JP4102657B2 - Water treatment equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention is a water treatment apparatus, particularly for decomposing and detoxifying substances such as harmful chemical substances and pollutants dissolved in water, efficiently treating organic substances such as sludge, and sterilizing pathogenic E. coli etc. The present invention relates to a water treatment device for treatment.
[0002]
[Prior art]
As a conventional water treatment apparatus for decomposing and detoxifying substances such as harmful chemical substances and pollutants dissolved in water, or treating organic substances such as sludge, there is one disclosed in Japanese Patent No. 2574736 (Patent Document 1). is there. This conventional water treatment apparatus is for continuously detoxifying a liquid to be treated such as water and waste liquid continuously and efficiently. Hereinafter, this conventional water treatment apparatus will be described with reference to the drawings.
[0003]
FIG. 4 is a cross-sectional view showing a conventional water treatment apparatus.
[0004]
As shown in FIG. 4, the conventional water treatment apparatus is provided with a liquid inflow portion 21 into which a liquid to be treated such as water or waste liquid flows, and a part of the fluid flow path downstream of the liquid inflow portion 21 is provided. It is squeezed by the Venturi tube 22. The venturi tube 22 is formed with a throttle portion 22A, a throat portion 22B, and a widened portion 22C from the upstream side.
[0005]
An oxidizing gas inlet 23 for waste liquid treatment is provided slightly downstream of the throat portion 22B. For example, ozone is used as the oxidizing gas. Hereinafter, explanation will be given by taking ozone as an example. A pressure mixing flow device 24 is provided on the downstream side of the expanding portion 22C. The pressure mixing flow device 24 is formed in a box shape, and a pressure mixing flow channel 25 in which horizontal flow channels 25A and vertical flow channels 25B are alternately provided in stages is formed. A nozzle hole 26 is provided at the outlet of the pressurized mixing channel 25, and the treated liquid is discharged from the nozzle hole 26 to the outside of the pressurized mixed flow device 24.
[0006]
In this conventional water treatment device, ozone is introduced into the flow of the liquid to be treated from the inlet 23 provided slightly downstream of the throat 22B, and the ozone and the treatment are performed in the widened portion 22C where the flow becomes slow. The ozone that has flowed in while being mixed with the liquid is pressure-dissolved in the liquid to be processed, and further, the gas flows in the upper part of the pressure mixing flow path 25 and the liquid to be processed flows in the lower part of the flow path. The contact area between ozone and the liquid to be treated is increased.
[0007]
In addition, the nozzle hole 26 is provided at the outlet of the pressure mixing channel 25 where the liquid to be treated flows down from above to form an outlet-side throttle, thereby increasing the static pressure inside the pressure mixing channel 25. The reaction and dissolution efficiency can be increased.
[0008]
Furthermore, since the liquid outlet for the liquid to be processed is lower than the liquid inlet for the liquid to be processed, the mixed flow of ozone and the liquid to be processed is stagnated in the pressure mixing channel 25. Accordingly, since the liquid to be processed having a higher density is easier to flow out than ozone, more ozone is contained in the pressure mixing flow path 25 than the liquid to be processed. Therefore, even if the ratio of ozone in the mixed flow of ozone flowing into the pressure mixing channel 25 and the liquid to be processed is small, the ratio of ozone is increased in the pressure mixing channel 25. As a result, the treatment efficiency of the liquid to be treated with ozone is increased.
[0009]
[Patent Document 1]
Japanese Patent No. 2574736
[Problems to be solved by the invention]
However, the above-described conventional water treatment apparatus has the following problems.
[0011]
(1) Since ozone is injected from the widened portion 22C slightly downstream from the throat portion 22B of the venturi tube 22, bubbles in the liquid to be treated grow in the low pressure throat portion 22B, and the pressure rises. Compared to the time until the portion 22C collapses, the time for ozone to contact the liquid to be treated is short. In other words, the time required for ozone to sufficiently diffuse into the liquid to be treated cannot be taken from the interface between ozone and the liquid to be treated.
[0012]
(2) Cavitation bubbles that are generated in the throat portion 22B at a low pressure of the venturi tube 22 and collapse at the expanded portion 22C at a high pressure are composed of a large number of bubble groups. At 22 outlets, many fine bubbles are formed. However, in the conventional water treatment apparatus, ozone is injected from the part where the cavitation bubbles enter the collapse stage, and therefore the bubble size of ozone in the expanded portion 22C is larger than the size of the fine bubbles. This means that the area of the gas-liquid interface between the ozone bubbles and the liquid to be treated is reduced, which causes a reduction in the efficiency of the oxidation treatment with ozone.
