JP3773758B2 - Liquid processing method and apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention includes (1) biological aerobic or anaerobic treatment of organic waste liquid discharged from a sewage treatment process in a sewage treatment plant or a sewage treatment plant or a drainage process of a food factory or a chemical factory, (2 ) Sterilization / sterilization treatment, decolorization treatment, deodorization treatment of wastewater from each factory (including those other than organic wastewater), treated water, water and sewage water, food and drinking water in the process of producing clean pure water Or (3) Inappropriate decomposition of dioxins, environmental hormones, PCBs, etc., which occurs when sterilizing / sterilizing, decolorizing, and deodorizing the above-mentioned various liquids, or when leachate is leached from a garbage incinerator. The present invention relates to a liquid processing method applied to decomposition processing of substances and the like, and an apparatus used for carrying out such a processing method.
[0002]
[Prior art]
In the various uses shown in the above (1) to (3), for example, as a method of killing harmful bacteria contained in the liquid and cleaning the liquid, or the bacteria contained in the liquid and its In order to reduce the volume of fouling components such as carcasses, as a method for reforming the fouling components to a state in which aerobic microorganisms can be easily treated biochemically, high-voltage pulse discharge treatment and / or electric field is applied to the liquid. A so-called high voltage processing method for processing a liquid by applying a pulse is known. The present inventors have also proposed a technique such as that disclosed in Japanese Patent Application Laid-Open No. 11-253999 as such a high voltage processing method and apparatus therefor.
[0003]
FIG. 1 is a diagram schematically showing a configuration example of a high voltage processing apparatus previously proposed by the present inventors. In this apparatus, a target liquid (liquid to be processed) is an organic waste liquid, The case where the organic waste liquid is biologically aerobically treated is assumed.
[0004]
In the apparatus shown in FIG. 1, first, an organic waste liquid is introduced into an activated sludge tank (aeration tank) 1 through a path 7 and aerated while mixing the activated sludge in the activated sludge tank 1 and the organic waste liquid. There are aerobic microorganisms in the activated sludge, the organic pollutants in the organic waste liquid are decomposed into carbon dioxide and water by the aerobic microorganisms, and the organic pollutants are assimilated into microorganisms to activate the activated sludge. Grows.
[0005]
The treated mixed liquid is introduced into the precipitation device 2 from the path 8 and separated into a solid liquid 20 and a precipitated sludge 10, and the supernatant liquid 20 is discharged from the path 9 as treated water. The treated water is discharged after being subjected to a higher-order treatment (nitrification / denitrification treatment, ozone treatment, etc.) if necessary according to the discharge standard of the discharge destination.
[0006]
On the other hand, a part of the precipitated sludge 10 is returned from the return path 11 to the activated sludge tank 1 by the pump 16 to become a microorganism source in the activated sludge tank 1, and a part of the precipitated sludge 10 is pumped from the path 12 17 is introduced into the reforming tank 3 of the reformer 18. The reforming apparatus 18 includes a reforming tank 3 and a power source 4, and a rod electrode (+ electrode) 5 and a plate electrode (−electrode) 6 connected to the power source 4 are sludge in the reforming tank 3. It is arrange | positioned in parallel so that it may be immersed in. The sludge in the reforming tank 3 (precipitation sludge 10 introduced from the precipitation device 2) can be considered as a dielectric having a predetermined dielectric constant electrically. When a voltage is applied while positive and negative charges are transferred to the electrodes 5 and 6, respectively, an electric field is formed in the dielectric (sludge), and insulation is obtained when the strength of the electric field exceeds a certain level. Breaking occurs, and discharge occurs between the electrodes 5 and 6.
[0007]
By carrying out the high voltage pulse discharge treatment between the electrodes 5 and 6 as described above, the precipitated sludge is solubilized and reduced in molecular weight (modified). That is, microorganisms in the precipitated sludge are killed by the high voltage pulse discharge, and further decomposed by cell destruction to produce low molecular organic substances and inorganic substances, and organic substances other than microorganisms are also reduced in molecular weight. It becomes an easily decomposable substance (hereinafter sometimes referred to as modified sludge).
