JP4403812B2 - Methane fermentation treatment method - Google Patents

Description

  The present invention relates to a methane fermentation treatment method for treating organic waste such as manure, raw garbage, food processing residue and the like using anaerobic microorganisms.

  Most organic waste such as garbage and digested sludge is incinerated or disposed of in landfills. However, due to problems such as dioxin generation due to incineration, tightness of landfill sites, and bad odors, treatment methods with less environmental impact are available It has been demanded. In order to solve these problems, a system has been developed in which organic waste is subjected to methane fermentation, and the generated methane gas is generated using a fuel cell or a gas engine.

  This methane fermentation is an energy-saving treatment method that can decompose organic waste into biogas and water, greatly reducing the amount of waste, and does not require aeration power because it is anaerobic. There is an advantage that methane gas can be recovered as energy.

  In the methane fermentation treatment, organic waste is pulverized and slurried, and then the slurry is put into a fermenter and fermented with methane bacteria under anaerobic conditions to convert the organic waste into methane gas. Various processing methods and fermenters have been proposed depending on the properties of the input raw materials and operating conditions.

  In methane fermentation, when fermentation is stable, a certain amount of biogas is produced if a specified amount of organic waste such as garbage is input. However, the fermentation state also fluctuates due to fluctuations in the fermentation temperature and the amount of dust input, and this fluctuation causes a reduction in fermentation performance. The reason why the fermentation performance is reduced is that the activity of the anaerobic bacteria group mainly related to methane fermentation is reduced, and as a factor of the decrease in activity, there is generation of an inhibitor such as ammonia in addition to pH and temperature. Therefore, a technique for controlling the fermentation state so that the concentration of ammonia, particularly ammoniacal nitrogen, is not more than a predetermined concentration is known.

  For example, Patent Document 1 below discloses that when organic wastewater is subjected to methane fermentation, the organic wastewater is diluted so that the concentration of ammoniacal nitrogen in the tank is 2000 mg / L or less.

  In Patent Document 2 below, the ammonia nitrogen concentration in the methane fermentation tank for treating organic waste is detected by a detection unit, and water is poured into the fermentation tank so that this concentration is 5000 mg / L or less. Supplying and diluting is disclosed.

Furthermore, the following Patent Document 3 discloses that waste water denitrified in a waste water treatment tank is injected into raw garbage as dilution water to reduce the ammonia concentration in the methane fermentation tank.
Japanese Patent Publication No.7-115030 JP 2003-39039 A Japanese Patent Laid-Open No. 11-57661

  As mentioned above, ammonia, one of the inhibitors of methane fermentation, inhibits the activity of bacteria related to methane fermentation and significantly reduces the fermentation performance. Therefore, detection and control of ammoniacal nitrogen concentration in the fermentation broth Is very important. And also in said prior art, reducing ammonia nitrogen concentration with dilution water is disclosed.

  However, in the above Patent Documents 1 to 3, a method for detecting the ammoniacal nitrogen concentration is not disclosed in detail. Usually, as a detection method, it is conceivable to detect ammonia nitrogen using an analytical instrument such as ion chromatography. However, this measurement method requires expensive precision measurement equipment, and is expensive to manage and maintain. Moreover, since the time required for detection is long and time-consuming, it is not suitable for constant monitoring.

  For this reason, it was practically difficult to control the ammonia nitrogen concentration to the optimum range by dilution while constantly monitoring the ammonia nitrogen concentration during the methane fermentation treatment.

  The present invention has been made in view of the above-mentioned problems of the prior art, and its purpose is to monitor ammonia nitrogen concentration in a methane fermenter by a simpler measurement method than before, and to stabilize methane fermentation. It is in providing the methane fermentation processing method which can be performed.

That is, in the methane fermentation treatment method of the present invention, after paste-like organic waste is slurried in a slurry adjustment tank and charged into the methane fermentation tank, methane fermentation is performed by anaerobic microorganisms to generate biogas. In the methane fermentation treatment method of taking out the fermentation liquor and treating it in a waste liquid treatment tank,
The electrical conductivity of the slurry adjustment tank is measured, and the organic waste supply amount and / or dilution water supply amount to the slurry adjustment tank is controlled so that the electrical conductivity of the slurry adjustment tank falls within a predetermined range. While measuring the electrical conductivity of the methane fermenter, so that the difference between the electrical conductivity of the methane fermenter and the electrical conductivity of the slurry adjustment tank does not exceed a predetermined value, It is characterized by controlling the dilution water supply amount .

