JP2004317350A - Living matter sludge monitoring device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a living matter sludge monitoring device capable of measuring and monitoring automatically and continuously the existence state of the living matter sludge in a water purification device using the living matter sludge. <P>SOLUTION: This device comprises a sensor for outputting a detection signal corresponding to the concentration of living matter sludge slurry in water to be measured stirred uniformly, an operation means for acquiring at least one data of a means for determining average data determined by averaging the level of the detection signal outputted from the sensor at prescribed time intervals, a means for determining amplification data shown by the difference between the maximum value and the minimum value of the detection signal, a means for determining signal data of an envelope acquired by taking out the envelope of the detection signal, and a means for determining the amplification data of the signal of the envelope shown by the difference between the maximum value and the minimum value of the signal of the envelope, and a determination part for determining the state of the living matter sludge in the water to be measured from the data determined by the operation means. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to industrial wastewater discharged from various factories, research facilities, power generation facilities, dairy farming, amusement facilities, etc., medical facilities such as buildings, general households, accommodation facilities, hospitals, restaurants, educational facilities such as schools, etc. The present invention relates to a biological sludge monitoring device for a water purification device using biological sludge which is installed for the purpose of purifying domestic wastewater discharged from exercise facilities and the like.
[0002]
[Prior art]
BACKGROUND ART A water purification device using biological sludge has been installed for the purpose of purifying various types of industrial wastewater or domestic wastewater and has been widely applied. In order to operate this water purification device stably, it is necessary to grasp the state of the biological sludge and maintain it. The detection of the average particle size of bio-sludge, the uniformity of sludge particle size, and the variation in particle size of this type of water purification device is performed by collecting the bio-sludge manually and then observing the bio-sludge using a microscope. Has been done.
[0003]
A turbidity meter that displays MLSS (solid matter dry weight concentration) is known as an index indicating the concentration of biological sludge in such a water purification device (for example, see Patent Document 1). This turbidimeter is a measuring device utilizing the fact that the light irradiated into the test water causes scattered reflection by the suspended matter contained in the test water, and measures the amount of the scattered light, and the light amount is measured in advance. The turbidity of the sample is measured and displayed by comparing the set light quantity-concentration.
[0004]
Further, as a device for optically detecting the concentration of a suspended substance suspended in a solvent, an optical suspended substance concentration measuring device is known (for example, see Patent Document 2). This device captures, with a light receiver, light that irradiates into the test water and transmits or scatters the suspended matter contained in the test water, and uses the amount of received light and a predetermined amount of received light-concentration to obtain the underwater Is used to measure and display the concentration of suspended solids.
[0005]
[Patent Document 1]
Japanese Utility Model Publication No. 1-363535
[Patent Document 2]
JP-A-54-63891
[0006]
[Problems to be solved by the invention]
By the way, instead of manually observing biological sludge using a microscope, for example, a method of taking in an image of biological sludge and performing an automatic analysis can be considered. However, for automatic analysis, the sludge must be distributed at appropriate intervals on the image. In order to observe changes over time, the measurement environment must be the same, and the sample concentration must be kept constant.However, since the actual concentration of biological sludge slurry always changes, There is a problem that it is difficult to perform the operation automatically and it is difficult to obtain a correct measurement result. Further, the particle size and shape of the biological sludge and its color tone change every moment, so it is difficult to narrow down the analysis pattern of the biological sludge and perform an automatic analysis. For this reason, there has been a problem that the observation of the state of biological sludge using images must ultimately be performed by analysis by a measurer. For this reason, for example, even if the state of the biological sludge becomes abnormal at night or on a holiday when the observer who observes the state of the biological sludge is absent, there is a problem that it is not possible to respond.
[0007]
In addition, the temporal change of the biological sludge is small, and it is difficult for even a skilled measurer to visually recognize the change from several hours to several days, and even more quantitatively represents the change. It was even more difficult. Therefore, it can be said that observation of sludge change by image analysis is practically impossible.
Furthermore, in the turbidity meter described above, the concentration of the suspended matter contained in the test water is measured, but the average particle diameter of the biological sludge, the uniformity or variation in the particle diameter of the biological sludge, the biological sludge In addition to not being able to obtain information on changes in the existing state of biological sludge, such as clarity (clarity of supernatant water obtained by allowing biological sludge to stand still), if such a change occurs, the amount of received light There is also a problem that the relationship of the concentration will also change, and therefore it is not possible to display an accurate value.
[0008]
For this reason, the state of the biological sludge cannot be grasped only by using the index by the conventional turbidity measurement method, and it has been difficult to operate the water purification device stably.
The present invention has been made in view of such circumstances, and an object of the present invention is to automatically and continuously measure and monitor the existing state of biological sludge and its change in a water purification apparatus using biological sludge. It is to provide a biological sludge monitoring device.
[0009]
[Means for Solving the Problems]
In order to solve the above-described problems, the present inventors have focused on a change in a detection signal detected by a sensor inserted into the measured water when the presence state of the biological sludge in the measured water is variously changed. Therefore, when light is irradiated on the water to be measured, the presence of biological sludge is detected using an optical sensor that detects and outputs scattered light generated by collision of the light with sludge particles in the water to be measured as a change in the amount of light. The condition was measured.
[0010]
First, the present inventor examined the relationship between the average value of the signal level output from the optical sensor and the biological sludge concentration. The water to be measured used at this time was a solution obtained by using a biological sludge slurry having an MLSS concentration of [12000 mg / L] as a stock solution and diluting this stock solution with city water at an appropriate magnification. Then, the solution was placed in a glass beaker having a capacity of [1000 mL], uniformly stirred, and then an optical sensor was inserted into the solution to perform measurement. The MLSS concentration of the solution was measured according to the method for measuring suspended substances specified in JIS-K-0102-14.1.
[0011]
As a result, as shown in FIG. 1, the concentration of biological sludge (MLSS concentration) increased.
