receive water And a second slope (52b) for dropping water after reversing the flow. Here, each lower end of the first slope (52a) and the second slope (52b) is warped in a curved shape as shown in FIG. Each surface of the first slope (52a) and the second slope (52b) has water repellency by, for example, Teflon (registered trademark) processing. Therefore, in the 2nd insulation part (50), when the water processed by the processing tank (11) exceeds an outflow part (17), as shown in FIG. After the surface of 52a) falls in a bowl shape, it jumps to the right diagonally upward in the figure at the lower end, and the fine water is the upper part in the figure of the second slope (52b) or the upper part in the figure. The outer wall (51c) of the second slope (52b), and then the surface of the second slope (52b) is dropped into a bowl shape, and then the outer wall (51b) ) Will fall to the surface.

  In the 2nd insulation part (50) of the above-mentioned composition, when the water supplied from the outflow part (17) of the processing tub (11) falls on the surface of the outer wall part (51b) or the stored water surface, the first While it becomes bowl-shaped via the slope (52a) and the second slope (52b), and the grains become small, air is interposed between the grains (between the droplets), and the electrical resistance is increased. Thereby, the water which flows through a processing tank (11), and the water of the outflow part (3b) of a water piping (3) are electrically insulated. In the second insulating part (50), even if the vertical distance from the outlet part (17) to the surface of the outer wall part (51b) or the stored water surface is short, the water in the treatment tank (11) and the water pipe The electrical resistance between the outflow part (3b) of (3) and the water becomes several hundred MΩ or more.

  Next, the operation of the water treatment device (1a) having the above configuration will be described.

  In the water treatment device (1a), the water treatment section (10) performs electrical treatment on the water flowing through the water pipe (3).

  Before the operation of the water treatment section (10) starts, the open / close valve (4a, 4b) of the water circulation circuit (1) is opened, and the water in the water storage tank (2) flows through the water pipe (3). And the water which flows through a water pipe (3) flows in into a nozzle header (41) from an inflow part (3a) via a pump (5a), and each lane (21a, 21b, 22a, 22b from a nozzle (42) ) And water is stored in the treatment tank (11). At this time, since the supplied water is granular (droplets), air is interposed between the droplets, and the electrical resistance is increased. Thereby, the water of the inflow part (3a) of a water piping (3) and the water which flows through a processing tank (11) are electrically insulated.

  At the start of operation of the water treatment section (10), the inside of the treatment tank (11) is in a flooded state. When a square wave voltage having the same polarity ratio is applied to the first electrode (31) and the second electrode (32) from the high voltage generator (33), the through hole ( 35) The current density of the current path increases. Here, when the current density of the current path in the through hole (35) increases, Joule heat is generated in the through hole (35), and the Joule heat causes the discharge member (34) to have a through hole (35). In the vicinity of the inside and the entrance / exit, vaporization of water is promoted, and bubbles (C) as a gas phase are formed. This bubble (C) will be in the state which covers the whole region of a through-hole (35), as shown in FIG. In this state, the bubble (C) functions as a resistance that prevents conduction through water between the first electrode (31) and the second electrode (32). Thereby, there is almost no potential difference between the first electrode (31) and the second electrode (32) and water, and the interface between the bubble (C) and water becomes the electrode. Therefore, dielectric breakdown occurs in the bubbles (C), and discharge occurs. And when discharge is performed in the bubbles (C), a bactericidal factor (an active species such as a hydroxyl radical) is generated in the water of the treatment tank (11).

  Then, the water which flows through each lane (21a, 21b, 22a, 22b) of a processing tank (11) is supplied to a 2nd insulation part (50) from an outflow port part (17). And in the 2nd insulating part (50), when the supplied water falls on the surface of an outer wall part (51b), it becomes a bowl-like shape, and since the grain becomes small, between each grain (between each droplet) ) Increases the electrical resistance due to the presence of air. Thereby, the water processed by the processing tank (11) and the water of the outflow part (3b) of water piping (3) are electrically insulated.