[0008]
In such a technique, the same effect can be obtained by applying electric field pulse application processing to sludge instead of performing high voltage pulse discharge processing. In other words, the discharge phenomenon does not occur when the applied voltage is set lower than the voltage at which sludge causes dielectric breakdown, or when the distance between the electrodes is large and the capacitance between the electrodes is large. If an electric field is formed between the electrodes by applying a voltage (so-called critical voltage) at which individual cells in the sludge are destroyed, the sludge is modified. Further, not only the high voltage pulse discharge process or the electric field pulse application process is performed alone, but also these processes can be performed in combination.
[0009]
Next, the modified sludge generated in the reformer 18 is returned to the activated sludge tank (aerobic treatment tank) 1 from the return path 13. In the activated sludge tank 1, aerobic microorganisms use the modified sludge as feed and decompose it.
[0010]
In this way, the sludge is reduced by high-voltage pulse discharge and / or electric field pulse application treatment and returned to the activated sludge tank 1 to circulate the sludge. As a result, the sludge is discharged as excess sludge. The amount to be reduced. This excess sludge is discharged out of the system via the path 15.
[0011]
[Problems to be solved by the invention]
Normally, when a high voltage is applied between electrodes immersed in a liquid, a corresponding high electric field is formed between the electrodes, and a so-called primary avalanche is formed by this high electric field. In this avalanche path of primary avalanche, some residual negative ions (negative ion group) are generated by the adhesion action of electrons and positive ions. The amount of charge in the liquid is a predetermined amount of space charge consisting of the sum of the residual negative ions and the charge that has been present, and the electric field in the liquid is between the electric field consisting of this space charge and the electrode in the first place. A combined electric field is formed by combining with an applied electric field of high voltage applied.
[0012]
When the synthetic electric field becomes sufficiently large, electrons generated by photoionization during the progress of primary avalanche grow as a secondary avalanche toward the center of gravity of the residual ion group. A thin plasma is formed by the primary avalanche and the secondary avalanche. This is a phenomenon called streamer (discharge).
[0013]
This streamer discharge is not always maintained in a stable state, and may change to another discharge state depending on circumstances. For example, a thin streamer discharge may change to another discharge form in which a positive column is formed between electrodes. Naturally, such a transition greatly depends on how the streamer discharge propagates between the electrodes.
[0014]
By the way, in the high voltage processing method as described above, the processing is generally performed in a state where the streamer discharge and the discharge of arc discharge other than the streamer which has changed after the streamer is generated are mixed. However, the processing efficiency in the modification treatment of the liquid to be processed under such circumstances is not always sufficient. In other words, in the case of discharge such as arc discharge, the modification of the liquid to be treated does not proceed sufficiently for a large amount of current to flow and consume a large amount of power, and the desired high voltage treatment effect cannot be obtained. There was a problem. In addition, when arc discharge or the like occurs, there has been a situation in which specific abnormal noise is generated.
[0015]
Therefore, the present invention has been made in view of the above-described actual situation, and an object of the present invention is to provide a liquid processing method that can sufficiently perform liquid reforming with a small amount of electric power and is highly efficient and economically advantageous. And to provide a useful device for carrying out such a method.
[0016]
[Means for Solving the Problems]
The liquid treatment method of the present invention that has achieved the above object is to provide at least one pair of electrodes, immerse at least one of the electrode pairs in a liquid, and form a pulse-like structure between the electrode pairs. In a liquid processing method for reforming a liquid existing between an electrode pair by supplying electric power to form a discharge state, the voltage or current of the supplied power is detected, and the streamer discharge is set to that value. When a decrease in voltage or an increase in current is observed when transitioning from arc to arc discharge, the power supply is stopped to prevent transition from streamer discharge to arc discharge or transition to arc discharge. It has a gist in that it operates in a manner that keeps it to a minimum.