Therefore, it was found that the signal level output from the optical sensor increased in proportion. This phenomenon is caused by an increase in the amount of biological sludge per unit volume, that is, when the concentration of biological sludge increases, the amount of biological sludge in the path of light irradiated by the optical sensor on the water to be measured increases. It is considered that the amount of light scattered and reaches the light receiving portion of the optical sensor is increased. Scientifically, this phenomenon has been demonstrated by Lambert-Beer's law. Focusing on this event, it is possible to determine an increase or decrease in the biological sludge concentration by detecting an increase or decrease in the signal level output by the optical sensor. That is, by continuously monitoring the signal level detected by the optical sensor, a change in the amount of biological sludge present in the water purification device can be detected. Therefore, by performing calibration using a sludge slurry having a known MLSS concentration in advance, the concentration of biological sludge can be monitored. These are the same as the principles of a conventional turbidimeter or MLSS meter.
[0012]
By the way, when the particle size of the biological sludge is uniform and the biological sludge is uniformly present in the slurry, the amplitude value indicated by the difference between the maximum value and the minimum value of the detection signal output from the optical sensor. Was found to exhibit a substantially constant value. However, it is known that particles in the natural world generally show a normal distribution (Gaussian distribution). For this reason, it is considered that the particle size distribution of the biological sludge in the water purification device also shows a Gaussian distribution in a theoretical state.
[0013]
However, when the water to be measured is uniformly stirred, especially when there is no standing for a long time, forced sedimentation in the gravitational field, classification to give the initial velocity, etc., the particle size distribution is uniform. In a uniform state. In such a uniform state, when biological sludge having a large particle size exists within the detection range of the optical sensor, the projected area thereof is large, so that the probability that light scattered by the biological sludge reaches the detection unit of the optical sensor is increased. Will be higher. Then, as described above, the output level of the detection signal of the optical sensor increases. On the other hand, when biological sludge having a small particle size exists in the detection range, the probability that light scattered by the biological sludge reaches the detection unit of the optical sensor decreases. Then, the output level of the detection signal of the optical sensor decreases.
[0014]
Focusing on such a phenomenon, for example, by detecting the amplitude value indicated by the difference between the maximum value and the minimum value of the output level of the detection signal of the optical sensor, it is possible to obtain information on the variation in the sludge particle diameter. Become. That is, by monitoring the amplitude value of the level of the detection signal output from the optical sensor, it is possible to detect a change in the state related to the particle diameter of the biological sludge in the water purification device.
[0015]
Therefore, the inventor conducted an evaluation test to confirm the detectability of the change state of the biological sludge based on such knowledge. In addition, this evaluation test was performed using the same measurement system as the above-mentioned MLSS concentration.
First, a biological sludge slurry having an MLSS concentration of [3500 mg / L] was prepared as a stock solution. Then, after the stock solution was uniformly stirred, it was placed in a dark place, and the waveform of a detection signal output from an optical sensor inserted into the stock solution was observed. As a result, a waveform in which the maximum value and the minimum value appeared randomly as shown in FIG. 2A could be observed. This is nothing but the distribution of the particle diameter of the biological sludge in the water purification apparatus having a Gaussian distribution as described above.
[0016]
Next, a homogenizer is used to pulverize the particles contained in the stock solution to create a homogenized solution, and when the optical sensor is inserted into this solution, the waveform of the detection signal output from the optical sensor Was observed. As shown in FIG. 2B, this waveform was found to have an amplitude value indicated by a difference between the maximum value and the minimum value of the detection signal of the optical sensor smaller than that of the undiluted solution, as shown in FIG. However, there was hardly any difference in the average signal level output from the sensor between the undiluted solution and the homogenized solution of the undiluted solution. This phenomenon is because the homogenization eliminated large particles but increased small particles.
[0017]
Next, a solution was prepared by further filtering the homogenized solution through a [30 mesh] sieve, and when an optical sensor was inserted into the solution, the waveform of a detection signal output from the optical sensor was observed. In the case of this solution, the waveform of the detection signal output from the optical sensor has a maximum signal waveform as shown in FIG. 2 (c) when compared with the waveform of the detection signal when measuring the undiluted solution [FIG. 2 (a)]. The result was that the amplitude value indicated by the difference between the value and the minimum value became smaller. When the average level of the signal waveform output from the sensor is compared with the undiluted solution [FIG. 2 (a)] or the homogenized solution [FIG. 2 (b)], the average level of the signal waveform output from the sensor is lower. The result was also obtained.
[0018]
As described above, in a solution obtained by homogenizing a solution containing biological sludge (stock solution) or a solution obtained by further homogenizing the solution, the stock solution is contained in the stock solution by homogenizing or filtering the stock solution. Large particle diameter sludge will be removed. For this reason, the particle diameters present in the sludge slurry are substantially uniform. Therefore, it is considered that the amplitude value indicated by the difference between the maximum value and the minimum value of the detection signal output from the optical sensor decreases. For this reason, if the change in the amplitude value indicated by the difference between the maximum value and the minimum value of the detection signal output from the sensor is monitored, it is possible to detect the variation in the particle diameter of the biological sludge. That is, it is possible to detect an abnormality of the biological sludge by monitoring a change in the amplitude value of the detection signal of the sensor over time.
[0019]
Further, as described above, when the particle size of the biological sludge is uniform and the biological sludge is uniformly present in the slurry, even if the particle size of the biological sludge varies, Density is uniform. That is, the relative projected areas formed by the biological sludge particles existing on the optical path are substantially the same. Therefore, the average value of the detection signal output from the sensor does not change. However, when abnormalities occur in biological sludge, the interparticle density may become non-uniform. In this case, the signal waveform output from the sensor is disturbed. Therefore, the average value of the signal level output from the sensor fluctuates. Therefore, it is possible to detect that the density between sludge particles is non-uniform by detecting the disturbance of the average value of the signal level output from the sensor. That is, it can be determined that an abnormality such as bulking has occurred in the biological sludge.
[0020]
Based on such knowledge, the inventor conducted an evaluation test to confirm the detectability of the change state of the biological sludge. In addition, this evaluation test was performed using the same measurement system as the above-mentioned MLSS concentration. However, the biological sludge used in the evaluation test described above was mixed with biological sludge in which filamentous bacteria (Sphaerotilus natans) were generated, and the bulking sludge abundance was set to [0%], [30%], [60%] and [100%]. ] And a sludge slurry whose MLSS concentration was adjusted to [3500 mg / L].