  As described above, according to the water treatment device (1a) of the present embodiment, the water treatment unit (10) is electrically insulated from the water treatment unit (10) and the water pipe (3). The distance extending means (43a, 43b) of the first insulating section (40) provided on the inflow side is more than the nozzle (42) than the vertical distance (La) from the tip of the nozzle (42) to the water surface of the water treatment section (10). 42) Since the water travel distance (Lba + Lbb) from the tip of the water treatment section (10) to the water surface is increased, the water in the water pipe (3) moves vertically downward from the nozzle (10). The electrical insulation in the first insulating portion (40) on the inflow side is improved as compared with the case where it is supplied. This improves the electrical insulation between the water treatment section (10) and the water in the water pipe (3) on the inflow side, so that the water treatment section (10) particularly on the inflow side of the water treatment section (10). Can prevent electricity from flowing through. Therefore, it is possible to reliably cause discharge in the water of the water treatment unit (10), and it is possible to efficiently use the input electric power.

  Further, according to the water treatment device (1a) of the present embodiment, the distance extension means (43a) collides the water supplied from the nozzle (42) and drops it onto the water treatment unit (10) by the reflector (43a). Therefore, due to the reflection of water at the reflector (43a), the water movement distance (Lba + Lbb) from the tip of the nozzle (42) to the water surface of the water treatment unit (10) is changed from the tip of the nozzle (42) to the water treatment unit ( Not only the vertical distance (La) to the water surface of 10) is longer, but also the water supplied from the nozzle (42) becomes granular due to the collision of water at the reflector (43a), and the water between the grains As a result, air intervenes in the water, and the electrical insulation between the water treatment section (10) and the water in the water pipe (3) on the inflow side can be improved.

  Further, according to the water treatment device (1a) of the present embodiment, since the water collision surface of the reflector (43a) has water repellency, it becomes difficult to form a water film on the surface of the reflector (43a). The water supplied from the nozzle (42) can be effectively granulated by the reflector (43a).

  Further, according to the water treatment device (1a) of the present embodiment, the nozzle (42) is configured so that the direction of the water supplied to the water treatment unit (10) is obliquely upward with respect to the horizontal plane. Since the water supplied from the nozzle (42) is reflected by the reflector (43a), the water movement distance (Lba + Lbb) from the tip of the nozzle (42) to the water surface of the water treatment unit (10) Not only becomes longer than the vertical distance (La) from the tip of the nozzle (42) to the water surface of the water treatment section (10), but also is supplied from the nozzle (42) by the collision of water at the reflector (43a). In addition, air intervenes between the water particles, and the electrical insulation between the water treatment section (10) and the water in the inflow side water pipe (3) can be improved.

  Moreover, according to the water treatment apparatus (1a) of this embodiment, since the insulation part (40, 50) is provided in the inflow side and outflow side of the water treatment part (10), the water treatment part (10) Therefore, it is possible to reliably suppress electricity from flowing into the water on the upstream side and the downstream side of the water treatment unit (10). Thereby, since discharge can be caused more reliably in the water of the water treatment unit (10), the input electric power can be used more efficiently.

  Moreover, according to the water treatment apparatus (1a) of this embodiment, since a bactericidal factor is produced | generated in water by discharge of a water treatment part (10), water can be reliably purified with this bactericidal factor.

  Moreover, according to the water treatment device (1a) of the present embodiment, when spraying water flowing from the water pipe (3) to the water treatment unit (10), the water treatment unit (10) and its water treatment unit ( Since the impedance between the water supplied to 10) can be increased, the water treatment unit (10) can be reliably insulated from the water supplied to the water treatment unit (10). .

  Further, according to the water treatment device (1a) of the present embodiment, the water flowing from the water treatment unit (10) to the water pipe (3) is dropped in a bowl shape and is formed into a so-called waterfall shape. 10) and the water discharged from the water treatment unit (10) can be increased in impedance, and the water discharged from the water treatment unit (10) and the water treatment unit (10) It can be reliably insulated.