[0013]
(3) Since ozone is injected in the vicinity of the expanding portion 22C, which is the bubble collapse portion, the pressure and temperature inside the bubble when the cavitation bubble collapses decreases. Conventional water treatment apparatuses perform oxidation treatment of a liquid to be treated by using high temperature and high pressure generated when cavitation bubbles collapse, but the oxidation treatment efficiency of the liquid to be treated decreases due to a decrease in the bubble internal pressure and temperature. .
[0014]
Accordingly, an object of the present invention is to solve the above-described problems of the conventional water treatment apparatus, and to provide a water treatment apparatus capable of improving the treatment efficiency.
[0015]
[Means for Solving the Problems]
The invention according to claim 1 is a water treatment apparatus in which a venturi pipe for generating cavitation is attached to a flowing water pipe through which a liquid to be treated flows, wherein a throttle part, a throat part, and a spread part are formed from the upstream side. An oxidizing solution inlet provided upstream of the venturi pipe and a cylindrical shape, and provided so as to constitute a part of the straight pipe line of the flowing water pipe downstream of the venturi pipe. And an ultrasonic wave irradiation means for irradiating the liquid to be treated flowing in the flowing water pipe with ultrasonic waves.
[0016]
According to the present invention, the inlet of the oxidizing solution is provided upstream from the throttle portion of the venturi tube so that an oxidizing solution such as hydrogen peroxide water can be injected into the liquid to be treated from the inlet. Compared to the conventional water treatment apparatus described above, a large number of fine bubble nuclei can be generated in the liquid to be treated, and in the liquid to be treated from the interface between the oxidizing solution and the liquid to be treated. In addition, a sufficient time is required for the oxidizing solution to sufficiently diffuse. Moreover, according to this invention, an ultrasonic wave can be efficiently irradiated to a to-be-processed liquid in a flowing water pipe by arrange | positioning an ultrasonic irradiation means concentric with a flowing water pipe.
[0017]
In addition, since the ultrasonic irradiation means is provided on the downstream side of the venturi pipe and the ultrasonic wave is applied to the liquid to be processed flowing in the flowing water pipe, the cavitation bubbles collapsed at the broadening section of the venturi pipe are formed. Further, it reaches the ultrasonic wave irradiation means as fine and numerous bubble nuclei. As a result, these bubbles repeatedly grow and collapse according to the vibration frequency due to ultrasonic vibration (pressure fluctuation), and the decomposition efficiency of harmful substances due to the generated high temperature and pressure is only Venturi tube. Higher than
[0018]
Furthermore, by using an oxidizing solution as the oxidizing agent, the efficiency of mixing the oxidizing agent into the liquid to be treated is higher than that of a gaseous oxidizing agent such as ozone, and accordingly, higher oxidation treatment efficiency can be obtained.
[0019]
The invention according to claim 2 is characterized in that, in the invention according to claim 1 , another inlet for oxidizing solution is provided in the flowing water line between the venturi pipe and the ultrasonic wave irradiation means. It is what you have.
[0020]
According to the present invention, by providing another inlet for the oxidizing solution in the flowing water line between the venturi pipe and the ultrasonic irradiation means, the oxidation of the liquid to be treated is further promoted. The decomposition efficiency can be further increased.
[0023]
The invention described in claim 3 is characterized in that, in the invention described in claim 1 or 2, the injection port is a hydrogen peroxide solution injection port.
[0024]
According to the present invention, by using hydrogen peroxide water as the oxidizing solution, the treatment liquid can be easily oxidized.
[0025]
The invention according to claim 4 is the invention according to any one of claims 1 to 3, wherein a plurality of the venturi tubes and the ultrasonic irradiation means are alternately arranged in series. It is what has.
[0026]
According to this invention, the oxidation treatment efficiency of the liquid to be treated is further improved by increasing the number of the venturi tubes and the ultrasonic irradiation means.
[0027]
DETAILED DESCRIPTION OF THE INVENTION
Next, an embodiment of the water treatment apparatus of the present invention will be described with reference to the drawings.
[0028]
FIG. 1 is a schematic cross-sectional view showing a water treatment apparatus according to the present invention, and FIG. 2 is a schematic cross-sectional view showing the water treatment apparatus according to the present invention in which another ultrasonic irradiation means is arranged.
[0029]
The water treatment apparatus of the present invention comprises a venturi pipe 2 and an ultrasonic tube 3 as an ultrasonic irradiation means provided in the middle of a flowing water pipe 1 through which water to be treated is sent by a pump (not shown). ing.
[0030]
The flowing water pipe 1 has straight pipes 1a, 1b and 1c. The venturi tube 2 includes a throttle portion 2a, a throat portion 2b, and a widened portion 2c, which are formed in this order from the upstream side. The ultrasonic tube 3 is formed in a cylindrical shape and constitutes a part of the straight pipe line 1 c on the downstream side of the venturi pipe 2. The straight pipe 1 a upstream of the venturi pipe 2 is provided with an inlet 4 for hydrogen peroxide water as an oxidizing solution.