[0017]
In addition, the liquid processing apparatus of the present invention that can achieve the above object includes at least one pair of electrodes, and is arranged so that at least one electrode of the electrode pair is immersed in a liquid. Detection that detects the voltage or current of the supplied power in a liquid processing apparatus that reforms the liquid existing between the electrode pair by supplying a pulsed power between the pair and forming a discharge state between the electrode pair. A voltage drop or an increase in current that occurs when transitioning from streamer discharge to arc discharge is detected in the value detected by the means, the switching means provided in the power supply path to the electrode pair, and the detection means. When it is recognized, the control means for controlling the switching means to stop the supply of the electric power is provided to prevent the transition from the streamer discharge to the arc discharge or the arc discharge. It is those having the gist transition to the point in which was constructed as to minimize the to.
[0020]
BEST MODE FOR CARRYING OUT THE INVENTION
In the present invention, by adopting the configuration as described above, it is possible to avoid performing high voltage processing in a state where discharges such as arc discharge other than streamers are mixed, and processing with high efficiency is possible. High voltage processing can be performed with a simple streamer discharge. In addition, it is possible to avoid the generation of unusual noise due to arc discharge or the like.
[0021]
FIG. 2 is an explanatory view schematically showing a state of discharge between the anode (anode) and the cathode (cathode). When the streamer discharge reaches the cathode, the streamer discharge changes to arc discharge. This change requires a predetermined minute time, and when a predetermined amount of fluctuation in voltage and current is observed within this time period. If the streamer discharge is stopped, it is possible to avoid a situation in which the streamer discharge and the discharge of the arc discharge other than the streamer that has transitioned after the occurrence of the streamer discharge are mixed, and the above-mentioned inconvenience occurs. Could be prevented. Alternatively, the inventors have also found that the same effect as described above can be achieved even if the discharge generated in the liquid to be treated when a high voltage is applied is maintained within a predetermined time for maintaining the streamer.
[0022]
As a result of experiments confirmed by the present inventors, it has been found that when ordinary distilled water or tap water is used as the liquid to be treated, the streamer discharge speed is about 30 mm / μsec. Further, according to this experiment, it was confirmed that the streamer propagates at a substantially constant speed without depending on the magnitude of the applied voltage, and the value becomes the above value. However, it was confirmed that there were some differences in the streamer discharge speed values for different types of liquids to be treated. However, the streamer discharge speed was almost constant without depending on the magnitude of the applied voltage. Therefore, the speed of the streamer discharge may be detected according to the type of the liquid to be treated.
[0023]
Hereinafter, the configuration and operational effects of the present invention will be described more specifically with reference to the drawings. However, the configurations shown below are not intended to limit the present invention, and design changes may be made in accordance with the gist of the preceding and following descriptions. Both are included in the technical scope of the present invention.
[0024]
FIG. 3 is an explanatory view schematically showing one configuration example of the apparatus according to the present invention, in which 25 is a high voltage power supply, 26 is a high voltage switch unit, 27 is a processing vessel, 28 is a voltage detection unit, Reference numeral 29 denotes discharge. The high voltage power supply 25 can apply a voltage of several tens of kV or more (preferably about 70 kV). Although the high voltage switch unit 26 has a mechanical switch configuration in FIG. 3, this high voltage switch unit 26 uses switching means capable of high repetitive operation such as a thyratron or a magnetic switch. Thus, the voltage from the high voltage power supply 25 can be pulsed. Further, at this time, by adopting the switching means, application of a high voltage exceeding a certain value for a predetermined time or more is not allowed.
[0025]
The processing vessel 27 corresponds to the reforming tank 3 of FIG. 1 and the pulsed (usually rectangular wave) high voltage is supplied to the processing vessel 27. The processing container 27 is supplied with a liquid to be processed (not shown) and is processed by the supplied high voltage pulse and / or high electric field pulse (discharge 29). Further, the voltage detector 28 detects a potential difference (voltage) in the processing container 27 (load side).
[0026]
In the apparatus shown in FIG. 3, the processing container 27 is provided with a pair of electrodes. However, the number of electrode pairs may be two or more. Further, the immersion state of the electrode in the liquid in this apparatus is usually a state where both the anode electrode and the cathode electrode are immersed, but the discharge as described above is performed when at least one of the electrodes is immersed. A state is achieved.
