KR101268165B1 - Water treatment facility using cavitation effect and induction heating - Google Patents

Abstract

PURPOSE: A water treatment apparatus is provided to be able to perform a powerful water treatment by activating water with irradiation of electromagnetic field, and using microbubbles generated by cavitation and water temperature rising effect by the eddy current. CONSTITUTION: A water treatment apparatus comprises a cavitation means(10), a discharge means(30), a storage bath(30), a reaction bath(40), an outlet line(50), a magnetization means(60) and a control unit. The cavitation means comprises a cavitation chamber(11), an impeller(12), and a rotating means(13) for rotating the impeller. A discharging means discharges the fluid flowed in to the cavitation chamber to the outside of the cavitation chamber in the state of maintaining the microbubbles generated within the cavitation chamber by cavitation generated by rotation of the impeller. The storage bath tentatively stores the fluid flowed in to the chamber of the cavitation means. The fluid discharged by the discharging means is flowed in to a reaction chamber(41) of the reaction bath, and microbubbles are collapsed within the reaction chamber. The outlet line transfers the fluid and microbubbles discharged by the discharging means to the reaction bath. The magnetization means generates an electromagnetic field on the outlet line. Multiple through-holes parallel to the rotation shaft of the impeller are equipped on the impeller. The magnetization means is inserted into a part of the through-holes.

Description

Water treatment facility using cavitation effect and induction heating

The present invention relates to a water treatment apparatus using cavitation and electromagnetic induction, and more particularly, water treatment can be performed in a state in which the microbubbles generated by the cavitation effect are magnetized by passing through an electromagnetic field. A water treatment apparatus using cavitation and electromagnetic induction.

Cavitation is a phenomenon in which a small portion of a liquid is vaporized in a state surrounded by a liquid and is also called cavitation or cavitation. In the case where the relative velocity of the object and liquid is very large, it occurs when the liquid registration on a part of the solid surface becomes less than the vapor pressure of the liquid. It occurs in the impeller of the pump or the screw of the ship. (Source: Naver Chemistry Dictionary; http://terms.naver.com/entry.nhn?cid=2904&docId=1596481&mobile&categ oryId = 2904)

Bubbles generated by cavitation collapse and cause serious damage to ship propellers and pump impellers. It is known that the temperature generated when bubbles generated by cavitation collapse is more than thousands of degrees, and the pressure is also more than several hundred atmospheres. This high-density energy is transmitted to the surroundings in the form of shock waves, and when bubbles are broken down, water molecules are decomposed into OH radicals and H radicals by pyrolysis, of which OH radicals are known as materials having strong oxidizing power. In addition, during the thermal decomposition process, the molecular bonds of the hardly decomposable substance are broken and oxidized by OH radicals, and the water temperature is increased.

On the other hand, water treatment refers to the treatment of raw water before treatment according to its purpose, but in a narrow sense, it may mean to purify water such as sewage treatment or water treatment, but in the present invention, water treatment includes water treatment in the above-described narrow meaning. However, it is used in a broad sense to include all manipulations on the water, such as heating to raise the temperature of the water. As an example of water treatment in a narrow sense, treatment is performed to solubilize sludge by using microbubbles generated by cavitation to reduce the amount of sludge generated in sewage treatment plants and wastewater treatment plants. Treatment to maximize the temperature, powerful local high pressure, high temperature effect and strong oxidizing agent OH radical to kill Legionella in cooling tower, and chemical treatment of difficult to biodegradable materials such as chromatic material and TCE in waste water It is not a method but a treatment to decompose with an environmentally friendly treatment method.

The present invention can be used for various purposes by using the cavitation to be solved, and to provide a water treatment apparatus using cavitation and electromagnetic induction that can be more powerful than the case of simply using the cavitation effect.

As a means for solving the above-mentioned problems,

In a water treatment device using cavitation and electromagnetic induction,

Cavitation means including a cavitation chamber, an impeller and rotating means for rotating the impeller, the cavitation means for generating cavitation to the fluid introduced into the cavitation chamber;

Discharge means for discharging fluid introduced into the cavitation chamber to the outside of the cavitation chamber while maintaining fine bubbles generated in the cavitation chamber by cavitation generated by the rotation of the impeller;

A reservoir for temporarily storing the fluid flowing into the chamber of the cavitation means;

A reaction tank including a reaction chamber into which the fluid discharged by the discharge means is introduced and in which microbubbles are collapsed;

A discharge pipe for transporting the fluid and the fine bubbles discharged by the discharge means to the reaction tank;

Magnetization means for generating an electromagnetic field in said discharge pipe;

And a controller for controlling the flow rate and the flow rate of the fluid moving through the impeller rotational speed of the cavitation means and the discharge pipe.