  The action and effect of the above-described invention will be described. The electric conductivity of organic waste varies depending on the salt concentration (for example, Na, Ca, K, Mg, etc.) contained, In the case of organic waste, the salt concentration is almost constant. For this reason, especially in the case of organic waste such as municipal waste with little component change, the solid content concentration of the slurry and the electrical conductivity have a positive correlation. There is also a correlation between the slurry solids concentration and the ammoniacal nitrogen concentration in the methane fermenter. Therefore, by controlling the electrical conductivity of the slurry adjusting tank within a predetermined range, it is possible to control the ammoniacal nitrogen concentration in the fermenter to be equal to or lower than the inhibition region of methane fermentation.

  In addition, the measurement of electrical conductivity does not require a complicated and expensive analytical instrument such as gas chromatography, can be easily measured at a low cost and in a short time, and can be constantly monitored. Accordingly, the ammoniacal nitrogen concentration can be monitored using the electrical conductivity as an index, and the methane fermentation state can be favorably maintained by maintaining the electrical conductivity below a predetermined value.

In addition, when the organic waste to be introduced into the methane fermentation treatment apparatus has a salt concentration change such as trash that has a salt concentration change due to the menu, the slurry solid content concentration is determined from the electrical conductivity in the slurry adjustment tank. Therefore, it is difficult to monitor and control the ammonia nitrogen concentration in the methane fermentation tank only from the electric conductivity value in the slurry adjustment tank. However , by subtracting the measured value of the electrical conductivity in the slurry adjustment tank from the measured value of the electrical conductivity in the methane fermenter, it is possible to obtain an electrical conductivity value due to ammonia nitrogen, It is possible to monitor and control the concentration of ammoniacal nitrogen present in the inside. Furthermore, the electric conductivity in the methane fermentation tank is adjusted by adjusting the amount of organic waste supplied to the slurry adjustment tank and / or the amount of diluting water and adjusting the electric conductivity in the slurry adjustment tank to be within a predetermined value range. The calculated value obtained by subtracting the electrical conductivity value in the slurry adjustment tank from the rate value can be an electrical conductivity value resulting from highly accurate ammonia nitrogen.

  And the methane fermentation tank is controlled by controlling the dilution water supply amount to the methane fermentation tank so that the difference between the electrical conductivity of the methane fermentation tank and the electrical conductivity of the slurry adjustment tank does not exceed a predetermined value. By controlling the ammonia concentration in the inside more accurately, it is possible to carry out stable fermentation even in the case of organic waste having a change in salt concentration such as trash.

  Furthermore, in this invention, when the difference of the said measured value is 9 mS / cm or more, it is preferable to supply dilution water in the said methane fermenter. According to this aspect, the ammoniacal nitrogen concentration in the methane fermenter can be maintained at 1500 mg / L or less, which is generally referred to as an inhibition region, so that the fermentation state in the methane fermenter can be stably maintained.

According to the present invention, the electrical conductivity of the slurry adjustment tank is measured, and the organic waste supply amount and / or dilution water supply to the slurry adjustment tank is set so that the electrical conductivity of the slurry adjustment tank falls within a predetermined range. While controlling the amount, measure the electrical conductivity of the methane fermenter, and dilute the methane fermenter so that the difference between the electrical conductivity of the methane fermenter and the electrical conductivity of the slurry adjustment tank does not exceed the predetermined value By controlling the amount of water supply, even in the case of organic waste with a large component change, it is possible to suppress the increase in ammonia nitrogen concentration in the methane fermenter and to prevent the activity of anaerobic bacteria from being inhibited. A stable fermentation state can be maintained.

Hereinafter, the present invention will be described in more detail with reference to the drawings. The schematic block diagram of one Embodiment of the methane fermentation processing apparatus which can be used for the methane fermentation processing method used as the reference example of this invention is shown by FIG.

