JP2012075966A - Circulation system for pool - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a circulation system for a pool capable of removing various bacteria in the water of the pool having a safe and long-time bacteria removing effect.SOLUTION: The circulating system for the pool includes the pool (100) and a circulation passage for filtering the water of the pool (100) to circulate the same and is equipped with a water tank (61) for storing the water circulated through the circulation passage, electrode pairs (64 and 65) for producing streamer discharge in the circulated water stored in the water tank (61) and a power supply part (70) for applying DC voltage across the electrode pairs (64 and 65). Hydrogen peroxide is produced in the circulated water by the streamer discharge to perform the removal of bacteria.

Description

  The present invention relates to a pool circulation system that can sterilize germs in pool water.

  In the hygiene management of water used in pools, disinfection of miscellaneous bacteria including pathogenic bacteria is mainly performed by dripping sodium hypochlorite (NaClO) into water. In the hygiene management of the pool, sodium hypochlorite is introduced so that the residual chlorine concentration falls within the range of 0.4 mg / liter to 0.8 mg / liter.

  For example, Patent Document 1 describes a technique for decomposing an organic substance or the like by injecting sodium hypochlorite with a time lag after peeling an oil component dissolved using strong alkaline electrolyzed water.

JP 2004-141838 A

  However, due to the influence of sodium hypochlorite, the eyeball may become congested, the hair may be affected by chlorine and turn brown, and the skin may become rough. Further, if sodium hypochlorite is continuously used, the disinfection effect may be extremely lowered with a tendency to be inclined toward the alkaline side.

  This invention is made | formed in view of this problem, Comprising: It aims at providing the circulation system for pools which can sterilize the germs in the water of the pool which has a sterilization effect safely and for a long time.

  A first invention is a pool circulation system having a pool (100) and a circulation path for filtering and circulating the water of the pool (100), and a water storage tank for storing the circulation water circulating in the circulation path (61), an electrode pair (64,65) for generating streamer discharge in the circulating water stored in the water storage tank (61), and a DC voltage is applied to the electrode pair (64,65). And a power supply unit (70) for generating streamer discharge, and hydrogen peroxide is generated in the circulating water by the streamer discharge.

  In the first invention, the hydrogen peroxide generated in the circulating water by the streamer discharge is diffused in the water by convection in the water storage tank (61) by the heat accompanying the streamer discharge, and the components to be treated contained in the water are oxidized and decomposed. To purify the cooling water.

  According to a second aspect, in the first aspect, the water storage tank (61), the electrode pair (64, 65), and the power source unit (70) are combined to provide an underwater discharge unit (500). The underwater discharge unit (500) is provided in the circulation path.

  In the second invention, the water storage tank (61), the electrode pair (64, 65), and the power source unit (70) are combined to form the underwater discharge unit (500). Easy to install in a pool circulation system.

  According to a third aspect, in the first or second aspect, the circulation path is a constant circulation path (110) that constantly circulates water in the pool (100).

  In 3rd invention, since the germs in the circulating water of a circulation path (110) can always be removed, the washing | cleaning degree of the water of a pool (100) can be improved.

  According to a fourth invention, in the first or second invention, the circulation path is an overflow circulation path (120) for circulating water overflowed from the pool (100).

  Also in the fourth invention, since germs in the circulating water in the overflow circuit (120) can be removed, the cleanliness of the water in the pool (100) can be improved.

  According to a fifth invention, in any one of the first to fourth inventions, an ion supply unit (110, 124, 125) for supplying copper ions or iron ions to the water storage tank (61) is provided.

  In the fifth invention, copper ions and iron ions are supplied from the ion supply unit (110, 124, 125) to the water storage tank (61). Under conditions where copper ions and iron ions coexist in water containing hydrogen peroxide, the so-called Fenton reaction (Fenton reaction) causes the copper ions and iron ions to act catalytically to generate hydroxyl radicals. Therefore, in the water in the water storage tank (61), the amount of hydroxyl radicals generated increases, and the decomposition efficiency of harmful substances improves.

  According to a sixth invention, in any one of the first to fifth inventions, the discharge electrode (64) of the electrode pair (64, 65) is disposed at the bottom of the water storage tank (61). And

  In the sixth invention, the inside of the water storage tank (61) can be efficiently convected by the heat accompanying the streamer discharge with the active species and hydrogen peroxide.

