JP2008173525A - Water treatment apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a water treatment apparatus capable of treating water to be treated by sufficiently reacting the component and gas in the water to be treated by enhancing the gas mixture ratio of the water to be treated. <P>SOLUTION: The water treatment apparatus is equipped with spiral blades having spiral blade elements, and the water to be treated flowing into a reaction tube by a pump and the air introduced into the reaction tube by an air introducing part flow toward a discharge pipe along the stirring blades while stirred. By this constitution, more air is dissolved in the water to be treated and the gas mixture ratio in the water to be treated is enhanced. Accordingly, the component and air in the water to be treated can be sufficiently mixed. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a water treatment apparatus that reacts treated water with a gas such as oxygen, ozone, hydrogen, or air.

  2. Description of the Related Art Conventionally, methods and apparatuses for injecting gas into treated water and reacting treated water and gas have been developed. One of them is a water treatment apparatus that uses ozone as a gas for oxidizing treated water (see, for example, Patent Document 1). In addition, there is a method of injecting ozone into treated water with an ejector.

JP 09-234474 A

  The water treatment apparatus disclosed in Patent Document 1 includes a diffuser at the bottom of a treatment tank into which treated water flows, and ozone is injected into the treated water from the diffuser. However, even if the diffuser as in Patent Document 1 or the conventional ejector is used in the treatment tank, the water to be treated and the gas are not efficiently mixed, and the reaction between the component and the gas in the water to be treated is not possible. Does not proceed smoothly. That is, there is a problem that the water to be treated cannot be sufficiently treated.

  Thus, the present invention has been found as a result of developments aimed at improving the air-fuel ratio to the water to be treated in view of the above-described actual situation. That is, this invention provides the water treatment apparatus which can fully react the component and gas in to-be-processed water, and can treat to-be-processed water by the improvement of the air-fuel ratio of to-be-processed water.

  The water treatment apparatus of the present invention comprises a reaction tube for reacting a component in water to be treated with a gas dissolved in the water to be treated, an inflow tube for allowing the water to be treated to flow into the reaction tube, and the reaction from the inflow tube. A pump that introduces the water to be treated into a pipe, a gas introduction part that introduces the gas into the reaction pipe, and a component in the water to be treated by the gas that is provided in the reaction pipe and introduced from the gas introduction part And a discharge pipe that discharges the treated water after treating the water to be treated, a rod provided at the center of the reaction pipe, and a blade body that is formed in a spiral shape around the rod body It has a spiral blade.

  The water treatment apparatus of the present invention includes a spiral blade having a spiral blade body, so that the water to be treated that has flowed into the reaction tube by the pump and the gas introduced into the reaction tube by the gas introduction unit are being stirred. It flows along the spiral blade toward the discharge pipe. Thereby, more gas dissolves in to-be-processed water, and the air-fuel ratio in to-be-processed water improves. Therefore, it is possible to sufficiently react components and gas in the water to be treated.

  Hereinafter, the present invention will be described in detail with reference to the drawings. As shown in FIG. 1, the water treatment apparatus of the present invention mainly has a pump 1, a reaction tube 2, and a gas introduction part 3. The water treatment apparatus of the present invention pumps up the water to be treated by the pump 1 and flows it into the reaction tube 2 to react the gas introduced by the gas introduction unit 3 with the components in the water to be treated. The treated water can be treated with.

  In the present invention, the water to be treated is water containing a component that is reacted by gas, for example, water having a component that requires an oxidation reaction by oxygen, ozone, air, or a reduction reaction by hydrogen or the like. It shows that. Examples of this component include metals such as iron and organic substances. Further, in the present invention, treated water means water treated by the reaction of components in water to be treated and gas, that is, water discharged from the reaction tube 2.

  FIG. 2 is a diagram showing a part of the internal structure of the reaction tube of the water treatment apparatus of the present invention. As shown in FIG. 2, the reaction tube 2 is a cylindrical member having an arbitrary inner diameter with a hollow inside. Then, at a location where the later-described spiral blade of the reaction tube 2 is provided, that is, in the vicinity of the center of the reaction tube 2, a line connecting the centers of circles drawn by the respective cross sections in the circumferential direction (hereinafter, the axis of the reaction tube 2) is approximately. It is a tube that forms a straight line. At both ends of the reaction tube 2, an inflow tube 25 and a discharge tube 29 are provided.

