JP2012040531A - Water treatment apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a water treatment apparatus which can continuously operate the electrolysis cleaning effective in water treatment, and in which the advantages of cleaning which an electrolytic cell and a bubble generating tank each have are effectively combined.SOLUTION: The water treatment apparatus includes: an electrolytic cell; a bubble generating tank which is arranged to the downstream side of the electrolytic cell; a last tank which is arranged to the downstream side of the bubble generating tank, wherein the last tank includes a recovery apparatus which collects a product which floats at the tank. Further, the water treatment apparatus includes a pretreatment apparatus to perform the pretreatment of a treated water arranged to the upstream side of the electrolytic cell. Further, the electrolytic cell holds an upwelling flow generator. In addition, water treatment using the electrolytic cell is performed, thereby the sterilization effect for bacteria or the like is acquired, the scale of an organic matter base is deposited near the positive electrode, the scale of a metal can be deposited near the negative electrode, and thereby the water treatment apparatus can respond to various treated water.

Description

  The present invention relates to the field of water treatment equipment such as sewage.

  There is water that needs various types of water treatment around us, and typical one is sewage. It is important to consider the environment, such as making it possible to reuse water through water treatment, preventing pollution of the environment, collecting and reusing generated substances contained in water, and detoxifying the generated substances. It is a difficult issue. Examples of water treatment targets include cleaning water such as de-view and tofu clean for electrolyzed water, cationic paint circulating water, painting waste liquid, compressor drain water, cooling tower circulating water, water-soluble Cutting fluid, cleaning fluid, other industrial wastewater, decolorization of wastewater, circulating water for racetracks, cleaning fluid, water resources, well water purification, seawater desalination, river water purification, basin / reservoir water purification, food In terms of relations, udon and soba boiled soup, rice tofu soup, other factory effluents, decolorization of wastewater, and agriculture, fisheries, livestock, and breeding relations, livestock facilities sewage, drainage decolorization, brocade culture, and marine processing In terms of drainage and ship related matters, there are numerous issues such as wastewater purification and ballast water purification. Under such circumstances, various water treatment apparatuses have been developed.

  For example, Patent Document 1 (Japanese Patent Application Laid-Open No. 2005-13966) circulates between a cooling tower for cooling equipment for offices and factories, an air conditioner condenser used for cooling, and a cooling tower. A technique related to an electrolytic purification apparatus for circulating cooling water that electrically removes scale components in cooling water has been disclosed. This deposits metal ions contained in the circulating cooling water as a scale on or near the surface of the negative electrode plate, and deposits and deposits the deposited scale below the electrolytic septic tank. After the preset operating time has elapsed, the scale accumulated in the bottom is opened by the discharge timer, and the circulating cooling water in the electrolytic septic tank is discharged through the discharge device together with the scale accumulated in the bottom. It has become so. The scale in the discharged circulating cooling water is filtered and removed by the filtering unit, and the circulating cooling water enters the receiving tank. When the preset holding time elapses, the discharge valve is closed, and the circulating cooling water again accumulates in the electrolytic septic tank. The scale left in the filtration unit is sequentially carried out and removed when it accumulates to some extent.

  However, in such a system, there is a drawback that a series of flow of the electrolytic purification action must be interrupted for discharging the scale accumulated at the bottom of the electrolytic purification tank. Even if the scale accumulated on the bottom of the electrolytic septic tank is automatically discharged, a large-scale control device is required, and the operation reliability of the control device is always required to be careful.

  Patent Document 2 (Japanese Unexamined Patent Application Publication No. 2006-136767) discloses a sewage treatment apparatus for purifying sewage such as domestic wastewater. This includes a treatment tank capable of storing sewage, an electrolysis device for electrolyzing water in the treatment tank, and a fine bubble generator for generating fine bubbles in the water in the treatment tank, It is characterized by providing.

  However, in such a method, since the electrolysis apparatus and the fine bubble generator are coexisting in the treatment tank, a measure for the electrolysis effect to fluctuate due to the influence of the fine bubbles attached to the electrodes of the electrolysis apparatus in particular. And a problem that it is required to pay great attention to the particle size of the fine bubbles.