[0021]
In this case, as shown in FIG. 3, as the bulking sludge abundance ratio of the sludge slurry increases, the disturbance of the detection signal level with respect to the average level of the detection signal of the sensor increases. By focusing on such a phenomenon, by monitoring the disturbance of the average value of the detection signal output from the sensor over time, the state of the biological sludge until the filamentous bacteria multiply and reaches bulking, that is, The degree of progress of bulking can be detected.
[0022]
Further, the amplitude of a signal (hereinafter referred to as an envelope signal) obtained by extracting an envelope (minimum peak value of the signal amplitude) of the signal detected by the sensor is closely related to the clarity of the measured water. . Specifically, when the water to be measured is pure water, the signal level of the envelope is minimum, and the amplitude value of the signal of the envelope indicated by the difference between the maximum value and the minimum value of the signal level of the envelope is also It was found to be minimal. This is thought to be because the level and amplitude of the signal of the envelope decreases as the amount of suspended solids present in the sludge slurry decreases. Focusing on this phenomenon, by monitoring the average level of the envelope signal and its amplitude value, it is possible to determine the clarity of the biological sludge slurry and the occurrence of abnormalities in the biological sludge slurry, for example, the presence or absence of sludge floc dismantling. Becomes possible.
[0023]
Based on such knowledge, the inventor conducted an evaluation test to confirm the detectability of the change state of the biological sludge. Note that this evaluation test was performed using the same system as the measurement system used in the above-described MLSS concentration evaluation test.
A solution obtained by adding kaolin (white clay) turbidity as a suspended substance to the stock solution containing the biological sludge described above and a sludge floc to simulate the dismantling of the stock solution, and ultrasonic pulverization that was previously irradiated with ultrasonic waves and decomposed A solution obtained by adding sludge to a stock solution was prepared. The raw water and the solution were prepared by adjusting the MLSS concentration calculated using the sludge of the raw liquid as a reference value to be [3500 mg / L], and adding the respective turbidities thereto. is there.
[0024]
Then, when the above-described optical sensor is inserted into these solutions, the waveform of the detection signal output by the sensor, the signal level of the envelope from which the envelope of the detected waveform is extracted, and the maximum value of the signal of the envelope And the amplitude value indicated by the difference from the minimum. As a result, as shown in FIG. 4, no difference was found in the signal level for any of the solutions. (Note that FIG. 4 shows the detection signal and the envelope signal on the same sheet with different scales for easy viewing.) This is obvious because the MLSS concentrations are equal. However, based on the signal level of the envelope of the undiluted solution, a solution in which kaolin (white clay) turbidity was added as a suspended substance to the undiluted solution [FIG. 4 (b)], and decomposed by previously irradiating ultrasonic waves There was a tendency that the level of the signal of the envelope of the solution [FIG. 4 (c)] obtained by adding the ultrasonic pulverized sludge to the stock solution was increased. Further, the amplitude value indicated by the difference between the maximum value and the minimum value of the signal of the envelope is also based on the amplitude value of the stock solution, and a solution obtained by adding kaolin (white clay) turbidity as a suspended substance to the stock solution [ 4 (b)] and a solution [FIG. 4 (c)] obtained by adding ultrasonically pulverized sludge decomposed by irradiating ultrasonic waves to a stock solution was observed to be larger.
[0025]
When kaolin turbidity is added, the turbidity increases and the envelope signal increases, but the amplitude value of the envelope signal is a constant change due to the uniform fine particle diameter. The signal level of the envelope varies between the solution containing kaolin turbidity and the solution containing fine particles obtained by crushing sludge with ultrasonic waves decomposed by ultrasonic irradiation beforehand, because the particle diameters are not uniform. The result was.
[0026]
For this reason, it was possible to determine the cleanliness of the sludge slurry by monitoring the level of the envelope signal from which the envelope of the signal detected by the sensor was extracted and the amplitude value thereof. Furthermore, the dismantling of sludge flocs of biological sludge could be detected.
When the above-described optical sensor is used, light of a specific wavelength emitted from the sensor may be absorbed depending on the color tone of the biological sludge. For example, if a change in the amount of light when different wavelengths of light are applied to the biological sludge is detected for each wavelength, it is possible to monitor a change in the color tone of the biological sludge from the difference in the absorption wavelength.
[0027]
Therefore, the present inventor, when inserting a sensor that irradiates light of different wavelengths into a solution containing various reagents mixed in a solution containing biological sludge, observes the level of a detection signal output by the sensor and changes the sludge color tone. An evaluation test was conducted to confirm the detectability of the compound. In this evaluation test, a stock solution containing the above-mentioned biological sludge was added to the stock solution, and the stock solution was reddish and ferric tetroxide (Fe ₃ O ₄ ) Were used. The MLSS concentrations of these solutions were prepared by previously adjusting the concentration of the stock solution to [3500 mg / L], and adding the respective reagents to this solution.
[0028]
Then, when the above-described optical sensor is inserted into these solutions and the wavelength of the output light of the sensor irradiating the solution is changed to [630 nm] and [450 nm], it is obtained from the detection signal of the sensor. The MLSS concentration was measured (FIG. 5). In addition, about this evaluation test, MLSS concentration analysis by hand was also performed.
First, in the case of undiluted sludge, since the MLSS concentration was previously adjusted to [3500 mg / L], both the case where the wavelength of the sensor was changed and the analysis by hand showed the same value as [3500 mg / L] [ FIG. 5 (a)]. Next, regarding the solution obtained by adding food red to the undiluted solution, in the sensor using the light of [450 nm], the detection signal of the sensor did not change, but in the sensor using the light of [630 nm]. Was able to detect a decrease in the MLSS concentration represented by the sensor output [FIG. 5 (b)]. This is presumably because light of [630 nm] caused absorption or light emission in the solution to which the red food was added.
[0029]
In addition, ferrous tetroxide (Fe ₃ O ₄ ), A decrease in the MLSS concentration could be detected for both the light of [450 nm] and the light of [630 nm] [FIG. 5 (c)]. This is because the sensor irradiates the light into the solution with ferric tetroxide (Fe ₃ O ₄ ) Was probably absorbed.