The impeller is provided with a plurality of through-holes parallel to the axis of rotation of the impeller, and at least a portion of the through-hole provides a water treatment apparatus using cavitation and electromagnetic induction, characterized in that the magnetization means for forming a magnetic field is inserted. .

The impeller is a circular cross-section, the outer peripheral surface is formed with a plurality of grooves parallel to the axis of rotation of the impeller in the direction of the axis of rotation of the impeller,

The inner circumferential surface of the cavitation chamber has a circular cross section, and the inner circumferential surface is preferably formed with a plurality of protrusions in the impeller direction.

The rotational speed of the impeller is preferably controlled to rotate at a speed of 100 to 5000rpm by the controller.

The discharge pipe is made in a pair,

The discharge pipe of any one of the pair of discharge pipes is magnetized to the north pole of the cavitation chamber side and the south pole of the reaction tank, and the other one of the discharge pipes is the south pole of the cavitation chamber side and the north pole of the reaction tank. It is good to be magnetized.

The fluid flowing into the cavitation chamber may be pressurized to increase the speed at which the fine bubbles generated by the cavitation action are dispersed.

It is preferable to further include a pressurizing means for pressurizing the fluid flowing through the discharge pipe to the reaction tank to destroy the fine bubbles.

The pressurizing means may be formed at a portion where the reaction tank and the discharge pipe are in contact with each other, and may be configured as a cone-shaped inlet portion whose diameter increases as the distance from the discharge pipe increases.

The reactor is preferably provided to be detachable.

It is more preferable to further include a pretreatment means for removing foreign matter of the fluid flowing into the cavitation means.

In addition, the magnetization means inserted into the through-hole provided in the impeller is preferably arranged differently in polarity with the adjacent magnetization means,

The through-holes provided in the impeller are arranged in three rows along the circumference of the impeller, and the magnetization means is most preferably inserted only in a column farthest from the column closest to the axis of rotation of the impeller.

According to the present invention, it is possible to provide a water treatment apparatus using cavitation and electromagnetic induction capable of strong water treatment by irradiating and activating the water temperature by the eddy current and the electromagnetic field irradiated with the microbubbles generated by the cavitation. .

1 is a schematic view of a water treatment apparatus according to one embodiment of the present invention.
2 is a diagram for explaining a control unit;
3 is a cross-sectional view of the impeller shown in FIG. 1.

Hereinafter, a water treatment apparatus using cavitation and electromagnetic induction according to an embodiment of the present invention will be described with reference to the drawings to provide specific contents for implementing the present invention.

1 is a view for explaining a water treatment apparatus according to an embodiment of the present invention, FIG. 2 is a view for explaining a control unit, Figure 3 is a cross-sectional view of the impeller shown in FIG.

As shown in FIGS. 1 and 2, the apparatus for treating water using cavitation and electromagnetic induction according to the present embodiment includes a cavitation means 10, a discharge means 20, a reservoir 30, a reaction tank 40, and an exhaust pipe 50. ), The magnetization means 60, the control unit 70, the preprocessing means (80).

The cavitation means comprises a cavitation chamber 11, an impeller 12, a rotating means 13. The cavitation chamber 11 is configured to have a space for accommodating the impeller 12 and the fluid to be treated. The impeller 12 rotates in the cavitation chamber 11 by the rotating means 13 to generate a cavitation phenomenon. A motor is used as the rotating means 13 and the rotation speed thereof is rotated at 100 to 5000 rpm.

In this embodiment, the cavitation chamber 11 has an inner circumferential surface having a circular cross section, and a plurality of protrusions 111 in the impeller direction are formed.

The impeller 12 is configured in the shape shown in Figure 3, the outer peripheral surface is circular, the outer peripheral surface is provided with a groove 123 in the center of rotation direction. A plurality of through holes 121 are formed in the impeller in the rotation axis direction. The through holes 122 are provided in three rows along the circumference of the impeller as shown in FIG. 3.

A portion of the through hole 121 is inserted into a magnetic means (magnet) 123. In this embodiment, only the through holes positioned in the innermost and outermost columns are inserted as shown in FIG. The magnetizing means is arranged differently from the adjacent magnetizing means and as shown in FIG.