  The inflow pipe 25 is provided in the vicinity of the end of the reaction tube 2 and is, for example, a cylindrical tubular member having a hollow inside. To flow into. The inflow pipe 25 may have any shape as long as the water to be treated can be introduced into the reaction tube 2 via the pump 1, and the inner diameter thereof is the same as the inner diameter of the reaction tube 2. Or it may be bent. Further, the inflow pipe 25 may be provided on the end face of the reaction pipe 2 or on the side face.

  The discharge pipe 29 is provided in the vicinity of the end of the reaction tube 2 and is a cylindrical annular member having a hollow inside, for example, and discharges treated water that has been treated in the reaction tube 2 by reaction with gas. The discharge pipe 29 may have any shape as long as the treated water can be discharged from the reaction tube 2, and the inner diameter thereof may be the same as the inner diameter of the reaction tube 2 or may be bent. Good. Further, the discharge pipe 29 may be provided on the end face of the reaction pipe 2 or on the side face.

  Inside the reaction tube 2, in the vicinity of the center of the reaction tube 2 in which the axis of the reaction tube 2 is substantially straight, as shown in FIG. 2, as shown in FIG. 2, a rod body 21 and a spiral blade body 22 centering on the rod body 21. A spiral blade consisting of The rod body 21 is substantially linear with a predetermined length, and both ends thereof are supported by the end portions of the reaction tube 2 so as to be approximately the center of the reaction tube 2. This rod 21 may be rotatably supported by the reaction tube 2 and can be rotated by a driving source such as a motor (not shown). By making the spiral blades rotatable, dust and the like accumulated in the reaction tube 2 can be easily discharged, and maintenance of the water treatment apparatus of the present invention is facilitated.

  As shown in FIG. 3, the blade body 22 of the spiral blade is a spiral blade centered on the rod body 21. The blade body 22 is provided so that a gap is formed between the reaction tube 2 and the blade body 22 so that the blade body 22 does not contact the inner side surface of the reaction tube 2. At this time, even if the gap between the reaction tube 2 and the blade body 22 is large, an improvement in the air-fuel ratio is observed due to the water to be treated flowing into the discharge pipe while spirally turning along the blade body 22. The smaller the is, the more the water to be treated that flows in the discharge pipe while spirally turning along the blade body 22, and the gas mixture ratio can be further improved.

  Thus, the reaction tube 2 is provided with a spiral blade inside. The reaction tube 2 may have any shape as long as the water to be treated can be introduced and the treated water can be discharged except in the vicinity of the center including the spiral blades on the inside, and the reaction tube 2 may be bent or thin. Good. Further, the shape of the reaction tube 2 in the vicinity of the center having a spiral blade on the inside is preferably such that the axis of the reaction tube 2 is a straight line.

  The inflow pipe 25 of the reaction tube 2 is provided with a pump 1. The pump 1 pumps up the water to be treated in the reaction tube 2 and causes the water to be treated to flow into the reaction tube 2 through the inflow tube 25. At this time, the pump 1 continuously feeds the water to be treated into the reaction tube 2 through the inflow tube 25.

  Further, a gas introduction part 3 is provided in the vicinity of the reaction tube 2 provided with the inflow pipe 25. This gas introduction part 3 can send the gas dissolved in the water to be treated into the reaction tube 2. The gas introduction unit 3 may be any type as long as gas can be fed in. For example, a gas pressurized by a compressor or the like so as to have a pressure higher than the water pressure is introduced into the gas introduction unit 3. By feeding into the reaction tube 2 through the tube, the gas can be fed into the reaction tube 2 without backflow of the water to be treated. Further, for example, when a cylinder having a pressurized gas is used, the reaction tube 2 and the cylinder may be connected via a valve for controlling the amount of gas introduced.

  The gas introduced into the reaction tube 2 by the gas introduction unit 3 is appropriately selected depending on whether the component in the water to be treated is oxidized or reduced. For example, when oxidizing a component in the water to be treated, a gas that easily reacts with the component is selected from oxygen, ozone, air, or the like, depending on the component in the water to be treated. Introduce gases such as ozone and air. Moreover, when reducing the component in to-be-processed water, hydrogen etc. are selected and the gas introduction part 3 introduce | transduces gas, such as hydrogen. Thereby, the component in water to be treated can be reacted to treat the water to be treated. The gas introduced into the reaction tube 2 from the gas introduction unit 3 is preferably introduced as fine bubbles as possible. In addition, the gas introduction unit 3 may introduce water to be treated or liquid mixed with gas into the reaction tube 2.