  First, the processing apparatus of FIG. 1 will be described. This processing apparatus includes a pulverization processing tank 10 for processing organic waste into a paste, a slurry adjusting tank 12 for storing the paste in a slurry state, and the slurry adjusting tank. 12 mainly comprises a tap water tank 11 for adjusting the slurry concentration, a methane fermentation tank 13, and a waste liquid treatment tank 14 for treating the fermented liquid after the methane fermentation treatment.

  The piping from the pulverization processing tank 11 is connected to the slurry adjustment tank 12 via the paste supply pump 20, and the piping from the tap water tank 11 is connected to the slurry adjustment tank 12 via the tap water supply electromagnetic valve 21. It is connected. The piping from the slurry adjustment tank 12 is connected to the methane fermentation tank 13 via a slurry supply pump 22. The pipe from the methane fermentation tank 13 is connected to the waste liquid treatment tank 14 via the pipe.

  The waste liquid treatment tank 14 only needs to be capable of denitrification treatment, for example, an activated sludge tank for performing a biological treatment method for removing organic matter and nitrogen by microorganisms, or after aeration treatment of ammonia and catalytic combustion with air. An apparatus that performs an ammonia stripping method that renders nitrogen gas harmless can be used.

  A pipe for extracting the slurry after the methane fermentation treatment is connected from the bottom of the methane fermentation tank 13 via a slurry extraction pump 23.

  Furthermore, a pipe for taking out the generated biogas is connected to the upper part of the methane fermentation tank 13, and this biogas is collected by a gas holder (not shown).

  An electrical conductivity meter 30 is connected to the slurry adjustment tank 12 so that the electrical conductivity in the slurry adjustment tank 12 can be measured. Here, a conventionally well-known thing can be used as the electrical conductivity meter 30, and it is not specifically limited.

  The measurement value from the electric conductivity meter 30 is configured to be input to a PLC 40 (programmable logic controller) that is an arithmetic unit. In the arithmetic unit PLC 40, the processing shown in the flowchart of FIG. 2 is performed.

  Arithmetic processing and control by the PLC will be described with reference to FIG. First, in step S <b> 1, the electrical conductivity of the slurry in the slurry adjustment tank 12 measured using the electrical conductivity meter 30 is input to the PLC 40 as a measured value.

  Then, the process proceeds to step S2, where it is determined whether the measured value is within a predetermined range. If the measured value is within the predetermined range, the slurry is sent to the methane fermentation tank 13, but the measured value is outside the predetermined range. If so, the process proceeds to step S3.

  In step S3, it is determined whether or not the measured value exceeds a predetermined range. When the measured value is equal to or greater than the predetermined range, the process proceeds to step S4, the tap water supply electromagnetic valve 21 is operated, tap water is supplied into the slurry adjustment tank 12, and the slurry is diluted. When the measured value is below the predetermined range value, the process proceeds to step S5, the paste supply pump 20 is operated, the paste-like organic waste is put into the slurry adjustment tank 12, and the slurry solid content concentration is adjusted. To do.

  Thus, in PLC40, it is comprised so that the electrical conductivity of a slurry can be controlled within a predetermined value range.

Next , a methane fermentation treatment method using this treatment apparatus will be described.

  The organic waste is first stored in the pulverization treatment tank 10, crushed, pulverized, and made into a paste. The pasted organic waste is stored in the slurry adjustment tank 12 via the paste supply pump 20. Here, it is diluted with moderate water from the tap water tank 11 to be slurried.

In this embodiment , the electrical conductivity is measured by the electrical conductivity meter 30 in the slurry adjusting tank 12, and this is input to the PLC 40.

  In the PLC 40, calculation processing and control are performed based on the input measurement value, and the paste supply pump 20 or the tap water supply electromagnetic valve 21 is operated as necessary, so that the electrical conductivity of the slurry adjustment tank 12 is increased. Control is performed within a predetermined value range.

  Next, this slurry is put into the methane fermentation tank 13 by the slurry supply pump 22 to perform methane fermentation.