  Moreover, according to the water treatment device (1a) of the present embodiment, since a plurality of lanes (21a, 21b, 22a, 22b) are provided, depending on the number of lanes (21a, 21b, 22a, 22b) The amount of water treated by the water treatment device (1a) can be adjusted.

  Further, according to the water treatment device (1a) of the present embodiment, since the high voltage generation unit (33) is an alternating type, the polarity of the applied voltage is predetermined in the first electrode (31) and the second electrode (32). Alternates every hour. Therefore, in the through hole (35), even if the current is increased, the spark discharge can be maintained without generating glow discharge. In other words, in the case of direct current, the discharge mode shifts from spark discharge to glow discharge as the current increases. In the water treatment device (1a) of the present embodiment, the first discharge mode shifts to glow discharge. Since the polarity of the applied voltage of the electrode (31) and the second electrode (32) is switched, it is possible to continue to generate spark discharge in the through hole (35) without generating glow discharge. Thereby, the thermal destruction of the through hole (35) due to glow discharge can be suppressed, and the increase in the diameter of the through hole (35) can be suppressed, so that stable discharge can be performed.

  Further, according to the water treatment device (1a) of the present embodiment, since the ratio of the positive electrode side and the negative electrode side in the voltage waveform generated by the high voltage generator (33) is equal, the first electrode (31) and In the second electrode (32), the oxidation reaction and the reduction reaction can be performed to the same extent. Therefore, elution by the oxidation reaction of the first electrode (31) and the second electrode (32) can be suppressed, and the first electrode (by the alternating voltage waveform generated by the high voltage generator (33) 31) and the second electrode (32) can be prevented from depositing metal or the like, so that stable discharge can be performed.

  Further, according to the water treatment device (1a) of the present embodiment, the voltage waveform generated by the high voltage generator (33) is a square wave, and therefore depends on the conductivity of water compared to a sine wave, for example. It is possible to cause a discharge without causing a stable discharge.

<< Embodiment 2 of the Invention >>
FIG. 8 shows Embodiment 2 of the water treatment device according to the present invention. In the following embodiments, the same portions as those in FIGS. 1 to 7 are denoted by the same reference numerals, and detailed description thereof is omitted.

  In the first embodiment, the water treatment apparatus in which the first insulating portion (40) is provided with the distance extending means (43a, 43b) is exemplified. However, in the present embodiment, the first insulating portion (40) is provided with the distance extending means. The water treatment apparatus provided with (43b) is illustrated.

  Similar to the water treatment device (1a) of the first embodiment, the water treatment device of the present embodiment includes a water storage tank (2), a water pipe (3), an open / close valve (4a, 4b), and a pump (5a, 5b). ) And a water circulation circuit (1) having a water treatment section (10).

  The water treatment part of this embodiment is similar to the water treatment part (10) of the first embodiment, and includes a first insulating part (40) provided on the inflow part (3a) side of the water pipe (3), Provided between the second insulating part (50) provided on the outflow part (3b) side of the pipe (3), the first insulating part (40) and the second insulating part (50), and the water pipe (3) The processing tank (11) which accommodates and processes the water supplied from this, and the 1st discharge unit (30a) and the 2nd discharge unit (30b) which were provided in the processing tank (11) are provided.

  The first insulating portion (40) of the present embodiment includes a nozzle header (41) connected to the inflow portion (3a) of the water pipe (3) and the lanes (21a, 21b, 22a, 22b) and a nozzle (42) connected to the nozzle header (41) and supplying water from the water pipe (3) to the processing section (10).

  The nozzle (42) sprays water from the water pipe (3), and as shown in FIG. 8, the distance extending means (43b) causes the center line A of the spray to face in a direction other than the vertically downward direction, for example, the nozzle The tip is directed diagonally downward to the right in the figure, and the water from the water pipe (3) is made to collide with the wall surface in the treatment tank, for example, the flow path adjusting plate 18 and fall to the water treatment unit (10). Has been.

  In the 1st insulation part (40) of the said structure, the water sprayed from the nozzle (42) collides with the surface of a flow-path adjustment board (18), and each particle | grain (droplet) becomes smaller, and each particle | grain is reduced. The electrical resistance increases due to air intervening between the droplets (between each droplet). Thereby, the water which flows in from the inflow part (3a) of a water piping (3) and the water which flows through a processing tank (11) are electrically insulated.