Based on such knowledge, in order to achieve the above-mentioned object, the biological sludge monitoring device according to claim 1 of the present invention comprises:
A sensor for outputting a detection signal corresponding to the concentration of the biologically-sludge slurry of the water to be measured uniformly stirred,
(A) means for obtaining average data obtained by averaging the levels of the detection signals output by the sensor at predetermined time intervals;
(B) means for obtaining amplitude data indicated by a difference between a maximum value and a minimum value of the detection signal;
(C) means for obtaining a minimum peak value (envelope signal) of the amplitude of the detection signal;
(D) Means for obtaining amplitude data of a signal indicated by a difference between a maximum value and a minimum value of data according to a time change of the minimum peak value (envelope signal).
Calculating means for obtaining at least one data of
A determination unit for determining a state of the biological sludge of the water to be measured from the data obtained by the calculation means.
[0030]
For this reason, as described in claim 2, when the average data obtained by averaging the level of the detection signal output by the sensor at predetermined time intervals repeats a temporal change, the determination unit determines the biological sludge slurry. It can be determined that bulking has occurred.
Further, as set forth in claim 3, the determination unit in the biological sludge monitoring apparatus according to the present invention is configured such that the amplitude data indicated by the difference between the maximum value and the minimum value of the detection signal output by the sensor is a predetermined value. When it exceeds or when it is less than a predetermined value, it can be determined that there is a variation in the sludge particle diameter in the biological sludge slurry.
[0031]
Alternatively, as set forth in claim 4, the determination unit determines a minimum peak value (envelope signal) of the amplitude of the detection signal output by the sensor and a time of the minimum peak value (envelope signal). The clarity of the biological sludge slurry can be determined from the amplitude data of the signal indicated by the difference between the maximum value and the minimum value of the data accompanying the change.
The sensor described above irradiates light to the water to be measured as described in claim 5, and the light is transmitted through the sludge particles in the water to be measured and / or the light in the water to be measured in the water to be measured. It is configured as an optical sensor that detects scattered light generated by collision with sludge particles (optical method).
[0032]
In addition, the sensor irradiates ultrasonic waves to the water to be measured as described in claim 6, and generates reflected scattered sound and reflected transmitted sound generated by collision of the ultrasonic waves with sludge particles in the measured water. It may be configured as an ultrasonic sensor for detection (ultrasonic method).
Alternatively, the sensor includes a microwave sensor that irradiates the measured water with a microwave and detects an electromagnetic wave of the microwave transmitted between sludge particles in the measured water. (Microwave method).
[0033]
Preferably, the sensor irradiates the water to be measured with two different wavelengths of light as described in claim 8, and each light transmits between sludge particles in the measurement water and / or It is desirable to detect scattered light generated by the light colliding with the sludge particles in the measurement water (optical method).
It should be noted that one of the above-described various methods may be selected and configured according to various conditions such as the type and state of the water to be measured and the site to which the sensor is applied.
[0034]
More preferably, it is desirable to determine the state of the biological sludge based on the detected data by variously combining the above-described methods.
Therefore, according to the present invention, it is possible to provide a biological sludge monitoring device capable of automatically and continuously measuring and monitoring the presence state of biological sludge in a water purification apparatus using biological sludge.
[0035]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a biological sludge monitoring device according to the present invention will be described with reference to the drawings. This biological sludge monitoring device is suitable for monitoring biological sludge in an aeration tank used for a sewage water purification device, for example.
FIG. 6 is a schematic configuration diagram illustrating an example of a sewage treatment facility. FIG. 6 shows a part of the embodiment of the present invention, and the scope of the present invention is not limited by FIG.
[0036]
The sewage treated in the sewage treatment facility flows into the first sedimentation tank 1 of the sewage treatment facility through a sewage pipe (not shown) or the like. The first sedimentation tank 1 sediments solids and sludge contained in sewage flowing into a sewage treatment facility. Then, the supernatant water in which the sludge contained in the sewage flowing into the first sedimentation tank is settled is sent to the aeration tank 2 which is decomposed using microorganisms. The aeration tank 2 is blown from the bottom thereof by an air pump (not shown) to supply oxygen or air to the microorganisms, and to mix the water to be treated (sewage) and the microorganisms in the tank with the water to be treated (sewage). The organic matter contained in is decomposed. Then, the treated water in which the microorganisms and organic substances have been decomposed is sent to the second sedimentation tank 3 for sedimenting the sludge contained in the treated water.
[0037]
The sludge settled in the second settling tank 3 is an activated sludge slurry containing microorganisms. This activated sludge slurry is returned to the aeration tank 2 and the microorganisms contained in the sludge are reused (returned sludge). The aeration tank 2 is provided with a sensor 10 for detecting a state of biological sludge as described later.
On the other hand, the treated water from which sludge has been removed in the second settling tank 3 is sent to a chlorine mixing tank 4 for killing various bacteria in the treated water. The chlorine mixing tank 4 has a role of killing various bacteria in the treated water by utilizing the sterilizing action of chlorine. As a method of disinfecting the treated water, chlorine disinfection using chlorine is most often used, but other various disinfection methods such as bromine, ozone, and ultraviolet disinfection may be applied.
[0038]
Further, the excess sludge from which a part of the activated sludge slurry precipitated in the first sedimentation tank 1 and the second sedimentation tank 3 of the sewage treatment facility is extracted is treated by the sludge treatment facility 5. The sludge treatment facility 5 is provided with, for example, a sludge concentration tank (not shown) for condensing sludge. This sludge thickening tank can be gravity concentrated using the specific gravity of sludge a little heavier than water, or centrifugal concentrated using centrifugal force as in the dehydrator of a washing machine, or sludge with one or more filter cloths in between. Pressing and dewatering by applying pressure to the water, or flotation and concentrating, in which air bubbles and sludge are combined with a chemical to raise sludge.
[0039]
The feature of the biological sludge monitoring device according to the present invention configured as described above is that the state of the biological sludge is continuously determined based on the detection data detected by the optical sensor 10.