  The water treatment apparatus of the present invention having such a configuration operates as follows. Here, the operation of the water treatment apparatus for introducing air into the reaction tube 2 is illustrated, but the present invention is not limited to this.

  First, the pump 1 pumps up the water to be treated and flows it into the reaction tube 2 through the inflow tube 25. At this time, the gas introduction unit 3 pressurizes air and introduces it into the reaction tube 2.

  As the water to be treated flows continuously from the pump 1 into the reaction tube 2, the water to be treated that has flowed into the reaction tube 2 is centered on the rod body 21 along the blade body 22 of the spiral blade. It flows in the direction of the discharge pipe 29 while spirally turning. Similarly, the gas is continuously introduced from the gas introduction unit 3 into the reaction tube 2, so that the fine bubbles introduced into the reaction tube 2 are centered on the rod body 21 along the blade body 22 of the spiral blade. As described above, the gas flows in the direction of the discharge pipe 29 while spirally turning.

  In this way, the water to be treated flows while swirling along the spiral blades, so that the water to be treated flows into the discharge pipe while being stirred. Therefore, the gas introduced as fine bubbles easily dissolves in the water to be treated, and the air mixture ratio can be improved.

  The treated water contains a component that reacts with oxygen in the air and oxidizes, and an oxidation reaction occurs when oxygen in the air comes into contact with a component in the treated water. That is, the water to be treated can be treated by oxidizing the components in the water to be treated.

  As described above, the water treatment apparatus of the present invention has an improved air mixture rate, so that the components in the water to be treated and the oxygen in the air come into contact with each other. Therefore, it becomes possible to treat water to be treated more than before. Thus, the treated water treated in the reaction tube 2 is discharged from the discharge tube 29 of the reaction tube 2.

  As described above, the water treatment apparatus of the present invention includes a spiral blade having a spiral blade body, so that the water to be treated that has flowed into the reaction tube by the pump and the gas introduced into the reaction tube by the gas introduction unit Flows to the discharge pipe along the spiral blade while being stirred. Thereby, more gas dissolves in to-be-processed water, and the air-fuel ratio in to-be-processed water improves. Therefore, the component and gas in to-be-processed water can fully be made to react, and it can provide as a water treatment apparatus with high processing efficiency.

  Although the water treatment apparatus mentioned above can use air as gas, the water treatment apparatus of this invention is not limited to this, Gases, such as oxygen, ozone, and hydrogen, can be used. Even when these gases are used as the gas, as in the case of the air described above, the gas can be introduced into the reaction tube 2 by providing a gas cylinder or the like to be used.

  For example, as shown in FIG. 4, the blade body 22 of the water treatment device of the present invention described above may be provided with a plurality of resistor bodies 23 formed of hemispherical protrusions on the surface of the blade body 22. The resistance body 23 is resistant to the flow of the water to be treated when the water to be treated flowing in from the inflow pipe 25 turns spirally along the blade body 22 of the spiral blade and flows toward the discharge pipe 29. It will be. In other words, the resistor 23 is a hindrance to the flow of water to be treated.

  The resistor body 23 provided in the blade body 22 is not limited to a hemispherical protrusion as shown in FIG. 4, and may have any shape such as a columnar shape, a conical shape, a polygonal column shape, or a polygonal column shape. In addition, any shape and length may be used as long as it is a resistance to the flow of water to be treated. Further, the number of resistors 23 is not limited. Furthermore, the resistor 23 may be continuously provided on the surface of the blade body 22 from the inflow pipe side to the discharge pipe side, for example.

  In the reaction tube 2 in which the spiral blade having the blade body 22 provided with such a resistor 23 is inserted, the water to be treated rotates spirally along the blade body 22 of the spiral blade as described above. In addition to flowing toward the discharge pipe 29, the flow of the water to be treated is disturbed on the surface of the blade body 22 having the resistor 23. Therefore, in the vicinity of the resistor 23, the water to be treated is stirred, the gas introduced from the gas introduction part 3 into the reaction tube 2 is more easily dissolved, and the air-fuel ratio can be further improved. . That is, the water to be treated can be treated by promoting the reaction of components in the water to be treated.