  According to the present invention, since hydrogen peroxide is generated and sterilized in the circulating water by streamer discharge, the generated gas is oxygen gas, and the germs in the circulating water can be sterilized safely. Furthermore, due to the persistence of hydrogen peroxide, it has a long-term sterilization effect.

  Further, in the present invention, streamer discharge is performed using the DC power supply (70), so that the power supply unit can be simplified, reduced in cost, and reduced in size compared with, for example, a pulse power supply. Moreover, when a pulse power supply is used, the shock wave and noise which generate | occur | produce in water with discharge will become large. On the other hand, when a DC power source (70) is used, such shock waves and noise can be reduced.

  According to the 2nd invention, since the underwater discharge unit (500) is comprised, it is easy to install in the existing pool circulation system.

  According to the third aspect of the present invention, it is possible to improve the cleanliness of the water in the pool (100) by removing germs in the circulating water in the constant circulation path (110).

  According to the fourth aspect of the present invention, it is possible to remove germs in the circulating water in the overflow circuit (120) and improve the cleanliness of the water in the pool (100).

  According to the fifth invention, by supplying iron ions or copper ions in the presence of hydrogen peroxide, a large amount of hydroxyl radicals can be generated using the Fenton reaction. Therefore, harmful substances in water can be effectively removed using this hydroxyl radical.

  According to the sixth aspect of the invention, harmful substances and the like in the water can be accurately removed by efficiently convection of the active species and hydrogen peroxide in the water storage tank (61).

FIG. 1 is a configuration diagram of a pool circulation system according to the first embodiment. FIG. 2 is an overall configuration diagram of the underwater discharge unit according to the first embodiment, and shows a state before the water purification operation is started. FIG. 3 is a perspective view of the insulating casing according to the first embodiment. FIG. 4 is an overall configuration diagram of the underwater discharge unit according to the first embodiment, and shows a state in which air purification is started and bubbles are formed. FIG. 5 is an overall configuration diagram of the underwater discharge unit according to the second embodiment. FIG. 6 is a perspective view of an insulating casing according to the second embodiment. FIG. 7 is an overall configuration diagram of the underwater discharge unit according to the third embodiment, and shows a state before the water purification operation is started. FIG. 8 is an overall configuration diagram of the underwater discharge unit according to the third embodiment, and shows a state in which air purification is started and bubbles are formed. FIG. 9 is a plan view of a lid portion of an insulating casing according to a modification of the third embodiment. FIG. 10 is a configuration diagram of a pool circulation system according to the fourth embodiment.

  Hereinafter, embodiments of the present invention will be specifically described with reference to the accompanying drawings. However, the embodiments are for facilitating understanding of the principle of the present invention, and the scope of the present invention is as follows. The present invention is not limited to the embodiments, and other embodiments in which those skilled in the art appropriately replace the configurations of the following embodiments are also included in the scope of the present invention.

Embodiment 1
FIG. 1 is a configuration diagram of a pool circulation system (900) according to Embodiment 1 of the present invention. The pool circulation system (900) maintains the water quality in the pool (100) by circulating and filtering the water in the pool (100), and the pool (100) in which water for swimming is stored, A constant circulation path (110) that constantly circulates water in the pool (100) and an overflow circulation path (120) that circulates water that has overflowed from the pool (100) are provided.

  The constant circulation path (110) constantly circulates the water in the pool (100), and one end of the constant circulation path (110) is a first circulation inlet provided on the side surface of the pool (100) ( 111) and the other end is connected to a first water supply port (114) provided on the side surface of the pool (100). In the constant circulation path (110), a first circulation pump (112) for circulating the circulating water in the direction of the arrow and a first filtration device (113) for filtering the circulating water are arranged.

  The overflow circuit (120) circulates the overflow water. The first pipe (124) that discharges water from the overflowed pool (100) and the circulating water that has overflowed through the first pipe (124). And an overflow water tank (123) for storing water and a second pipe (125) for circulating the overflow water stored in the overflow water tank (123) to the pool (100) again.