Specifically, as shown in FIG. 7, the activated sludge state determination means of the biological sludge monitoring device according to the present invention converts the modulated laser light output from the light emitting unit 20, for example, the laser light L amplitude-modulated at a predetermined frequency. When the measurement target water S is irradiated, the laser beam L is provided with a light receiving unit 31 that receives the transmitted light transmitted between the sludge particles in the measurement target water S. The modulated laser light output from the light emitting unit 20 electrically connects the laser diode 22 driven by the laser diode driving circuit 21 to the laser light L having a wavelength of [630 nm] at [70 to 150 kHz] (eg, 95 kHz). It is driven and output by an amplitude modulator 23 such as a function generator that performs amplitude modulation (AM modulation). When light having a large projected area with respect to the particle diameter of biological sludge is irradiated into the water S to be measured, it becomes difficult to detect a waveform change in the light receiving unit 31 (deterioration of S / N ratio). For this reason, the projected area of the light beam irradiated into the measured water S is preferably [1 cm ² ] Is desirably narrowed down to about or less. Specifically, a configuration may be used in which the light beam output from the laser diode 22 is narrowed using a lens or the like.
[0040]
On the other hand, the transmitted light received by the light receiving unit 31 is provided to the photoelectric converter 33 of the detection unit 30 via the optical fiber 32. The photoelectric converter 33 has a role of converting an electric signal according to the amount of light received by the light receiving unit 31. The detection unit 30 includes a band-pass filter (BPF) 34 that extracts only a signal of an amplitude-modulated frequency component contained in the modulated laser light from the electric signal output from the photoelectric converter 33, A detector 36 for detecting the amplitude modulation frequency component F obtained by amplifying the output signal via the amplifier 35 and obtaining an envelope component E thereof is provided. The amplitude modulation applied to the laser light has a role of modulating the laser light L onto the water S to be measured to distinguish it from extraneous light such as natural light mixed into the water S to be measured. The amplitude modulation frequency component F and its envelope component E are provided to the signal processing unit 37, and the state of the biological sludge is determined as described later.
[0041]
Although not shown, the treated water in the aeration tank 2 is supplied with air from substantially the bottom of the aeration tank 2 (air blow), and the water to be treated and the microorganism flocs are stirred together with the air. Therefore, when the concentration of the measured water S is detected using the above-described optical sensor, if air enters between the light emitting unit 20 and the light receiving unit 31, it is detected as if the sludge concentration was low. For this reason, a detection error occurs. Therefore, when detecting the biological sludge in the aeration tank 2, it is necessary to temporarily suspend the air sent into the aeration tank 2 by air blow.
[0042]
Alternatively, although not shown, a cylindrical outer periphery surrounding the optical sensor 10 is provided, and its bottom is opened to take in only the water to be measured into the detection site of the sensor and prevent air from being blown by the air blow. It may be configured as follows.
When the detection method using transmitted light shown in FIG. 7 is applied to the biological sludge monitoring device thus configured, the state determination of the biological sludge performed by the signal processing unit 37 will be described with reference to a flowchart shown in FIG. .
[0043]
First, when the laser light L amplitude-modulated by the predetermined frequency output from the laser diode 22 of the light emitting unit 20 passes between the sludge particles in the water S to be measured, the laser light L is irradiated and scattered by the sludge particles. After detecting the transmitted light (laser light L) transmitted between the sludge particles, the detection unit 30 converts the transmitted light into an electric signal via the photoelectric converter 33 in accordance with the amount of transmitted light, and then switches the band-pass filter 34. Demodulation (AM detection), the light-emitting unit 20 obtains an envelope component (light-receiving signal) E of a frequency component signal F amplitude-modulated.
[0044]
The average level of the light receiving signal E indicates the MLSS concentration of the measured water S as described above. That is, the decrease in the average level means that the amount of biological sludge in the measured water S, that is, the concentration of the biological sludge increases, and the amount of light (the amount of transmitted light) transmitted between the sludge particles present in the measured water S. Indicates a decrease. Therefore, by monitoring the average level of the received light signal E, the amount of biological sludge in the returned sludge can be grasped.
[0045]
At this time, the signal processing unit 37 determines whether or not the level of the light reception signal E output from the detection unit 30 is disturbed (Step S1). When the signal processing unit 37 determines that the level of the received light signal E is disturbed, the signal processing unit 37 further determines a change in the signal amplitude of the received light signal E (step S2). Incidentally, the signal amplitude of the light receiving signal E referred to here, for example, when the light receiving signal E as shown in FIG. 9 is detected, is equal to or more than a predetermined level (B) with reference to the average level (MLSS density) of the light receiving signal E. ) Or a change in amplitude (A) of a signal waveform obtained by extracting the light receiving signal E of a predetermined level or less (C).
[0046]
At this time, when the signal processing unit 37 determines that the change in the amplitude of the light reception signal E is smaller than a predetermined threshold, the signal processing unit 37 determines that the slurry concentration in the solution is non-uniform (step S2). On the other hand, when the signal processing unit 37 determines in step S2 that the change in the amplitude of the received light signal E is larger than a predetermined threshold, the signal processing unit 37 further determines whether the minimum peak value (minimum peak value) of the signal amplitude has changed. A determination is made (step S3). When the change in the minimum peak value is larger than a predetermined threshold, the signal processing unit 37 determines that the filamentous bulking has occurred in the solution.
[0047]
On the other hand, when the change in the minimum peak value is smaller than the predetermined threshold value in step S3, the signal processing unit 37 determines that viscous bulking has occurred in the solution.
When it is determined in step S1 that the level of the received light signal E is not disturbed, the signal processing unit 37 further determines a change in the signal amplitude of the received light signal E (step S4). In step S4, if the change in the amplitude of the received light signal E is smaller than a predetermined threshold, the signal processing unit 37 determines the level of the minimum peak value of the received light signal (step S5). If there is a minimum peak value higher than a predetermined threshold value (a past minimum peak value in a normal state) in step S5, the signal processing unit 37 determines that the sludge of the solution has been dispersed. When only the minimum peak value lower than the predetermined threshold value (the past minimum peak value in the normal state) is determined in step 5, the signal processing unit 37 determines that the sludge of the solution has been dismantled.
[0048]
On the other hand, the signal processing unit 37 that has determined in step S4 that the change in the amplitude of the received light signal E is larger than a predetermined threshold value further determines the level of the minimum peak value of the received light signal E (step S6). When the minimum peak value of the received light signal E is higher than a predetermined threshold value in step S6, the signal processing unit 37 determines that the sludge of the solution is normal. When the minimum peak value level of the received light signal E is lower than the predetermined threshold value in step 6, the signal processing unit 37 determines that the sludge of the solution has been dismantled.