  Further, the gas dissolved in the water to be treated may become large bubbles due to water pressure and other influences. By providing the resistor 23 as described above, the bubbles remain so as to be caught by the resistor 23 and become small bubbles again so as to be crushed by the water to be treated. Thereby, it becomes easy to melt | dissolve in to-be-processed water again, and the fall of an air-fuel ratio can be prevented. That is, the water to be treated can be treated by reacting more components in the treated water.

  The gas introduction part 3 of the water treatment apparatus of the present invention described above may use an air-jet jet pump as shown in FIG. The water treatment apparatus of the present invention is not limited to the mixed-air jet pump shown in FIG. 5, and various types of conventional mixed-air jet pumps can be used. Hereinafter, the mixed-air jet pump and the water treatment apparatus of the present invention will be described with reference to FIG.

  The mixed air jet pump shown in FIG. 5 has a flow path 30, a nozzle 32, and a gas injection port 34. The flow path 30 has a bent portion 31, and a nozzle 32 is provided from the outside of the bent portion 31 toward the discharge side of the flow path 30. The nozzle 32 is provided with a pump (not shown) and a gas inlet 34. The discharge side of the flow path 30 is connected to the reaction tube 2 in the same manner as the gas introduction part 3 described above, and the water to be treated is sucked from the suction side of the flow path 30.

  The nozzle 32 is injected with high-pressure water to be treated. At this time, a gas that reacts with components in the water to be treated is injected from the gas inlet 34 into the water to be treated in the nozzle 32. As a result, the high-pressure water to be treated sucks gas and enters a gas-liquid mixed state (mixed state), and is jetted from the nozzle 32 into the flow path 30 as a jet 33. The jet 33 jetted in this way pushes the liquid in the flow path 30 or the gas at the start in the direction of the reaction tube 2 so that the vicinity of the bent portion 31 becomes negative pressure and sucks water to be treated into the flow path 30. be able to.

  When this mixed-air jet pump is used, high-pressure water to be treated which is sprayed from the nozzle 32 is sprayed in a mixed state with gas. And the to-be-processed water in a mixed-air jet pump mixes the to-be-processed water of an air-mixed state, and the to-be-processed water suck | inhaled by the flow path 30, and reacts the to-be-processed water which the gas mixed efficiently It can be introduced into the tube 2. Accordingly, the gas can be mixed more efficiently, the components in the water to be treated can be reacted smoothly, and the water to be treated can be treated more smoothly.

It is a block diagram which shows the structure of the water treatment apparatus of this invention. It is a figure which shows a part of internal structure of the reaction tube of the water treatment apparatus of this invention. It is a figure which shows the upper surface of the spiral blade of the water treatment apparatus of this invention. It is a figure which shows the shape of the spiral blade | wing of another example of the water treatment apparatus of this invention. It is a figure which shows schematic structure of the mixed air jet pump as an example of the gas introduction part of the water treatment apparatus of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Pump 2 Reaction tube 21 Rod body 22 Blade body 23 Resistance body 25 Inflow tube 29 Outlet tube 3 Gas introduction part 30 Flow path 31 Bending part 32 Nozzle 33 Jet 34 Gas inlet

Claims (5)

A reaction tube for reacting components in the water to be treated with a gas dissolved in the water to be treated;
An inflow pipe for allowing the water to be treated to flow into the reaction pipe;
A pump for introducing the water to be treated from the inflow pipe into the reaction pipe;
A gas introduction part for introducing the gas into the reaction tube;
A discharge pipe that is provided in the reaction tube and discharges treated water that has been treated from the treated water by reacting a component in the treated water with the gas introduced from the gas introduction unit;
A water treatment apparatus comprising: a rod body provided in the center of the reaction tube; and a spiral blade having a blade body spirally formed around the rod body.   The said blade | wing body is equipped with the resistor which resists the flow of the said to-be-processed water which flows in the said discharge pipe from the said inflow pipe | tube along the said spiral blade | wing body. The water treatment apparatus as described in. A drive source for rotating the rod is provided;
The water treatment apparatus according to claim 1, wherein the spiral blade is rotationally driven around the rod body in the reaction tube.   The water treatment apparatus according to claim 1, wherein the gas introduction unit is an air-mix jet pump using the water to be treated mixed with the gas.   The water treatment apparatus according to claim 1, wherein the gas is oxygen, ozone, hydrogen, or air.