  An overflow groove (121) is provided around the upper surface of the pool (100), and a second circulation inlet (122) is provided at the bottom of the predetermined position in the overflow groove (121). A second water supply port (126) is provided on the side surface of the pool (100).

  One end of the first pipe (124) is connected to the second circulation inlet (122), and the other end is connected to the overflow water tank (123). One end of the second pipe (125) is connected to the overflow water tank (123), and the other end is connected to the second water supply port (126).

  The second pipe (125) is provided with a second circulation pump (140) for circulating the circulating water in the direction of the arrow and a second filtration device (141) for filtering the circulating water.

  In the second pipe (125), a detector (142) such as a flow meter and a differential pressure gauge is provided on the downstream side of the second filtration device (141). When circulating and filtering the pool (100), the water pressure and water level in the pool (100) are detected by the detector (142), and the flow rate of the second circulation pump (140) is controlled by the inverter (143). . Thus, in the overflow circuit (120), the second circulation pump (140) is efficiently controlled so that the flow rate is necessary for the overflow of the pool (100).

  The constant circulation path (110), the first pipe (124), and the second pipe (125) are made of, for example, copper pipes. By comprising with a copper pipe, the ion supply part which supplies copper ion to the water storage tank (61) mentioned later is comprised by producing | generating copper ion from the inner wall.

  In the constant circulation path (110), an underwater discharge unit (500) is disposed between the first filtration device (113) and the first water supply port (114).

  Next, the detailed structure of the underwater discharge unit (500) will be described. The pool circulation system (900) includes an underwater discharge unit (500). The underwater discharge unit (500) generates purifying components such as hydrogen peroxide in water by streamer discharge in water, and purifies cooling water using the purifying components. As shown in FIG. 2, the underwater discharge unit (500) includes a water storage tank (61) and a discharge unit (72).

  The water storage tank (61) is formed in a sealed container shape, and the inflow side flow path (110a) on the inflow side and the outflow side flow path (110b) on the outflow side to the water storage tank (61) are connected.

  The discharge unit (72) houses therein the discharge electrode (64) and the counter electrode (65), a power supply unit (70) for applying a voltage to the electrode pair (64, 65), and the discharge electrode (64). And an insulating casing (71).

  The electrode pair (64, 65) is for generating a streamer discharge in water. The discharge electrode (64) which is one electrode of the electrode pair (64, 65) is arranged inside the insulating casing (71). The insulating casing (71) is disposed at the bottom of the water storage tank (61). Therefore, the discharge electrode (64) is disposed at the bottom of the water storage tank (61) through the bottom surface of the insulating casing (71). By disposing the discharge electrode (64) at the bottom of the water storage tank (61), hydrogen peroxide generated as described later is convected in the water storage tank (61) by heat generated by the streamer discharge to promote diffusion. It is. The discharge electrode (64) is formed in a flat plate shape up and down. The discharge electrode (64) is connected to the positive electrode side of the power supply unit (70). The discharge electrode (64) is made of a conductive metal material such as stainless steel or copper. The counter electrode (65) which is the other electrode of the electrode pair (64, 65) is disposed outside the insulating casing (71). The counter electrode (65) is provided above the discharge electrode (64). The counter electrode (65) has a flat plate shape in the vertical direction, and is configured in a mesh shape or a punching metal shape having a plurality of through holes (66) in the vertical direction. The counter electrode (65) is disposed substantially parallel to the discharge electrode (64). The counter electrode (65) is connected to the negative electrode side of the power supply unit (70). The counter electrode (65) is made of a conductive metal material such as stainless steel or brass.

  The power supply unit (70) is constituted by a DC power supply that applies a predetermined DC voltage to the electrode pair (64, 65). That is, the power supply unit (70) is not a pulse power supply that repeatedly applies a high voltage instantaneously to the electrode pair (64, 65), but is always a few kilovolts of direct current to the electrode pair (64, 65). Apply voltage. Of the power supply unit (70), the negative electrode side to which the counter electrode (65) is connected is connected to the ground. The power supply unit (70) is provided with a constant power control unit (not shown) that controls the discharge power of the electrode pair (64, 65) to be constant.

  The insulating casing (71) is made of an insulating material such as ceramics. The insulating casing (71) has a container-like case body (72) whose one surface (upper surface) is open, and a plate-like lid (73) that closes the open portion above the case body (72). is doing.