[0031]
The throttle part 2a connecting the straight pipe line 1a and the throat part 2b of the venturi pipe 2 has a maximum diameter part that is the same as the diameter of the straight pipe line 1a and a minimum diameter part that is the same as the diameter of the throat part 2b. The diameter is reduced in a shape such that the cross-sectional shape in the pipe direction is a ¼ arc. That is, the throttle portion 2a intersects the straight pipe 1a at a right angle and is smoothly connected to the throat portion 2b.
[0032]
If another injection port 5 of hydrogen peroxide as an oxidizing solution is provided in the straight pipe line 1b between the venturi tube 2 and the ultrasonic tube 3, the effect of oxidizing the liquid to be processed is further enhanced. In this case, the length of the straight pipe portion 1b should be such a length that the microbubbles generated at the outlet 4 of the expanding portion 2c of the venturi pipe 2 do not recombine and coalesce.
[0033]
In the example shown in FIG. 1, one Venturi tube 2 and one ultrasonic tube 3 are arranged, but another Venturi tube and ultrasonic tube may be alternately arranged in series. Further, in this case, another injection port of hydrogen peroxide may be provided in the straight pipe portion between another venturi tube and the ultrasonic tube. However, as the number of the venturi tubes 2 increases, it is necessary. Since the number of water pump heads to be increased and the energy required for water supply also increase, it is considered that about 2 to 3 are appropriate for practical use. Further, a plurality of venturi tubes may be arranged in series, and an ultrasonic tube may be arranged downstream of the most downstream venturi tube.
[0034]
Next, the above-described water treatment method by the water treatment apparatus of the present invention will be described by taking as an example the case where one Venturi tube 2 and one ultrasonic tube 3 are used.
[0035]
Cavitation bubble nuclei are generated in the liquid to be treated flowing in the straight pipe 1a from the inlet 4 provided in the straight pipe 1a upstream of the inlet of the throttle portion 2a of the venturi pipe 2, and OH radicals and oxidizing power are generated. Hydrogen peroxide water (H ₂ O ₂ ) capable of generating strong ozone or the like is injected under pressure.
[0036]
By doing so, the injected hydrogen peroxide solution is uniformly diffused in the pipe line until reaching the throat portion 2a of the venturi pipe 2 where cavitation occurs.
[0037]
The liquid to be treated that has flowed into the venturi 2 has a static pressure that suddenly decreases as the flow velocity in the throttle portion 2a increases rapidly. And when the static pressure of this part falls below a saturated water vapor pressure, many fine cavitation bubble nuclei contained in the liquid to be treated are exposed to the low pressure of the throat 2b and grow rapidly.
[0038]
It is desirable that the length (L) of the parallel portion of the throat portion 2b is at least three times the diameter d of the throat portion 2b. This is because the contact time between the cavitation bubbles and the harmful chemical substance dissolved in the liquid to be treated can be increased. Furthermore, the grown cavitation bubble collapses rapidly due to a rapid pressure increase accompanying a decrease in the flow velocity in the spreading portion 2c.
[0039]
Among toxic substances contained in an aqueous solution, volatile substances are taken into the bubbles through the gas-liquid interface between the bubbles and the liquid during the growth of the cavitation bubbles, and the high temperature, high pressure and OH radical generated when the cavitation bubbles collapse. It is decomposed by the action of On the other hand, it is considered that a non-volatile substance is not taken into the bubble so much and is decomposed by being exposed to high temperature and high pressure at the gas-liquid interface.
[0040]
Furthermore, substances with large molecular weights such as organic substances and microorganisms such as Escherichia coli with cell membranes are destroyed by the action of OH radicals with strong turbulence, impact pressure, high temperature and strong oxidizing power due to collapse of cavitation bubbles in the vicinity. It is considered that it will be decomposed, resulting in low molecular weight, solubilization, and death.
[0041]
Further, the cavitation bubbles generated, grown and collapsed in the upstream venturi tube 2 are innumerable fine bubble groups at the outlet 6 of the expanded portion 2c of the venturi tube 2, and these fine bubble groups are Then, it flows into the ultrasonic tube 3 arranged on the downstream side and becomes a new bubble nucleus for generating ultrasonic cavitation.
[0042]
Therefore, compared with a case where ultrasonic treatment is performed only with a normal ultrasonic oscillator, ultrasonic irradiation is performed in a place where a large number of cavitation bubble nuclei (causing the occurrence of cavitation) exist. As a result, the frequency of cavitation increases dramatically.