  Patent Document 3 (Japanese Patent Laid-Open No. 2008-200366) discloses that the water to be treated introduced into the electrolytic cell is subjected to electrolytic treatment in the presence of chloride ions and contains hypochlorous acid which is a strong oxidizing substance. A water treatment method for producing chlorous acid-containing water is disclosed. This is characterized in that, in the previous stage of the electrolytic cell or in the electrolytic cell, the flow rate in the electrolytic cell is ensured and the amount of air that dilutes the hydrogen gas generated by the electrolysis is supplied to the water to be treated. Water treatment method.

  However, in such a system, as described in Patent Document 2, it is necessary to take measures for the electrolysis effect to fluctuate due to the influence of the fine bubbles attached to the electrode, particularly the electrode of the electrolysis apparatus. In addition, there was a problem of requiring great care.

  The present invention is premised on being applied to purification of various types of treated water, and a first object of the present invention is water that can continuously operate electrolytic purification effective for water treatment. It is to provide a processing apparatus. The second object of the present invention is to provide a water treatment device that effectively combines the advantages of water purification that each of the electrolytic cell and the bubble generation cell has.

Therefore, means for solving the problems adopted by the present invention are:
It has an electrolysis tank, a bubble generation tank is arranged downstream of the electrolysis tank, a final tank is arranged downstream of the bubble generation tank, and the final tank has a recovery device that collects product substances floating in the tank. It is the water treatment apparatus characterized by becoming.
Further, the water treatment apparatus is characterized in that a pretreatment apparatus for pretreatment of treated water is disposed upstream of the electrolytic cell.
Further, the water treatment apparatus is characterized in that an upflow generator is accommodated in the electrolytic cell.

  According to the present invention, by performing water treatment using an electrolytic cell, a bactericidal effect such as bacteria can be obtained, and an organic scale is deposited in the vicinity of the positive electrode, and a metal scale is deposited in the vicinity of the negative electrode. It can be deposited. In addition to being able to handle various types of treated water, a bubble generation tank is placed downstream of the electrolytic cell, so that the scale flowing in from the electrolytic cell is sent to the downstream while floating by bubbles, and the collapse of fine bubbles Due to the effect, chlorine gas can be made harmless and ozone-like sterilization effect can be obtained, and chlorine gas concentration can be reduced and water purification comparable to ozone sterilization can be expected. Further, in the final tank, various products sent while the product recovery device is floating are continuously recovered, so that water treatment can be performed without stopping the operation of the water treatment device. The product can be reused and discarded.

It is a side view of the water treatment apparatus concerning the Example of this invention. It is a side view of the water treatment apparatus concerning the other Example of this invention. It is a layout view of a water treatment device according to another embodiment of the present invention.

  As a form for implementing this invention, it has an electrolytic cell, arrange | positions a bubble generation tank in the downstream of an electrolytic cell, arrange | positions the final tank in the downstream of a bubble generation tank, and a final tank floats in a tank A water treatment device having a recovery device for collecting product substances can be provided.

  As a form for implementing this invention, it can be set as the water treatment apparatus which has arrange | positioned the pre-processing apparatus which performs the pre-processing of a treated water further upstream of an electrolytic vessel.

  As a form for implementing this invention, it can be set as the water treatment apparatus by which the upward flow generator is accommodated in the electrolytic cell.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings with reference numerals attached to the members. Conventionally, the cooling water generally used for cooling the refrigerant flowing in the heat exchanger 60 is supplied from the cooling tower 61 to the heat exchanger 60 by a pump 67, heated by performing heat exchange, and returned to the cooling tower 61. A closed circuit system is formed which is cooled by the cooling fan 68 and circulates to the bottom of the cooling tower 61. The cooling water reduced by evaporation in the cooling tower 61 is appropriately supplemented by the water supply device 66, but tap water and groundwater used as circulating cooling water contain components such as calcium ions, magnesium ions and dissolved silica. Therefore, the concentration of metal ions increases and aggregates to form a scale that adheres to the heat exchange surface of the heat exchanger 60 and decreases the heat exchange efficiency, or adheres to the inner surface of the pipe and reduces the flow resistance of the cooling water. It had problems such as increase and bacteria breeding. In addition, there was a problem of detoxifying the chlorine component contained in tap water.