  The case body (72) has a square cylindrical side wall (72a) and a bottom (72b) that closes the bottom of the side wall (72a). The discharge electrode (64) is laid on the upper side of the bottom (72b). In the insulating casing (71), the vertical distance between the lid (73) and the bottom (72b) is longer than the thickness of the discharge electrode (64). That is, a predetermined interval is ensured between the discharge electrode (64) and the lid (73). Thereby, a space (S) is formed between the discharge electrode (64), the case main body (72), and the lid portion (73) inside the insulating casing (71).

  As shown in FIGS. 2 and 3, the lid (73) of the insulating casing (71) is formed with one opening (74) penetrating the lid (73) in the thickness direction. This opening (74) allows the formation of an electric field between the discharge electrode (64) and the counter electrode (65). The inner diameter of the opening (74) of the lid (73) is preferably 0.02 mm or more and 0.5 mm or less.

  As described above, the insulating casing (71) accommodates only one electrode (discharge electrode (64)) of the electrode pair (64, 65) inside, and between the electrode pair (64, 65). An insulating member having an opening (74) forming a current density concentration portion for increasing the current density of the current path is configured.

  In addition, in the opening (74) of the insulating casing (71), the current density in the current path is concentrated, so that water is vaporized by Joule heat and bubbles (B) are formed. That is, the opening (74) of the insulating casing (71) functions as a gas phase forming part that forms bubbles (B) forming a gas phase part in the opening (74).

  About the circulation system (900) for pools which concerns on this embodiment comprised as mentioned above, the usage aspect is demonstrated below.

  In the constant circulation path (110), the water in the pool (100) flows out from the first circulation inlet (111), passes through the first circulation pump (112) and the first filtration device (113), and again enters the first circulation path (110). Return from the water inlet (114) to the pool (100).

  In the overflow circuit (120), the water overflowed from the pool (100) flows from the second circulation inlet (122) through the first pipe (124) to the overflow water tank (123) and is stored there. The water flows from the water tank (123) through the second pipe (125) to the pool (100) from the second water supply port (126) provided on the side surface of the pool (100) again.

  In the pool circulation system (900) of this embodiment, the water flowing through the first circulation pump (112) is purified by operating the underwater discharge unit (500). The water purification operation by such an underwater discharge unit (500) will be described in detail.

  At the start of operation of the underwater discharge unit (500), as shown in FIG. 2, the space (S) in the insulating casing (71) is in a flooded state. When a predetermined DC voltage (for example, 1 kV) is applied from the power supply unit (70) to the electrode pair (64, 65), an electric field is formed between the electrode pair (64, 65). At this time, the periphery of the discharge electrode (64) is covered with the insulating casing (71). For this reason, the leakage current between the electrode pair (64, 65) is suppressed, and the current density of the current path in the opening (74) is concentrated.

  As the current density in the opening (74) increases, the Joule heat in the opening (74) increases. As a result, in the insulating casing (71), the vaporization of water is promoted in the vicinity of the opening (74) to form bubbles (B). As shown in FIG. 4, the bubbles (B) cover almost the entire area of the opening (74), and are formed between the water on the negative electrode side conducting to the counter electrode (65) and the discharge electrode (64) on the positive electrode side. Air bubbles (B) are interposed between them. Therefore, in this state, the bubble (B) functions as a resistance that prevents conduction through water between the discharge electrode (64) and the counter electrode (65). Thereby, the leakage current between the discharge electrode (64) and the counter electrode (65) is suppressed, and a desired potential difference is maintained between the electrode pair (64, 65). Then, streamer discharge is generated in the bubble (B) due to dielectric breakdown.

  As described above, when streamer discharge is performed with the bubbles (B), active species such as hydroxyl radicals, hydrogen peroxide, and the like are generated in the water in the water storage tank (61). Active species such as hydroxyl radicals and hydrogen peroxide are convected in the water storage tank (61) by heat accompanying the streamer discharge. This promotes diffusion of active species and hydrogen peroxide in water. Further, when streamer discharge is performed with the bubbles (B), an ion wind is easily generated with the bubbles (B) along with the streamer discharge. Therefore, in the water storage tank (61), the diffusion effect of active species and hydrogen peroxide can be further improved by using this ion wind.