[0027]
In the apparatus configuration shown in FIG. 3, the voltage applied to the processing container 27 (that is, the voltage applied to the liquid to be processed) is detected by the voltage detector 28, and the value fluctuates by a predetermined amount or more per minute time. If this is recognized, it will show a sign that the streamer discharge changes (or shifts) to arc discharge. In the middle of the transition to the arc discharge, by controlling the high voltage switch unit 26 to the “open” state, the power of the power source can be reduced, and the transition from the streamer discharge to the arc discharge is stopped. Transition can be kept to a minimum.
[0028]
In other words, streamer discharge maintains discharge with a high voltage, and arc discharge maintains discharge with low voltage and high current. The voltage between the cathodes will drop rapidly. Then, by detecting this voltage drop (for example, about 1 kV or more) and turning off the discharge energy by setting the high voltage switch unit 26 to the “open” state, the transition from streamer discharge to arc discharge is made. It is possible to prevent the occurrence of a state in which streamer discharge and arc discharge coexist. Further, by adopting such a configuration, it is possible to sufficiently modify the liquid to be treated with a small amount of electric power, which is highly efficient and economically advantageous. The “minute time” means from several n (nano) seconds to 1 μ (micro) seconds.
[0029]
In the above configuration, the high voltage switch unit 26 has also been configured to perform high voltage pulse shaping. However, a pulse forming line (PFL) such as a blue line path is connected to the high voltage power supply 25 (described later). 5) The structure incorporated in the high voltage power supply 25 may be sufficient, and even if such a structure is employ | adopted, a pulse voltage can be applied to the processing container 27. FIG. When such a configuration is adopted, the high voltage switch unit 26 may be a normal mechanical switch.
[0030]
FIG. 4 is an explanatory view schematically showing another configuration example of the device according to the present invention. In this device, except that a current detection unit 30 is provided instead of the voltage detection unit 28 in FIG. The configuration is the same as that shown in FIG. 3, and overlapping is avoided by attaching the same reference numerals to corresponding portions. Therefore, the principle of pulse formation and the mechanism of the high voltage switch unit 26 in the apparatus shown in FIG. 4 are the same as described above.
[0031]
In the apparatus configuration shown in FIG. 4, the current applied to the processing container 27 (that is, the current applied to the liquid to be processed) is detected by the current detection unit 30, and the value fluctuates by a predetermined amount or more per minute time. In such a case, the transition from the streamer discharge to the arc discharge can be stopped or the transition can be minimized by setting the high voltage switch unit 26 to the “open” state.
[0032]
That is, as described above, the current during the streamer discharge is small and the arc discharge is maintained in a state where the current is large. Therefore, when the streamer discharge is changed to the arc discharge, the current flowing through the processing container 27 increases rapidly. It will be. Then, by detecting this increase in current (for example, about 100 to 1000 A or more) and turning off the energy of the discharge 29 with the high voltage switch unit 26 in the “open” state, the transition from streamer discharge to arc discharge is made. It is possible to prevent the occurrence of a state in which streamer discharge and arc discharge are mixed, and to prevent the occurrence of this phenomenon or to minimize the transition to arc discharge.
[0033]
FIG. 5 is an explanatory view schematically showing still another configuration example of the device according to the present invention. In this device, the voltage pulse shaping unit 31 is indispensable in a state including the high voltage switch unit 26a. It is configured as. The pulse shaping unit 31 is, for example, a PFL as described above, but preferably has a Bloom line path.
[0034]
When the pulse forming unit 31 is formed on the Bloom line path, if the voltage of the high voltage power supply 25 is V ₀ , the length of the transmission line is L, and the propagation speed of the voltage wave is v, the wave height V ₀ is on the load side. A rectangular wave pulse having a pulse length of 2 L / v (FIG. 6) will be supplied (for example, “High Voltage Pulse Power Optics”, Morikita Publishing, page 171). In the present invention, the voltage pulse length is set to a predetermined time or less so that the discharge generated in the liquid when the voltage is applied to the liquid to be treated maintains the streamer.