[0043]
In the ultrasonic tube 3, since the ultrasonic energy converges toward the center, the ultrasonic energy is significantly stronger than the ultrasonic energy generated by a normal flat plate-like ultrasonic oscillator. Be exposed. Accordingly, a large positive and negative pressure is repeatedly generated around the cavitation bubble nucleus, and the cavitation bubble grows and collapses repeatedly according to the pressure fluctuation. As a result, the processing efficiency of harmful substances contained in water is also greatly increased compared to the case where only the Venturi tube 2 or only the ultrasonic tube 3 is used.
[0044]
Also, another oxidizing solution injection port 5 is provided between the venturi tube 2 and the ultrasonic tube 3, and hydrogen peroxide is injected into the liquid to be processed from here, thereby further improving the processing efficiency of harmful substances. Can be increased.
[0045]
As shown in FIG. 2, in place of the cylindrical ultrasonic tube 3 described above, an ultrasonic irradiation means is constituted by a plurality of parallel donut-shaped ultrasonic oscillators 7 arranged in parallel. It is good also as a part of flowing water pipe line of to-be-processed water. In this case, the ultrasonic wave irradiation means has a higher degree of freedom in setting the frequency of the ultrasonic wave, but requires more power.
[0046]
【Example】
Next, the present invention will be further described with reference to examples.
[0047]
It is provided with one venturi tube and one ultrasonic irradiation means, and the oxidizing solution injection port is a volatile harmful chemical substance using a water treatment device that is only upstream of the venturi tube. Decomposition experiments were performed on m-chlorophenol.
[0048]
The relationship between the elapsed time from the start of the experiment and the concentration of m-chlorophenol (mg / l) in the liquid to be treated is compared with the result of the same experiment conducted with only one venturi tube as shown in FIG. Shown in
[0049]
In this case, the flow rate of the liquid to be treated flowing in the flowing water pipe is 210 (l / min) in both cases, and the amount of the hydrogen peroxide solution injected from the straight pipe portion 1a on the upstream side of the venturi pipe 2 is the amount to be treated. The concentration of the hydrogen peroxide solution in the liquid was set to 1000 ppm.
[0050]
As is apparent from FIG. 3, it can be seen that the decomposition of m-chlorophenol proceeds faster when the water treatment device of the present invention is used than when only the venturi tube is used.
[0051]
【The invention's effect】
As described above, according to the present invention, in the water treatment apparatus in which the venturi pipe is arranged in the flowing water pipe through which the liquid to be treated flows, the inlet for the oxidizing solution is provided on the upstream side of the venturi pipe, By providing ultrasonic irradiation means downstream of the venturi tube, the pressure loss of the pipeline system is small, an excellent decomposition treatment performance of harmful substances can be obtained, and a high decomposition treatment can be performed in a short time. Useful effects are brought about.
[Brief description of the drawings]
FIG. 1 is a schematic sectional view showing a water treatment apparatus of the present invention.
FIG. 2 is a schematic cross-sectional view showing a water treatment apparatus of the present invention provided with another ultrasonic irradiation means.
FIG. 3 is a graph showing the relationship between elapsed time and the concentration of m-chlorophenol in the liquid to be treated.
FIG. 4 is a cross-sectional view showing a conventional water treatment apparatus.
[Explanation of symbols]
1: flowing water pipes 1a, 1b, 1c: straight pipe line 2: venturi pipe 2a: throttle part 2b: throat part 2c: spreading part 3: ultrasonic tube 4: injection port for hydrogen peroxide 5: hydrogen peroxide water Inlet 6: Venturi outlet 7: Ultrasonic vibrator 21: Liquid inflow part 22: Venturi tube 22A: Throttle part 22B: Throat part 22C: Spreading part 23: Oxidizing gas inlet 24: Pressurized mixed flow device 25 : Pressurized mixing channel 25A: Horizontal channel 25B: Vertical channel 26: Nozzle hole

Claims (4)

In a water treatment apparatus in which a venturi pipe in which cavitation occurs, in which a narrowed part, a throat part, and a widened part are formed from the upstream side in a flowing water pipe through which a liquid to be treated flows,
An oxidizing solution inlet provided upstream of the venturi pipe and a cylindrical shape are provided so as to constitute a part of a straight pipe line of the flowing water pipe downstream of the venturi pipe. A water treatment apparatus comprising: an ultrasonic wave irradiation means for irradiating the liquid to be treated flowing in the flowing water pipe with an ultrasonic wave.   The water treatment apparatus according to claim 1, wherein another inlet for the oxidizing solution is provided in the flowing water line between the venturi pipe and the ultrasonic wave irradiation means.   The water treatment apparatus according to claim 1, wherein the inlet is an inlet for hydrogen peroxide water.   4. The water treatment apparatus according to claim 1, wherein a plurality of the venturi pipes and the ultrasonic wave irradiation units are alternately arranged in series. 5.

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