  Further, as described above, the copper ions deposited from the constant circulation path (110), the first pipe (124), and the second pipe (125) are supplied to the water storage tank (61). In the presence of hydrogen peroxide and copper ions, the Fenton reaction (Fenton reaction) promotes the generation of hydroxyl radicals by the copper ions acting catalytically. Thereby, the purification efficiency of the water by the hydroxyl radical improves. In addition, since copper ions have the effect of suppressing the growth of bacteria, the bactericidal action in water also increases.

  As described above, active species such as hydroxyl radicals diffused in water are used to purify water by oxidizing and decomposing components to be treated (for example, ammonia) contained in water. In addition, hydrogen peroxide diffused in water is used for water sterilization. Thereby, in the circulation system (900) for pools of this embodiment, the purity of circulating water is maintained.

<< Embodiment 2 >>
In Embodiment 1 described above, one opening (74) is formed in the lid portion (73) of the insulating casing (71). However, for example, as shown in FIGS. 5 and 6, a plurality of openings (74) may be formed in the lid portion (73) of the insulating casing (71). In this modification, the lid portion (73) of the insulating casing (71) is formed in a substantially square plate shape, and a plurality of openings (74) are arranged in a grid pattern in the lid portion (73) at regular intervals. Has been. On the other hand, the discharge electrode (64) and the counter electrode (65) are formed in a square plate shape over all the openings (74).

  Also in this modification, each opening (74) functions as an electric field density concentration part and a gas phase formation part. As a result, when a DC voltage is applied from the power supply unit (70) to the electrode pair (64, 65), the current density of each opening (74) increases, and bubbles (B) are formed in each opening (74). The As a result, streamer discharge is caused in each bubble (B), and active species such as hydroxyl radicals and hydrogen peroxide are generated.

<< Embodiment 3 >>
The pool circulation system (900) according to Embodiment 3 is different from that of Embodiment 1 described above in the configuration of the discharge unit (72). In the following, differences from the first embodiment will be mainly described.

  As shown in FIG. 7, the discharge unit (72) of the third embodiment is configured as a so-called flange unit type that is inserted and fixed from the outside to the inside of the water storage tank (61). In the discharge unit (72) of the third embodiment, the discharge electrode (64), the counter electrode (65), and the insulating casing (71) are integrally assembled.

  The insulating casing (71) of Embodiment 3 has a substantially outer shape that is cylindrical. The insulating casing (71) has a case body (72) and a lid (73).

  The case main body (72) of Embodiment 3 is made of, for example, an insulating material made of glass or resin. The case body (72) includes a cylindrical base portion (76), a cylindrical wall portion (77) projecting from the base portion (76) toward the water storage tank (61), and the cylindrical wall portion (77). And an annular convex part (78) projecting further toward the water storage tank (61) side. The case body (72) is integrally formed with a distal end cylindrical portion (79) on the distal end side of the annular convex portion (78). A cylindrical insertion port (76a) is formed in the axial center portion of the base portion (76) so as to extend in the axial direction. A cylindrical space (S) that is coaxial with the insertion port (76a) and has a larger diameter than the insertion port (76a) is formed inside the cylindrical wall (77).

  The lid portion (73) of the third embodiment is formed in a substantially disc shape and is fitted inside the annular convex portion (78). The lid (73) is made of, for example, a ceramic material. As in the first embodiment, one circular opening (74) penetrating the lid (73) up and down is formed at the axis of the lid (73).

  The discharge electrode (64) is a vertically long rod-shaped electrode having a circular cross section perpendicular to the axis. The discharge electrode (64) is fitted in the insertion opening (76a) of the base (76). Thereby, the discharge electrode (64) is accommodated in the insulating casing (71). In the third embodiment, the end of the discharge electrode (64) opposite to the water storage tank (61) is exposed to the outside of the water storage tank (61). For this reason, the power supply part (70) arrange | positioned outside the water storage tank (61) and the discharge electrode (64) can be easily connected by electrical wiring.