  The methane fermentation tank 13 is provided with a fixed filter bed or the like filled with immobilized microorganisms on which anaerobic microorganisms such as methane bacteria (not shown) are attached and supported. The slurry is subjected to methane fermentation and anaerobic. Organic waste is decomposed by microorganisms. It is preferable to perform the temperature in methane fermentation at 50-60 degreeC. According to this, since it is possible to perform fermentation with a more active high-temperature methane bacterium, the decomposition rate of organic waste can be further improved.

  Note that the same amount of fermentation broth as the slurry supplied at regular intervals is drawn from the bottom of the methane fermentation tank 13 by the slurry extraction pump 23, and the inside of the methane fermentation tank 13 is always filled with a fixed amount of slurry. . In addition, biogas produced by fermentation is collected in a gas holder (not shown) and is effectively used as a fuel for a power generator such as a fuel cell power generation device or a gas engine or a boiler.

Thus, in this embodiment, it is carried out methane fermentation by controlling the electrical conductivity of the slurry adjusting tank in a predetermined range.

  The relationship between the solid content concentration of the organic waste slurry and the electrical conductivity is positively correlated as shown in FIG. 3, and the numerical values are summarized in Table 1. For example, since organic waste contains salts such as Na, Ca, K, and Mg, these salts are expressed as electrical conductivity. Even if the slurry is unfermented, the electrical conductivity is reduced. Have.

  From FIG. 3 and Table 1, it can be seen that there is a high correlation between the solid content concentration of the slurry and its electrical conductivity. Thereby, when controlling the solid content concentration of the slurry, the solid content amount can be controlled by measuring the electric conductivity without measuring the weight of the slurry.

  In addition, for organic wastes that have almost no change in components, such as municipal waste, and whose salt concentration is almost constant, the concentration of slurry solids and the concentration of ammoniacal nitrogen produced by methane fermentation are shown in FIG. As shown, there is a positive correlation, and Table 2 summarizes the numerical values.

  4 and Table 2, it can be seen that the solid content concentration of the slurry and the ammonia nitrogen concentration generated by methane fermentation have a high correlation. Therefore, by adjusting the solid content concentration of the slurry, it is possible to grasp the ammonia nitrogen concentration generated by methane fermentation, so it is possible to carry out methane fermentation treatment so that ammonia nitrogen is below the inhibition region It is.

In addition, the inhibition of anaerobic bacteria such as methane bacteria by ammonia is mainly stronger in non-dissociated ammonia (NH ₃ ) than in ammonium ions (NH ₄ ⁺ ). However, it is known that when ammonium ion is measured by ion chromatography and the concentration converted to ammonia nitrogen exceeds a certain value, it becomes an inhibition region (KHHansen et al., Water Research, vol. 32, No. .1, p5-12 (1998)). According to this document, the inhibition by ammonia occurs at an ammoniacal nitrogen concentration of 4000 mg / L, and it occurs at 1500 to 2000 mg / L when acclimatization is not performed.

  Therefore, it is considered that stable methane fermentation can be maintained if the ammoniacal nitrogen concentration is 1500 mg / L or less.

  Depending on the type of organic waste used in the treatment, the salt concentration and the solid content concentration, the optimum electrical conductivity for the implementation of methane fermentation varies. Therefore, the regression equations as shown in FIGS. It is necessary to determine the electrical conductivity when the ammonia nitrogen concentration is 1500 mg / L, and to set a reference value. From the obtained reference value (reference value−0.5 mS / cm) to (reference value + 0) Stable methane fermentation can be carried out by adjusting the electrical conductivity of the slurry within the range of .5 mS / cm), and (reference value−0.2 mS / cm) to (reference value + 0.2 mS). / Cm), the control operation of the methane fermenter with high accuracy can be carried out more effectively.

  In the above embodiment, the organic waste is assumed to have an almost constant salt concentration with almost no change in components such as municipal waste.

FIG. 5 shows an embodiment of a methane fermentation treatment apparatus which can be used in the methane fermentation process of the present invention. In the following description of the embodiment, the same parts as those in the reference example are denoted by the same reference numerals, and the description thereof is omitted.