[0049]
Therefore, according to the biological sludge monitoring and control device configured as described above, by monitoring the level of the transmitted light received by the light receiving unit 31, that is, the level change of the light receiving signal E output by the detecting unit 30, The state can be determined. In particular, it is possible to detect the occurrence of bulking, which is a problem in a water purification device using biological sludge. This is based on the finding that when the number of filamentous bacteria increases and bulking occurs, the fluctuation of the short-term average value of the light receiving level of the transmitted light received by the light receiving unit 31 increases.
[0050]
For example, when the number of filamentous bacteria is small as shown in FIG. 10, the level of the light reception signal E output by the detection unit 30 is equal to the maximum value of the light reception signal E output by the detection unit 30 as shown in FIG. The signal amplitude indicated by the difference from the minimum value is within a certain range, and the average value shows a certain value. Where a large amplitude value is detected, it indicates that the particle diameter of the sludge particles present at the detection site of the sensor 10 is small and the amount of light reaching the light receiving unit 31 is large. On the other hand, where a small amplitude value is detected, it indicates that the particle diameter of the sludge particles present at the detection site of the sensor 10 is large and the amount of light reaching the light receiving unit 31 is small.
[0051]
Next, as shown in FIG. 12, when the number of filamentous bacteria increases and the filamentous bacteria are entangled with each other to form a large particle group, the short-time average value of the received light waveform is shown in FIG. Fluctuate greatly. Therefore, occurrence of bulking can be detected.
Incidentally, when the particle diameter of the sludge particles is small and no filamentous bacteria are present (for example, FIG. 13), the amplitude value of the detection signal is small, and the average value of the detection signal also shows a constant value (FIG. 11 (c)). ].
[0052]
In particular, in step S2, after the signal processing unit 37 determines that the amplitude change of the received light signal E is large and there is occurrence of bulking, the signal processing unit 37 further captures the temporal change of the disturbance of the level of the received light signal E to thereby determine the degree of progress of the bulking. Can also be determined. That is, the signal processing unit 37, which has determined in step S2 that the change in the amplitude of the received light signal E is large, further observes the temporal change of the received light signal E. When the level of the light receiving signal E increases with the passage of time, the signal processing unit 37 can determine that bulking is in progress. On the other hand, when the level of the light receiving signal E decreases with the passage of time, the signal processing unit 37 can determine that the bulking has decreased and the signal has a tendency to recover.
[0053]
Next, as shown in FIG. 14, a light receiving unit 31a that detects light transmitted through the measured water S and a light receiving unit 31b that detects scattered light scattered by sludge particles included in the measured water S are combined. The configured biological sludge monitoring device will be described. Although not shown, the biological sludge monitoring device is configured so that the light emitting unit 20 can select two types of wavelengths of light emitted from the measured water S by a control signal of the signal processing unit 37.
[0054]
In the biological sludge monitoring device configured as described above, when the wavelength of the light of the light receiving unit 31a that detects the light transmitted through the water S to be measured is changed, the light is received by the average level of the light receiving signal E at each wavelength of the light. The state of the measurement water S can be determined. Specifically, when the wavelength of the light emitted from the light emitting unit 20 into the measured water S is [450 nm] and [630 nm], the scattered light scattered by the sludge particles contained in the measured water S is detected. As shown in FIG. 15, the state of the biological sludge can be determined from the average value of the received light signal at each wavelength detected by the light receiving unit 31b.
[0055]
Specifically, the average value of the received light signal E when the wavelength of the light emitted by the light emitting unit 20 is [450 nm] is low, and the received light signal when the wavelength of the light emitted by the light emitting unit 20 is [630 nm]. When the average value of E is low, it can be determined that the color tone of the measured water is blackish. The average value of the light reception signal E when the wavelength of the light emitted by the light emitting unit 20 is [450 nm] is low, and the average value of the light reception signal E when the wavelength of the light emitted by the light emitting unit 20 is [630 nm]. When the value is high, it can be determined that the color tone of the measured water is reddish.
[0056]
Alternatively, the average value of the received light signal E when the wavelength of the light emitted by the light emitting unit 20 is [450 nm] is high, and the average of the received light signal E when the wavelength of the light emitted by the light emitting unit 20 is [630 nm]. When the value is low, it can be determined that the color tone of the measured water is purple. The average value of the received light signal E when the wavelength of the light emitted by the light emitting unit 20 is [450 nm] is high, and the average of the received light signal E when the wavelength of the light emitted by the light emitting unit 20 is [630 nm]. When the value is high, it can be determined that the color tone of the measured water is whitish. That is, the state of the sludge can be determined by using the average level of the received light signal E at each wavelength detected by the light receiving unit 31a that detects the transmitted light transmitted through the sludge particles contained in the water S to be measured.
[0057]
As described above, the light receiving unit 31b that detects the scattered light scattered by the sludge particles contained in the measured water S detects the color tone of the sludge particles while detecting the transmitted light transmitted through the measured water S. The unit 31a detects the density of the sludge particles. Therefore, according to the biological sludge monitoring device configured by combining the output signal (light receiving signal) of the light receiving unit 31b that detects scattered light and the output signal (light receiving signal) of the light receiving unit 31a that detects transmitted light, When the wavelength of the light emitted by the light source 20 is changed, the color tone and density of the biological sludge contained in the water S to be measured can be simultaneously determined by using the average level of the light receiving signal E of the light receiving unit (31a, 31b) for each wavelength. Can be determined.
[0058]
For example, in the light receiving unit 31a that detects light transmitted through the measured water S, the average value of the light receiving signal E when the wavelength of the light emitted by the light emitting unit 20 is [450 nm] is low, and the light emitting unit 20 emits light. The light emitted by the light emitting unit 20 in the light receiving unit 31b that detects the scattered light scattered by the sludge particles contained in the measured water S while the average value of the received light signal E when the light wavelength is [630 nm] is low. When the average value of the light reception signal E when the wavelength of the light is [450 nm] is high, and when the average value of the light reception signal E when the wavelength of the light emitted from the light emitting unit 20 is [630 nm] is high, the measured water S The state of the contained biological sludge can be determined to be white in color and low in density. It is needless to say that the average value of the light receiving signal E detected by the light receiving units (31a, 31b) indicates the MLSS concentration of the water S to be measured.