  FIG. 1 shows an example in which the water treatment apparatus of the present invention is applied to the purification of cooling water in the cooling tower 61 of the external cooling system 55. A first bubble generation tank 2 is disposed downstream of the electrolytic tank 1, a second bubble generation tank 3 is disposed downstream of the first bubble generation tank 2, and a final tank 4 is disposed downstream of the second bubble generation tank 3. It is arranged. The cooling water of the cooling tower 61 can be supplied to the electrolytic cell 1 through the pipe 62 by the pump 63 when the stop valves 64 and 65 are opened. The treated water in the final tank 4 is returned to the cooling tower 61 when the stop valves 51 and 52 are opened. A positive electrode 11 and a negative electrode 12 are arranged opposite to each other in the electrolytic cell 1, and an electrolytic action is generated by controlling the DC power supply 14 at 24 V or less by the control panel 15. The positive / negative switching of the electrodes may be performed at intervals of about 15 minutes to several seconds depending on the liquid. Further, the separator 13 may be disposed between the electrodes 11 and 12. The electrolytic promotion liquid in the electrolytic promotion liquid tank 18 is supplied to the electrolytic cell 1 by opening and closing the electromagnetic valve 19. The electrolytic cell 1 is provided with a rotating blade 17 that is driven to rotate by an electric motor 16. Bubbles or fine bubbles generated in the bubble generation unit 23 can be sent to the first bubble generation tank 2 by opening the stop valve 22 and to the second bubble generation tank 3 by opening the stop valve 31. The final tank 4 and the electrolytic cell 1 are connected via a pipe 46, and the treatment liquid can be returned to the electrolytic cell 1 by opening the stop valves 44 and 45 and driving the pump 43. The product recovery device 41 is attached to the final tank 4 in order to recover the product floating in the final tank 4 to the product recovery container 42. The stop valve 21 is a stop valve for draining the first bubble generating tank 2, and the stop valve 47 is a stop valve for draining the final tank 4.

  Explaining the operation, the cooling water sent from the cooling tower 61 to the electrolytic cell 1 contains heavy metals such as bacteria and SS, silica, calcium content, and magnesium content. Bacteria and the like are mostly killed by electrolytic treatment in the electrolytic cell 1. The metal ionized in the electrolytic cell 1 settles as a scale near the negative electrode 12 or adheres to the negative electrode 12. It is also possible to drive the electric motor 16 and rotate the rotary blade 17 to generate an upward flow in the electrolytic cell 1 to forcibly float the sinking scale. The set of scales that have floated is sequentially sent to the first bubble generating tank 2. Since the fine bubbles are sent from the bubble generating unit 23 to the first bubble generating tank 2 without interruption, a set of scales is sent to the second bubble generating tank 3 while rising over the first bubble generating tank 2 without sinking. . Since fine bubbles are generated in the second bubble generation tank 3 as in the first bubble generation tank 2, the set of scales is further sent to the final tank 4 and floats in the tank. In the final tank 4, a product recovery device 41 such as a scraper is operated, and a product composed of scales and bubbles floating in the final tank 4 is collected and recovered without interruption in the product recovery container 42. Since the fine bubbles are supplied to the first bubble generation tank 2 and the second bubble generation tank 3 without interruption, the treated water in the tank is purified and sent downstream. The treated water in the final tank 4 can be returned to the electrolytic cell 1 by the pump 43 by opening the stop valves 44 and 45. Moreover, it is possible to return to the cooling tower 61 by opening the stop valves 51 and 52. As described above, the system flow of the cooling water treatment of the cooling tower 61 is normally constituted by a closed circuit system.