  As described above, according to the water treatment device of the present embodiment, the water treatment unit (10) and the water pipe (3) are electrically connected to the inflow side of the water treatment unit (10) to electrically insulate the water. The distance extending means (43b) of the provided first insulating portion (40) is located closer to the nozzle (42) than the vertical distance (La) from the tip of the nozzle (42) to the water surface of the water treatment unit (10). Since the water movement distance (Lb) to the water surface of the water treatment unit (10) is increased, the water in the water pipe (3) is supplied vertically downward from the nozzle (10). In addition, the electrical insulation at the inflow side insulating portion (40) is improved. This improves the electrical insulation between the water treatment unit (10) and the water in the water pipe (3) on the inflow side, as in the first embodiment. In particular, the inflow side of the water treatment unit (10) is improved. , It is possible to prevent electricity from flowing from the water treatment section (10).

  In each of the above embodiments, the water treatment unit (10) causes discharge in water. However, in the present invention, the water treatment unit (10) may cause electrolysis in water.

  Moreover, each said embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  Further, in each of the above-described embodiments, several essentially preferable configurations are exemplified, but the present invention may be combined as appropriate.

  As described above, the present invention is useful for a water treatment apparatus that electrically purifies treated water.

1a Water treatment equipment 3 Water piping (water passage)
DESCRIPTION OF SYMBOLS 10 Water treatment part 11 Treatment tank 40 1st insulation part 42 Nozzle 43a Reflector (distance extension means)
43b Distance extension means 50 2nd insulation part

Claims (5)

A water treatment section (10) provided in the middle of the water passage (3) through which water flows, and electrically treating the water;
Insulating portions (40, 50) provided on the inflow side and the outflow side of the water treatment portion (10), respectively, for electrically insulating the water treatment portion (10) and the water in the water passage (3). A water treatment device comprising:
The inflow-side insulating part (40) is provided above the water treatment part (10), and supplies a nozzle (42) for supplying water from the water passage (3) to the water treatment part (10), and the nozzle A distance extending means for increasing the water moving distance from the tip of the nozzle (42) to the water surface of the water treatment unit (10) than the vertical distance from the tip of (42) to the water surface of the water treatment unit (10) (43a, 43b)
The water treatment apparatus, wherein the distance extending means (43a) is a reflector (43a) that collides water supplied from the nozzle (42) and drops the water to the water treatment unit (10) . In claim 1 ,
The water treatment apparatus according to claim 1, wherein a water collision surface of the reflector (43a) has water repellency. In claim 1 or 2 ,
The water treatment apparatus, wherein the nozzle (42) is configured such that a direction of the supplied water is obliquely upward with respect to a horizontal plane. A water treatment section (10) provided in the middle of the water passage (3) through which water flows, and electrically treating the water;
Insulating portions (40, 50) provided on the inflow side and the outflow side of the water treatment portion (10), respectively, for electrically insulating the water treatment portion (10) and the water in the water passage (3). A water treatment device comprising:
The inflow-side insulating part (40) is provided above the water treatment part (10), and supplies a nozzle (42) for supplying water from the water passage (3) to the water treatment part (10), and the nozzle A distance extending means for increasing the water moving distance from the tip of the nozzle (42) to the water surface of the water treatment unit (10) than the vertical distance from the tip of (42) to the water surface of the water treatment unit (10) (43a, 43b)
The nozzle (42) is configured to spray water from the water passage (3),
The water treatment apparatus, wherein the distance extending means (43b) is configured such that the center line of the spray by the nozzle (42) faces in a direction other than the vertically downward direction. In claim 4 ,
The water treatment section (10) has a treatment tank (11) for containing water supplied from the water passage (3),
The distance extending means (43b) is configured to cause the water from the nozzle (42) to collide with the wall surface in the treatment tank (11) and drop the water treatment unit (10). A water treatment device characterized.

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