The impeller 12 is rotated at a high speed of 100 ~ 5000rpm according to the size of the diameter and the negative pressure is generated in the wing portion of the end and the projection 111 of the cavitation chamber 11 by the rotation of the impeller. When the negative pressure falls below the saturated steam pressure, dissolved air dissolved in the water is separated, or steam is generated between the impeller and the fluid (in this specification, the fluid includes water) to form fine bubbles.

In this case, the dimensionless number indicating the sensitivity of the cavitation is called the cavitation number, which is defined as the difference between the pressure in the pump and the saturated steam pressure divided by the kinetic energy. The lower the number of cavitations, the more easily cavitation is characterized.

Bubbles generated by cavitation decay within a very short time. The decay time is theoretically known to be 0.05 ~ 0.1 seconds, but in fact, it takes longer to decay when the pressure change is small. On the other hand, higher pressures and temperatures are known to occur when clusters decay in a cluster form than collapse of a single bubble, which means that when the external bubbles collapse, the pressure is transferred toward the internal bubbles and the internal bubbles Because it is more violently collapsed.

Pressures of hundreds of atmospheres or more and thousands of degrees of temperature generated by the collapse of bubbles pyrolyze water molecules and ionize them into OH · radical and H · radical.

H ₂ O → H. + OH.

OH + OH-> H ₂ O ₂

O ₂ → 2O

O + H ₂ O → OH + OH

H + O ₂ → HO ₂

HO ₂ + HO ₂ → H ₂ O ₂ + O ₂

The OH radical generated by the thermal decomposition of water is an intermediate product with stronger oxidizing power than ozone (O ₃ ). 1) Sterilization and disinfection 2) Activation 3) Oxidative decomposition of hardly decomposable organic substances 4) Decolorization, deodorization and deodorization Action 5) It has the function of inhibiting the production of carcinogenic substances (THM), so it can be used in AOP (Advanced Oxydation Process).

The cavitation action is very actively generated by the interaction of the protrusion 111 formed in the cavitation chamber 11 and the groove 123 formed in the impeller 12.

On the other hand, the magnet 122 inserted into the through hole 121 of the impeller 12 rotates at a high speed with the impeller 12 to cause a rapid magnetic flux change in the cavitation chamber, the eddy current is generated due to the change of the magnetic flux And, the heat generated by the eddy currents to increase the temperature of the incoming fluid. In addition, the rapid change in magnetic flux is activated by polarizing the water molecules, and helps to decompose the pollutants contained in the water.

The discharge means 20 is a means for discharging the fluid introduced into the cavitation chamber 11 to the outside of the cavitation chamber 11 while maintaining the micro bubbles generated in the cavitation chamber 11 by cavitation In this embodiment, a pump is used. The pump pressure is appropriately in the range of 0.5 to 5 atmospheres, and the flow rate is determined in consideration of the time (within 0.1 to 5 seconds) at which bubbles remain in the cavitation chamber 11. Insufficient flow and pressure can cause bubbles to break down inside the cavitation system, causing serious damage to the unit. Therefore, it is desirable to separate and discharge the generated bubbles at an appropriate flow rate and pressure as soon as they are generated so that the generated bubbles do not adhere to the impeller of the cavitation device. The flow rate of the fluid is determined to be shorter.

The reservoir 30 is configured to temporarily store the fluid flowing into the cavitation chamber 11.

The reactor 40 is composed of a reaction chamber 41 and the pressing means. Pressure and temperature generated when the micro bubbles are destroyed can cause a corrosion state in the reaction chamber 41, so the reaction chamber 41 is connected to both ends by a flange 44, so that the structure can be replaced immediately in case of serious damage. Made with. (This means detachable structure)

The reaction chamber 41 is a space in which the fluid discharged by the discharge means 20 flows in and the microbubbles are collapsed therein to react with the fluid.

The pressurizing means is configured to apply pressure to the microbubbles so that the microbubbles located in the reaction chamber 41 can be collapsed at a higher speed. The pressurizing means includes a conical inlet part 42 and an outlet part 43. do.

The mechanism by which the fine bubbles are pressed by the inlet 42 is as follows.

Bernoulli's theorem is defined by

The larger the diameter of the fluid flows, the lower the speed and the higher the pressure inside. The inlet 42 has a cone shape that increases in diameter from the cavitation chamber 11 toward the reaction chamber 41. Just before the speed slows down, the internal pressure increases, which is why the microbubbles are pressurized. In addition to this, the discharge portion 43 has a cone shape that becomes narrower in the direction away from the reaction chamber 42. However, the diameter is narrowed just before exiting the reaction chamber 42, so that the pressure increases once again.