  1 is different from the processing apparatus according to the embodiment shown in FIG. 1 in that an electric conductivity meter 31 is newly installed in the methane fermentation tank 12, and a pipe from the waste liquid processing tank 14 is connected to the circulation processing pump 24. Are connected to the methane fermentation tank 13, and are configured such that a part of the treated water denitrified in the waste liquid treatment tank 14 can be returned to the methane fermentation tank 13, and an electric conductivity meter 30. The measurement value from 31 is input to a PLC 41 (programmable logic controller) which is an arithmetic unit, and the treated water in the waste liquid treatment tank 14 is returned to the methane fermentation tank 13 according to the calculation result here. There are three points.

  Next, arithmetic processing and control by the PLC 41 will be described with reference to FIG. Since the processing from step S1 to step S5 is the same as that in the above-described embodiment, it is omitted here.

  In step S6, the slurry whose electrical conductivity is controlled within a predetermined range is transferred to the methane fermentation tank 13 through step S2, and methane fermentation is performed. Here, the electrical conductivity of the fermentation broth in the methane fermentation tank 13 is measured by the electrical conductivity meter 31, and the measurement result is input to the PLC 41. Then, the process proceeds to step S7, where the difference between the measured values of the electric conductivity meter 30 and the electric conductivity meter 31 is calculated, and it is determined whether the difference between the calculated values is less than a predetermined value. If it is less than the predetermined value, the methane fermentation treatment is performed as it is. However, when the difference between the calculated values is equal to or larger than the predetermined value, the process proceeds to step S8, the processing liquid circulation pump 24 is operated to supply a part of the processing water into the methane fermentation tank 13, and the methane fermentation tank 13 The fermentation broth inside is diluted.

  That is, the PLC 41 is configured so that the electrical conductivity of the slurry is controlled to be within a predetermined value range, and further, the electrical conductivity difference between the slurry adjusting tank 12 and the methane fermentation tank 13 is set to a predetermined value or less. It has become.

Next, a fermentation processing method using this processing apparatus will be described.
The organic waste is first stored in the pulverization treatment tank 10, crushed, pulverized, and made into a paste. The pasted organic waste is stored in the slurry adjustment tank 12 via the paste supply pump 20. Here, it is diluted with moderate water from the tap water tank 11 to be slurried.

  Here, in the slurry adjustment tank 12, the electric conductivity is measured by the electric conductivity meter 30, and this is input to the PLC 41.

  In the PLC 41, the paste supply pump 20 or the tap water supply electromagnetic valve 21 is operated as necessary based on the input measurement value, and the electrical conductivity meter of the slurry adjustment tank 12 falls within a predetermined value range. To control.

  Next, this slurry is put into the methane fermentation tank 13 by the slurry supply pump 22 to perform methane fermentation.

  Here, in the methane fermentation tank 13, the electric conductivity is measured by the electric conductivity meter 31, and this is input to the PLC 41. The difference between the measured values from the electric conductivity meter 30 and the electric conductivity meter 31 is calculated in the PLC 41, and the processing liquid circulation pump 24 is operated as necessary to pass a part of the processing water into the methane fermentation tank 13. The fermentation broth is diluted so that the difference between the measured values is less than a predetermined value, and methane fermentation is performed.

  Thus, in this embodiment, the electrical conductivity of the slurry adjustment tank is adjusted to a predetermined range, and the methane fermentation is performed by controlling the difference from the electrical conductivity in the methane fermentation tank to be less than the predetermined value. It is characterized by that.

  For example, since organic waste contains salts such as Na, Ca, K, and Mg, these salts are expressed as electrical conductivity. Even if the slurry is unfermented, the electrical conductivity is reduced. Have. However, in the case of organic waste with a change in salt concentration, such as trash that has a change in salt concentration due to the menu, even if the slurry dilution rate is kept constant, the salt concentration is different. Variations in electrical conductivity occur.

  As shown in Fig. 7, the electrical conductivity when the dilution rate is constant is a slurry that uses trash that changes in salt concentration as organic waste, and the numerical values are summarized in Table 3. Show.

  7 and Table 3, even when the dilution rate of the slurry is adjusted to be constant, the electric conductivity at that time has a difference of about 2.3 mS / cm between the maximum value and the minimum value. Therefore, when carrying out the methane fermentation treatment of organic waste from the garbage with salt concentration changes, the ammonia nitrogen concentration in the methane fermentation tank should be controlled only by adjusting the electrical conductivity of the slurry adjustment tank. It is difficult.