  The end (64a) on the water storage tank (61) side of the discharge electrode (64) faces the space (S) inside the insulating casing (71). In the example shown in FIG. 7, the end (64a) of the discharge electrode (64) protrudes above the opening surface of the insertion port (76a) (on the water storage tank (61) side). The distal end surface of (64a) may be substantially flush with the opening surface of the insertion port (76a), or the end (64a) may be recessed below the opening surface of the insertion port (76a). In addition, the discharge electrode (64) has a predetermined gap between the discharge electrode (64) and the lid (73) having the opening (74), as in the first embodiment.

  The counter electrode (65) has a cylindrical electrode body (65a) and a flange (65b) projecting radially outward from the electrode body (65a). The electrode body (65a) is externally fitted to the case body (72) of the insulating casing (71). The flange part (65b) constitutes a fixed part that is fixed to the wall part of the water storage tank (61) and holds the discharge unit (72). In a state where the discharge unit (72) is fixed to the water storage tank (61), a part of the electrode body (65a) of the counter electrode (65) is submerged.

  The counter electrode (65) includes an inner cylindrical portion (65c) having a smaller diameter than the electrode main body (65a) and a connecting portion (65d) formed between the inner cylindrical portion (65c) and the electrode main body (65a). ). The inner cylinder part (65c) and the connecting part (65d) are immersed in the water in the water storage tank (61). The inner cylinder part (65c) forms the cylindrical space (67) in the inside. One end of the inner cylinder portion (65c) in the axial direction constitutes a holding portion that contacts the lid portion (73) and holds the lid portion (73). Further, the tip cylinder part (79) of the case body (72) is fitted between the electrode body (65a), the inner cylinder part (65c), and the connecting part (65d). On the other end side in the axial direction of the inner cylinder portion (65c), a mesh-shaped leakage preventing material (68) is provided so as to cover the cylindrical space (67). The leakage preventive material (68) is substantially grounded by contacting the counter electrode (65). Thereby, the leakage preventive material (68) prevents leakage from the inside to the outside of the cylindrical space (67) in the space (underwater) inside the water storage tank (61).

  The counter electrode (65) is in a state where a part of the electrode body (65a) is exposed to the outside of the water storage tank (61). For this reason, a power supply part (70) and a counter electrode (65) can be easily connected by electrical wiring.

  Also in the pool circulation system (900) of the third embodiment, the water flowing through the circulation path (110) is always purified by operating the underwater discharge unit (500).

  At the start of operation of the underwater discharge unit (500), as shown in FIG. 7, the space (S) in the insulating casing (71) is in a flooded state. When a predetermined DC voltage (for example, 1 kV) is applied from the power supply unit (70) to the electrode pair (64, 65), the current density inside the opening (74) increases.

  When a direct current voltage is continuously applied to the electrode pair (64, 65) from the state shown in FIG. 7, water in the opening (74) is vaporized to form bubbles (B) (see FIG. 8). reference). In this state, the bubble (B) covers almost the entire area of the opening (74), and the resistance of the bubble (B) is between the negative electrode side water in the cylindrical space (67) and the discharge electrode (64). Is granted. As a result, the potential difference between the discharge electrode (64) and the counter electrode (65) is maintained, and streamer discharge is generated in the bubbles (B). As a result, hydroxyl radicals and hydrogen peroxide are generated in water, and these components are used for purification of cooling water.

  In the third embodiment, one opening (74) is formed in the axial center of the disc-shaped lid (73), but a plurality of openings (74) are formed in the lid (73). May be. In the example shown in FIG. 9, five openings (74) are arranged at equal intervals on a virtual pitch circle centered on the axis of the lid (73). By forming a plurality of openings (74) in the lid (73) in this way, streamer discharge can be caused in the vicinity of each opening (74).

<< Embodiment 4 >>
In the above-described Embodiments 1 to 3, the underwater discharge unit (500) is always disposed in the circulation path (110). However, the scope of the present invention is not limited to such an embodiment. In the fourth embodiment, as shown in FIG. 10, an underwater discharge unit (500) is disposed in the overflow circuit (120).

  The underwater discharge unit (500) is disposed between the detector (142) and the second water supply port (126), and the water tank (61) has an inflow on the inflow side to the water tank (61). The side flow path (125a) and the outflow side outflow path (125b) are connected. Other configurations and operations are the same as those in the first to third embodiments.