The discharge pipe 50 is a pipe for transporting the fluid and the fine bubbles discharged by the discharge means to the reaction tank. In this embodiment, the discharge pipe 50 is composed of two as shown in FIG.

The magnetization means 60 is a configuration for generating an electromagnetic field in the discharge pipe 50, the pipe of any one of the two pipes of the cavitation means 10 side of the N pole the reactor 10 side of the S pole The electromagnetic field is generated to be charged, and the other pipe generates the electromagnetic field to be charged with the opposite polarity. This is clearly shown in FIG. 1. The magnetization means 60 may use a permanent magnet or an electromagnet. When using a permanent magnet, it is preferable to use a neodymium-based magnet known to have a strong magnetic field. Using an electromagnet has the advantage of generating a strong magnetic field compared to a permanent magnet, but it is inefficient in terms of energy because power is consumed.

The controller 60 is configured to control the rotational speed of the impeller 12 and the flow rate and flow rate of the fluid moving through the discharge pipe 50 to control the pressure of the pump. On the other hand, if the electromagnet is used as the magnetizing means, as shown in Figure 2 the magnetizing means is also controlled by the controller.

The pretreatment means 80 is a means for removing foreign matter in the fluid to be introduced into the reservoir (30). In FIG. 1, reference numeral 81 denotes a pipe through which fluid is introduced into the pretreatment means 80, and reference numeral 82 denotes a pipe for removing foreign substances filtered out from the pretreatment means 80.

Hereinafter, the mechanism in which the fluid is processed by the water treatment device having the above-described configuration will be replaced with a description of the functions, operations, and effects of each configuration.

The fluid to be treated (as described above, is a concept including all operations applied to water, such as heating with removal of contaminants) is a state in which foreign matter such as suspended matter or contaminants is removed by the pretreatment means 80. The fluid introduced into the storage tank 30 and the fluid introduced into the storage tank 30 passes through the cavitation means 10 and moves to the reaction means 40 through the two discharge pipes 50 with microbubbles inside thereof. In this case, the micro bubbles are exploded in the reaction chamber 41 having a pressurizing means (a cone-shaped inlet part 41) in which pressure is rapidly increased, thereby causing a reaction. As described above, it can reach hundreds to thousands of atmospheres, and temperatures can reach thousands of degrees. It is possible to break temporarily by increasing the pressure, and the increase in the breaking pressure has a relation proportional to the ratio of the diameter of the reaction chamber 41 side to the diameter of the cavitation means 10 side at the inlet 41. In addition, since the bubbles are destroyed in the form of clusters instead of unit bubbles, the pressure, temperature, and shock waves generated when the bubbles are destroyed are further increased. Since the effect is halved, it is to be able to receive the effect of a strong positive pressure at negative pressure at a time so that the fine bubbles introduced into the reaction chamber 41 by the pressing means.

On the other hand, when a strong magnetic force line is applied to the liquid, the liquid molecules are excited by the action of the magnetic moment and the magnetic field of the liquid molecules to maintain an unstable state. The two discharge pipes (50), as described above, arrange the magnets to generate magnetic fields in different directions. When the fluid moves through the two discharge pipe 50, the ion is polarized by the electromagnetic induction effect of Faraday. That is, the water molecules are excited by the interaction between the magnetic moments of the water molecules and the magnetic field, and the transition occurs to an unstable activated state. This is because an induced voltage occurs when polarization of free electrons occurs. In this case, the speed of the fluid is preferably maintained at a speed of at least 1.5 m / sec. When water is activated, the function of removing odor, nitrogen nitrate, fluorine, and calcium carbonate ion that causes scale occurs to purify water. An unstable state can be said to be activated by absorbing magnetic energy. Activation of water improves the decomposition and purification of pollutants. In addition, the effect is doubled when the magnetized liquid collides with the opposite polarity of the N pole and the S pole. The device seeks to double the reaction effect by first inducing a liquid which has been transferred to an unstable state by cavitation into a more unstable state by an electromagnetic effect and colliding in the reaction chamber.

In summary, in the reaction chamber 41, 1) local pressure and high temperature are generated due to the breakdown of microbubbles. Generation of OH radicals and H radicals 4) Activation mechanisms of fluid molecules due to magnetic field effects in cavitation chambers and piping at once, 1) destruction of sludge cells, 2) death of Legionella bacteria in cooling towers, 3) chromatic substances in wastewater And the destruction of hardly decomposable biodegradable substances such as TCE, 4) removal of odor, 5) removal of nitrogen nitrate, fluorine, and calcium carbonate ion causing scale.