[0059]
Thus, according to the biological sludge monitoring device configured as described above, the scattered light and the reflected light when irradiating the biological sludge in the measured water S by changing the wavelength of the laser diode 22 of the optical sensor are detected. Since the determination is made by combining the average levels of the detection signals of the respective wavelengths, it is possible to simultaneously detect the change in the color tone and the change in the density of the sludge.
[0060]
The present invention can be implemented with various modifications without departing from the scope of the invention. For example, in the above-described embodiment, the light receiving unit 31 that detects biological sludge is provided in the aeration tank 2. However, a sampling tube (not shown) is provided in the aeration tank 2 to remove the sludge slurry in the aeration tank 2. After being transferred to the measuring tank, the sludge slurry in the measuring tank may be configured to detect the state of the biological sludge using the above-described method. The transfer of the sludge slurry from the aeration tank 2 to the measurement tank via the sampling tube may be performed by, for example, a method using a pump or a method using compressed air. In this case, since the sludge slurry in the aeration tank 2 is transferred to the measurement tank via the sampling tube, it is not necessary to stop the air blow to the aeration tank 2 at the time of measurement, which is required in the above-described embodiment, and the biological sludge is not required. It is more preferable to continuously detect the above condition.
[0061]
Alternatively, after the sludge slurry in the aeration tank 2 is pumped up by a bucket (not shown), the state of the biological sludge may be detected using the above-described method. In this case, the method of pumping the sludge slurry from the aeration tank is not particularly shown, but may be a mechanical method or a manual pumping method.
[0062]
Since the sludge slurry is pumped from the aeration tank 2 in this manner, the state of the biological sludge can be detected without stopping the air blow to the aeration tank 2 containing the biological sludge.
Further, in the above-described embodiment, the method using the transmitted light type probe for detecting the light transmitted through the measured water S is used, for example, when the measured water S is irradiated with light as shown in FIG. The light receiving unit 31 having a light receiving unit that detects scattered light obtained by the sludge particles in the water S to be measured may be used. Even with this method of detecting scattered light, it is possible to automatically and continuously measure and monitor the existing state of biological sludge.
[0063]
In FIG. 16, the light emitting unit, the detecting unit, and the signal processing unit are the same as those of the biological sludge monitoring device using the transmitted light type probe described above, so that the description thereof is partially omitted.
Alternatively, as shown in FIG. 17, the light receiving unit 31a for detecting the light transmitted through the water S to be measured and the light receiving unit 31b for detecting the scattered light scattered by the sludge particles contained in the water S to be measured are combined. It may be a biological sludge monitoring device. In this case, the detection signals detected by the respective light receiving units (31a, 31b) are combined by a combining circuit 38, and then supplied to a signal processing unit 37 via a band pass filter (BPF) 34. This synthesizer detects the concentration of biological sludge contained in the water S to be measured by calculating the ratio of the level of the detection signal detected by each probe, and corrects the detection error due to the sludge attached to the probe. And so on.
[0064]
Alternatively, in addition to the method of detecting biological sludge by the above-described optical method, a method using ultrasonic waves (ultrasonic method) may be used. An ultrasonic sensor used in the ultrasonic method includes, for example, a transmitter 41 for irradiating ultrasonic waves into the water S to be measured, a transmitter 42 for driving the transmitter 41, and an The receiver 43 is provided at a position facing the target and a receiver 44 for processing an ultrasonic signal received by the receiver 43.
[0065]
The ultrasonic method utilizes the fact that the ultrasonic waves emitted from the transmitter 41 are scattered by the sludge contained in the water S to be measured, and the signal level of the ultrasonic waves received by the receiver 43 is attenuated according to the sludge concentration. Things. Therefore, even when the ultrasonic method is used, the state of the biological sludge can be detected in the same manner as the above-described optical method.
[0066]
Alternatively, the state of the biological sludge may be detected using microwaves other than the method described above. For example, as shown in FIG. 19, the microwave sensor using the microwave includes a microwave transmitter 51 that irradiates the microwave into the water S to be measured and a microwave transmitter 52 that drives the microwave transmitter 51. The microwave transmitter 53 receives the scattered waves scattered by the sludge contained in the water S to be measured by the microwave transmitter 51, and processes the microwave received by the microwave receiver 53. The microwave receiver 54 is provided.
[0067]
In this microwave method, the microwave radiated from the microwave transmitter 51 is scattered by the sludge contained in the measured water S, and the signal level of the microwave received by the microwave receiver 53 increases or decreases according to the sludge concentration. It is based on this. Therefore, even when the microwave method is used, the state of the biological sludge can be detected in the same manner as the above-described optical method.
[0068]
In the above-mentioned reflected light method, ultrasonic method or microwave method, when light, ultrasonic waves or microwaves having a large projected area with respect to the particle diameter of material sludge are irradiated into the water S to be measured, a light receiving section is formed. Alternatively, it becomes difficult to detect a waveform change in the receiver (deterioration of the S / N ratio). For this reason, the projected area of the light beam, ultrasonic wave or microwave applied to the water S to be measured is preferably [1 cm ² It is desirable to narrow down to about the following.
[0069]
As described above, the biological sludge monitoring device according to the present invention monitors the average data obtained by averaging the levels of the detection signals output by the sensors that detect the concentration of the biologically-sludge slurry that is uniformly agitated at predetermined time intervals. The presence of bulked sludge can be detected. Further, by monitoring the change over time of the average data, the progress of bulking can be detected.
[0070]
Further, since the amplitude data indicated by the difference between the maximum value and the minimum value of the detection signal is monitored, it is possible to detect the variation in the particles of the biological sludge. By monitoring the change over time of the amplitude data, an abnormality in the biological sludge can be immediately detected.
Also, the minimum peak value (envelope signal) of the amplitude of the detection signal and the amplitude data of the envelope signal indicated by the difference between the maximum value and the minimum value of the envelope signal are monitored. Therefore, the degree of clarification of the sludge slurry can be grasped. Therefore, the dismantling of the sludge floc can be detected.
[0071]
Furthermore, when the water to be measured is irradiated with light of two different wavelengths, the light is transmitted to the sludge particles in the water to be measured and / or the light is transmitted to the sludge particles in the water to be measured. Since the scattered light generated by the collision of the sludge is detected, it is possible to detect the color change of the sludge existing in the measured water.