  In the pool circulation system (900) of the present embodiment, the water discharge unit (500) is operated to purify the water flowing through the second circulation pump (140), such as hydroxyl radicals diffused in the water. The active species are used to purify water by oxidizing and decomposing components to be treated (for example, ammonia) contained in water. In addition, hydrogen peroxide diffused in water is used for water sterilization. Thereby, also in the circulation system (900) for pools of this embodiment, the purity of circulating water is maintained.

<< Other Embodiments >>
In Embodiments 1 to 3 described above, the underwater discharge unit (500) is always disposed in the circulation path (110), and in Embodiment 4, it is disposed in the overflow circulation path (120). However, the scope of the present invention is not limited to such an embodiment, and the underwater discharge unit (500) can be always provided in both the circulation circuit (110) and the overflow circuit (120). is there.

  The power supply unit (70) of each embodiment described above uses a constant power control unit that controls the discharge power of the streamer discharge to be constant. However, instead of the constant power control unit, a constant current control unit for controlling the discharge current at the time of streamer discharge to be constant may be provided. When this constant current control is performed, the discharge is stabilized regardless of the conductivity of the washing water, so that the occurrence of sparks can be avoided in advance.

  In each of the above-described embodiments, the discharge electrode (64) is connected to the positive electrode of the power supply unit (70), and the counter electrode (65) is connected to the negative electrode of the power supply unit (70). However, by connecting the discharge electrode (64) to the negative electrode of the power supply unit (70) and connecting the counter electrode (65) to the positive electrode of the power supply unit (70), so-called between the electrode pair (64,65). Negative discharge may be performed.

  Moreover, in each embodiment mentioned above, it is set as the ion supply part of a copper ion by making a continuous circulation path (110), a 1st piping (124), and a 2nd piping (125) into a copper pipe. However, as the ion supply unit, for example, an iron pipe that generates iron ions can be used. Since iron ions, like copper ions, promote the Fenton reaction in the presence of hydrogen peroxide, the amount of hydroxyl radicals generated can be increased. Moreover, these can also be made into an ion supply part by immersing a copper piece and an iron piece in a water storage tank (61), for example.

  As described above, the present invention is useful for a pool circulation system capable of obtaining cooling water from which germs are removed.

61 Water tank
64 Discharge electrode
65 Counter electrode
66 Through hole
70 Power supply
71 Insulation casing
72 Discharge unit
73 Lid
74 opening
100 pool
110 Continuous circuit
111 First circulation inlet
112 First circulation pump
113 First filtration device
114 First water inlet
120 Overflow circuit
121 Overflow groove
122 Second circulation inlet
123 overflow tank
124 First piping
125 Second piping
126 Second water inlet
140 Second circulation pump
141 Second filtration device
142 Detector
500 Underwater discharge unit
900 Pool circulation system

Claims (6)

In a circulation system for a pool, including a pool (100) and a circulation path for filtering and circulating water of the pool (100),
A water storage tank (61) for storing circulating water circulating in the circulation path, an electrode pair (64, 65) for generating streamer discharge in the circulating water stored in the water storage tank (61), A power supply unit (70) for generating a streamer discharge by applying a DC voltage to the electrode pair (64, 65), and generating hydrogen peroxide in the circulating water by the streamer discharge. And circulation system for pools. In claim 1,
The water storage tank (61), the electrode pair (64, 65), and the power supply unit (70) are combined to provide an underwater discharge unit (500), and the underwater discharge unit (500) is connected to the circulation path. A circulation system for a pool characterized by being provided in In claim 1 or 2,
The circulation system for pools, wherein the circulation path is a constant circulation path (110) that constantly circulates water in the pool (100). In claim 1 or 2,
The circulation system for a pool, wherein the circulation path is an overflow circulation path (120) for circulating water overflowing from the pool (100). In any one of Claims 1 thru | or 4,
A pool circulation system comprising an ion supply unit (110, 124, 125) for supplying copper ions or iron ions to the water storage tank (61). In any one of claims 1 to 5,
The pool circulation system, wherein the discharge electrode (64) of the electrode pair (64, 65) is disposed at the bottom of the water storage tank (61).

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