Experiments in which the sludge was pretreated using the water treatment of the present invention and digested in an anaerobic digester showed that the SS component of the sludge was reduced by more than 25%, the sludge was reduced by more than 30%, and the amount of methane gas generated was increased by more than 30%. Brought. In addition, the supply of energy for heating the sludge digester is no longer necessary, proving an environmentally friendly energy saving device.

While the above has provided specific details for carrying out the present invention by describing one preferred embodiment of the present invention, the technical idea of the present invention is not limited to the described embodiments and does not contradict the technical idea of the present invention. It can be embodied in water treatment devices using various types of cavitation and electromagnetic induction within the scope.

10: cavitation means 20: discharge means
30: reservoir 40: reactor
50: discharge pipe 60: magnetization means

Claims (11)

In a water treatment device using cavitation and electromagnetic induction,
Cavitation means including a cavitation chamber, an impeller and rotating means for rotating the impeller, the cavitation means for generating cavitation to the fluid introduced into the cavitation chamber;
Discharge means for discharging fluid introduced into the cavitation chamber to the outside of the cavitation chamber while maintaining fine bubbles generated in the cavitation chamber by cavitation generated by the rotation of the impeller;
A reservoir for temporarily storing the fluid flowing into the chamber of the cavitation means;
A reaction tank including a reaction chamber into which the fluid discharged by the discharge means is introduced and in which microbubbles are collapsed;
A discharge pipe for transporting the fluid and the fine bubbles discharged by the discharge means to the reaction tank;
Magnetization means for generating an electromagnetic field in said discharge pipe;
And a controller for controlling the flow rate and the flow rate of the fluid moving through the impeller rotational speed of the cavitation means and the discharge pipe.
The impeller is provided with a plurality of through-holes parallel to the axis of rotation of the impeller, at least a portion of the through-hole water treatment apparatus using cavitation and electromagnetic induction, characterized in that the magnetization means for forming a magnetic field is inserted.
The method of claim 1,
The impeller is a circular cross-section, the outer peripheral surface is formed with a plurality of grooves parallel to the axis of rotation of the impeller in the direction of the axis of rotation of the impeller,
The inner circumferential surface of the cavitation chamber has a circular cross section, the inner circumferential surface of the water treatment apparatus using cavitation and electromagnetic induction, characterized in that a plurality of projections in the direction of the impeller is formed.
The method according to claim 1 or 2,
The rotation speed of the impeller is controlled by the control unit to rotate at a speed of 100 to 5000rpm, characterized in that the water treatment apparatus using cavitation and electromagnetic induction.
The method of claim 1,
The discharge pipe is made in a pair,
The discharge pipe of any one of the pair of discharge pipes is magnetized to the north pole of the cavitation chamber side and the south pole of the reaction tank, and the other one of the discharge pipes is the south pole of the cavitation chamber side and the north pole of the reaction tank. Water treatment device using cavitation and electromagnetic induction, characterized in that the magnetization.
The method of claim 1,
Pressurizing the fluid flowing into the cavitation chamber to increase the rate of dispersion of the micro bubbles generated by the cavitation action, water treatment device using the cavitation and electromagnetic induction.
The method of claim 1,
And a pressurizing means for pressurizing the fluid flowing through the discharge pipe into the reaction tank to destroy the micro bubbles.
The method according to claim 6,
The pressurizing means is formed in a portion where the reaction tank and the discharge pipe is in contact with the water treatment device using cavitation and electromagnetic induction, characterized in that the cone-shaped inlet portion is larger in diameter as the distance away from the discharge pipe.
The method of claim 1,
The reactor is a water treatment apparatus using cavitation and electromagnetic induction, characterized in that the separation is provided.
The method of claim 1,
Water treatment device using cavitation and electromagnetic induction further comprising a pre-treatment means for removing foreign matter of the fluid flowing into the cavitation means.
The method of claim 1,
Magnetizing means inserted into the through-hole provided in the impeller is water treatment apparatus using cavitation and electromagnetic induction, characterized in that the polarization is arranged differently from the adjacent magnetizing means.
The method of claim 10,
The through-holes provided in the impeller are arranged in three rows along the circumference of the impeller, and the magnetization means is inserted only in the column farthest from the column closest to the axis of rotation of the impeller.

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