  FIG. 2 shows an example in which the water treatment apparatus of the present invention is applied to the purification of the cooling water in the cooling tower 61 of the external cooling system 55. Basically, the first bubble generation tank 2 and the second bubble for the electrolytic cell 1 are used. The arrangement relationship between the generation tank 3 and the final tank 4 is different. It is designed to meet the needs of users' location restrictions. In the embodiment of FIG. 1, the arrangement of the first bubble generation tank 2, the second bubble generation tank 3 and the final tank 4 with respect to the electrolytic cell 1 is a horizontal type, whereas the example of FIG. 2 is a vertical arrangement. . A first bubble generation tank 2 is disposed downstream of the electrolytic tank 1, a second bubble generation tank 3 is disposed downstream of the first bubble generation tank 2, and a final tank 4 is disposed downstream of the second bubble generation tank 3. It is arranged. The cooling water of the cooling tower 61 can be supplied to the electrolytic cell 1 through the pipe 62 by the pump 63 when the stop valves 64 and 65 are opened. The treated water in the final tank 4 is returned to the cooling tower 61 when the stop valves 51 and 52 are opened. A positive electrode 11 and a negative electrode 12 are arranged opposite to each other in the electrolytic cell, and an electrolytic action is shown by controlling the DC power supply 14 at 24 V or less by the control panel 15. The positive / negative switching of the electrodes may be performed at intervals of about 15 minutes to several seconds depending on the liquid. The electrolytic promotion liquid in the electrolytic promotion liquid tank 18 is supplied to the electrolytic cell 1 by opening and closing the electromagnetic valve 19. Bubbles or fine bubbles generated in the bubble generation unit 23 can be sent to the first bubble generation tank 2 by opening the stop valve 22 and to the second bubble generation tank 3 by opening the stop valve 31. The final tank 4 and the electrolytic cell 1 are connected via a pipe 46, and the treatment liquid can be returned to the electrolytic cell 1 by opening the stop valves 44 and 45 and driving the pump 43. The product recovery device 41 is attached to the final tank 4 in order to recover the product floating in the final tank 4 to the product recovery container 42. The stop valve 21 is a stop valve for draining the first bubble generating tank 2, and the stop valve 47 is a stop valve for draining the final tank 4. Since there is substantially no difference in operation, description thereof is omitted.

  An embodiment of the present invention will be described with reference to FIG. The water treatment apparatus of this embodiment is based on three tanks of an electrolytic cell 1, a first bubble generation tank 2, and a final tank 4, and does not have a second bubble generation tank 3. Further, the final tank 4 and the electrolytic cell 1 are connected by a pipe 46, and the same as that of the first and second embodiments in that the treated water in the final tank 4 is returned to the electrolytic cell 1 by driving the pump 43. It is. However, the final tank 4 is connected to the extraction tank 6 by a pipe 73, and the treated water after purification can be reused or discharged to a river or the like. That is, an open circuit system is formed as a whole. The most characteristic feature is that a pretreatment tank 5 is provided upstream of the electrolytic cell 1. There are many types of water to be treated, and not just those that can be put into the electrolytic cell 1 as they are. In some cases, it is better to put a solid component or a component containing a lot of oil component into the electrolytic cell 1 after being precipitated or separated by pretreatment. In such a case, the pretreatment tank 5 is further installed upstream of the electrolysis tank 1, the pretreatment tank 5 and the electrolysis tank 1 are connected by the pipe 72, and the necessary treatment water in the pretreatment tank 5 is appropriately pumped by the pump 71. Water may be sent to the electrolytic cell 1.

  Although several embodiments have been described above, the present invention can be implemented in various other forms without departing from the spirit or main features thereof. Moreover, the above-mentioned Example is only an illustration in all the points, and must not be interpreted limitedly.

  The water treatment apparatus according to the present invention can be applied to the purification of various types of treated water, and can be continuously operated and the product can be automatically recovered. It can be greatly expected to be used in a wide range of fields.

DESCRIPTION OF SYMBOLS 1 Electrolysis tank 2 1st bubble generation tank 3 2nd bubble generation tank 4 Final tank 5 Pretreatment tank 6 Extraction tank 11 Positive electrode 12 Negative electrode 13 Isolation screen 14 DC power supply 15 Control panel 16 Electric motor 17 Rotary blade 18 Electrolysis promotion liquid tank 19 Solenoid valve 21 Stop valve 22 Stop valve 23 Bubble generating unit 31 Stop valve 41 Product recovery device 42 Product recovery container 43 Pump 44 Stop valve 45 Stop valve 46 Piping 47 Stop valve 50 Piping 51 Stop valve 52 Stop valve 55 External cooling System 60 Heat exchanger 61 Cooling tower 62 Piping 63 Pump 64 Stop valve 65 Stop valve 66 Water supply device 67 Pump 68 Cooling fan 71 Pump 72 Piping 73 Piping

JP-A-2005-13966 JP 2006-136767 A JP 2008-200366 A

Claims (3)

  It has an electrolysis tank, a bubble generation tank is arranged downstream of the electrolysis tank, a final tank is arranged downstream of the bubble generation tank, and the final tank has a recovery device that collects product substances floating in the tank. The water treatment apparatus characterized by becoming.   The water treatment device according to claim 1, wherein a pretreatment device for pretreatment of treated water is disposed upstream of the electrolytic cell.   The water treatment device according to claim 1 or 2, wherein an upflow generator is accommodated in the electrolytic cell.

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