[0072]
【The invention's effect】
As described above, according to the biological sludge monitoring device of the present invention, it is possible to continuously monitor the state of the biological sludge of the water purification device using the biological sludge and determine a change in the state. Furthermore, using the information on the state change, it is possible to quickly detect abnormalities in the biological sludge and adjust / control the operating conditions of the water purification apparatus. For this reason, a tremendous effect can be obtained in practical use such as stable operation management of the water purification device can be realized.
[Brief description of the drawings]
FIG. 1 is a graph showing a relationship between a biological sludge concentration and an average level of a signal waveform output by a sensor.
FIG. 2 is a graph showing a relationship between a difference in sludge particle diameter and an amplitude of a signal waveform output by a sensor.
FIG. 3 is a graph showing the relationship between the abundance of filamentous bacterial sludge and the signal level output by a sensor.
FIG. 4 is a graph showing the signal level of the envelope obtained by extracting the envelope of the supernatant liquid turbidity and the signal output by the sensor.
FIG. 5 is a graph showing the relationship between the difference in the color tone of biological sludge and the amplitude of a signal waveform output by a sensor.
FIG. 6 is a schematic configuration diagram showing an example of a sewage treatment facility.
FIG. 7 is a diagram showing a schematic configuration of a biological sludge monitoring device according to an embodiment of the present invention.
FIG. 8 is a flowchart showing an algorithm for detecting bulking of the biological sludge monitoring apparatus according to one embodiment of the present invention.
FIG. 9 is a graph showing a waveform of a minimum peak value of a detection signal amplitude detected by a sensor of the biological sludge monitoring apparatus according to one embodiment of the present invention, particularly a waveform when bulking occurs in filamentous bacteria. A graph showing.
FIG. 10 is a micrograph showing biological sludge when the amount of filamentous bacteria is small.
FIG. 11 is a graph showing a relationship between a detection signal detected by a sensor of the biological sludge monitoring device according to one embodiment of the present invention and an average value of the detection signal.
FIG. 12 is a micrograph showing biological sludge when there are many filamentous bacteria.
FIG. 13 is a micrograph showing biological sludge when there is no filamentous bacteria and the sludge particle size is small.
FIG. 14 is a view showing a schematic configuration of a main part of a biological sludge apparatus according to another embodiment of the present invention, which detects a state of biological sludge using transmitted light and scattered light.
FIG. 15 is a diagram showing a relationship between sludge states when a state of biological sludge is detected using transmitted light and scattered light.
FIG. 16 is a diagram showing a schematic configuration of a main part of a biological sludge apparatus according to another embodiment of the present invention for detecting a state of biological sludge using scattered light.
FIG. 17 is a diagram showing a schematic configuration of a main part of a biological sludge apparatus according to another embodiment of the present invention, which detects a state of biological sludge using transmitted light and scattered light.
FIG. 18 is a diagram showing a schematic configuration of a main part of a biological sludge apparatus according to another embodiment of the present invention for detecting the state of biological sludge using ultrasonic waves.
FIG. 19 is a diagram showing a schematic configuration of a main part of a biological sludge apparatus according to another embodiment of the present invention, which detects the state of biological sludge using microwaves.
[Explanation of symbols]
10 sensors
20 Light emitting unit
21 Laser diode drive circuit
22 Laser Diode
23 Amplitude modulator
30 Detector
31 Receiver
32 optical fiber
33 photoelectric converter
34 Bandpass Filter
35 Amplifier
36 detector
37 signal processing unit
E Envelope component
F Amplitude modulation frequency component
L laser light
S Water to be measured

Claims (8)

A sensor for outputting a detection signal corresponding to the concentration of the biologically-sludge slurry of the water to be measured uniformly stirred,
(A) means for obtaining average data obtained by averaging the levels of the detection signals output by the sensor at predetermined time intervals;
(B) means for obtaining amplitude data indicated by a difference between a maximum value and a minimum value of the detection signal;
(C) means for determining the minimum peak value of the amplitude of the detection signal;
(D) means for obtaining amplitude data of a signal indicated by a difference between a maximum value and a minimum value of data according to a time change of the minimum peak value,
Calculating means for obtaining at least one data of
A biological sludge monitoring apparatus comprising: a determination unit configured to determine a state of the biological sludge of the water to be measured from the data obtained by the arithmetic unit. The determination unit determines that bulking has occurred in the biological sludge slurry when average data obtained by averaging the levels of the detection signals output by the sensor at predetermined time intervals repeatedly fluctuates with time. The biological sludge monitoring device according to claim 1. When the amplitude data indicated by the difference between the maximum value and the minimum value of the detection signal output by the sensor exceeds a predetermined value, or is less than a predetermined value, the biological sludge The biological sludge monitoring device according to claim 1, wherein the biological sludge monitoring device is configured to determine that the variation of the sludge particle diameter in the slurry is increasing or decreasing. The determination unit, from the minimum peak value of the amplitude of the detection signal output by the sensor and the amplitude data of the signal indicated by the difference between the maximum value and the minimum value of the data with time change of the minimum peak value, The biological sludge monitoring device according to claim 1, wherein the biological sludge slurry is used to determine clarity. The sensor irradiates the water to be measured with light, and transmits the transmitted light passing through the sludge particles in the measurement water and / or the scattered light generated by collision of the light with the sludge particles in the measurement water. The biological sludge monitoring device according to any one of claims 1 to 4, comprising an optical sensor for detecting. The sensor is an ultrasonic sensor that irradiates ultrasonic waves to the water to be measured and detects a reflected scattered sound and / or a transmitted sound generated by the collision of the ultrasonic waves with the sludge particles in the measured water. The biological sludge monitoring device according to claim 1. The sensor according to any one of claims 1 to 4, wherein the sensor is configured to irradiate a microwave to the water to be measured and to detect an electromagnetic wave of the microwave transmitted between sludge particles in the water to be measured. The biological sludge monitoring device according to the above. The sensor irradiates the water to be measured with light of two different wavelengths, and transmits each light through the sludge particles in the measurement water and / or the light to the sludge particles in the measurement water. The biological sludge monitoring device according to claim 5, which detects scattered light generated by the collision.

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