[0035]
In order for the discharge to maintain the streamer, first, the streamer is generated from one electrode, and the applied voltage is stopped before reaching the other electrode. Therefore, if the length between the electrodes is R, and the propagation speed of the streamer discharge is v ′ (depends on the type of liquid and does not depend on the applied voltage), the pulse shaping portion is set so as to satisfy the following formula (1). What is necessary is just to comprise.
(2L / v) <(R / v ′) (1)
[0036]
If a variable capacitor and a variable inductance are provided in the Bloom line, the value of v can be changed as appropriate, and the pulse length can be adjusted so as to satisfy the expression (1). In the above description, the case where the voltage pulse length is adjusted has been described, but it is needless to say that the pulse length caused by the current may be adjusted in exactly the same manner.
[0037]
As described above, the pulse shaping unit 31 as pulse length adjusting means is added to the output side of the high voltage power supply 25 to adjust the pulse length, and the pulse length is set so as to satisfy the above expression (1). Thus, the transition from the streamer discharge before the transition to the arc discharge to the arc discharge can be prevented or the transition to the arc discharge can be minimized, and the occurrence of the mixed state of the streamer discharge and the arc discharge can be avoided.
[0038]
In setting the pulse length to a predetermined time or less, the time may be obtained from the discharge distance between the anode (anode) and the cathode (cathode). For example, assuming that the streamer discharge speed is about 30 mm / μsec as described above and the discharge distance between the anode (anode) and the cathode (cathode) is 30 mm, the pulse length is about 1 μsec.
[0039]
【The invention's effect】
The present invention is configured as described above. The liquid can be sufficiently reformed with a small amount of electric power, and a liquid processing method that is highly efficient and economically advantageous, and for implementing such a method. A useful device was realized.
[Brief description of the drawings]
FIG. 1 is a diagram schematically showing an apparatus configuration example for implementing a high voltage processing method.
FIG. 2 is an explanatory view schematically showing a state of discharge between an anode and a cathode.
FIG. 3 is an explanatory view schematically showing a configuration example of an apparatus according to the present invention.
FIG. 4 is an explanatory view schematically showing another configuration example of the apparatus according to the present invention.
FIG. 5 is an explanatory view schematically showing still another configuration example of the apparatus according to the present invention.
FIG. 6 is an explanatory diagram showing an example of an output voltage waveform of a rectangular wave pulse.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Activated sludge tank 2 Precipitation apparatus 3 Reformer tank 4 Power supply 5 Rod electrode 6 Flat plate electrode 7, 8, 9, 12, 15, 21 Path 10 Precipitated sludge 11, 13, 22 Return path 16, 17, 19 Pump 18 Reformation Apparatus 20 Supernatant 25 High voltage power supply 26 High voltage switch unit 27 Processing vessel 28 Voltage detection unit 29 Discharge 30 Current detection unit

Claims (2)

Providing at least one pair of electrodes, immersing at least one of the electrode pairs in a liquid and supplying a pulsed power between the electrode pairs to form a discharge state between the electrode pairs; In the liquid treatment method for modifying the liquid existing between the electrode pairs, the voltage or current of the supplied power is detected, and the voltage drop or current increase generated when transitioning from streamer discharge to arc discharge is detected. when are observed, stop the supply of the electric power, the liquid processing method characterized by operating in the manner to minimize the transition to prevent or arcing to transition from streamer discharge to arc discharge . At least one pair of electrodes, and at least one electrode of the pair of electrodes is arranged to be immersed in a liquid, and a pulsed power is supplied between the pair of electrodes so that a discharge state is generated between the pair of electrodes. In the liquid processing apparatus for reforming the liquid existing between the electrode pair by forming, a detecting means for detecting the voltage or current of the supplied power and switching provided in the power supply path to the electrode pair And the value detected by the detection means, when a decrease in voltage or increase in current that occurs when transitioning from streamer discharge to arc discharge is recognized, the switching means is controlled to supply the power. a control means for stopping, that the transition to prevent or arcing to transition from streamer discharge to the arc discharge is obtained by construction as to minimize Liquid treatment apparatus according to claim.

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