  However, by reducing the electrical conductivity in the slurry adjustment tank from the electrical conductivity in the methane fermentation tank, it is possible to eliminate the electrical conductivity value due to the salt component contained in the organic waste from the beginning. Therefore, a highly accurate electric conductivity value having a high correlation with the ammoniacal nitrogen concentration can be obtained. Therefore, a stable methane fermentation treatment state can be obtained by controlling the difference in electrical conductivity to be a predetermined value or less.

  The ammonia nitrogen concentration in the methane fermentation tank 13 is adjusted by diluting the fermentation liquid in the methane fermentation tank 13 so that the difference in electrical conductivity between the slurry adjustment tank 12 and the methane fermentation tank 13 is less than 9 mS / cm. Can be made 1500 mg / L or less, so that stable methane fermentation can be maintained.

  As described above, according to the present invention, when organic waste having a small salt concentration and component change is processed, the electrical conductivity in the slurry adjusting tank is controlled to be within the predetermined value range, In the case of treating organic waste with significant changes in salt concentration and components, by controlling the difference between the electrical conductivity of the methane fermentation tank and the electrical conductivity of the slurry adjustment tank so as not to exceed a predetermined value, The fermentation state in the methane fermentation tank can be constantly maintained stably. In addition, the measurement of the electrical conductivity in this invention may be performed continuously, and may be intermittently performed as needed.

  Hereinafter, the present invention will be described in more detail with reference to examples. In addition, this invention is not limited to a following example.

  In the following examples, a 10-liter fermentor was used as the methane fermenter, and the fermentation temperature was 55 ° C. As an electric conductivity meter, a conductivity meter ES-51 manufactured by HORIBA was used.

Reference example 1
Using the treatment apparatus as shown in FIG. 1, continuous operation was performed by the methane fermentation treatment method shown in the reference example of the present invention .

  As organic waste, municipal waste with little change in composition was used. The paste adjustment organic waste or tap water is put into the slurry adjustment tank so that the electric conductivity of the slurry adjustment tank is 2.5 mS / cm to 3.5 mS / cm, and the electric conductivity of the adjustment tank is adjusted. Adjustments were made. The solid content of the slurry at this time was about 10%.

  FIG. 8 shows the electrical conductivity during operation and the change over time in the ammonia nitrogen concentration of the methane fermenter determined from the ion chromatograph method, and Table 4 summarizes the numerical values.

  From the results shown in FIG. 8 and Table 4, control of the paste supply amount and / or dilution water supply amount to the slurry adjustment tank so that the electrical conductivity of the slurry adjustment tank is 2.5 mS / cm to 3.5 mS / cm. In order to maintain the ammonia nitrogen concentration in the methane fermentation tank at 1500 mg / L or less, which is generally referred to as an inhibition region, by setting the electrical conductivity to 3.5 mS / cm or less, the inside of the methane fermentation tank It was possible to maintain a stable fermentation state.

Example 1
Using the treatment apparatus as shown in FIG. 5, continuous operation was performed using the methane fermentation treatment method of the present invention.

  As organic waste, we used garbage with a marked change in salt concentration. The slurry adjustment tank was adjusted by introducing paste-like organic waste or tap water into the slurry tank so that the electric conductivity of the slurry adjustment tank was 2.5 mS / cm to 3.5 mS / cm.

  In FIG. 9, the electrical conductivity of the slurry adjustment tank adjusted to a predetermined value, the difference in electrical conductivity in the methane fermentation tank, and the time-dependent change of ammoniacal nitrogen in the methane fermentation tank determined from the ion chromatography method, Table 5 summarizes the numerical values.

  From the results of FIG. 9 and Table 5, when the difference in electrical conductivity is 9 mS / cm or less, it can be maintained below 1500 mg / L, and when the difference in electrical conductivity exceeds 9 mS / cm, the concentration of ammoniacal nitrogen Has become 1500 mg / L, which has caused inhibition of methane fermentation, but as a result of circulating the treatment liquid from the waste liquid treatment tank and lowering it to less than 9 mS / cm, the ammoniacal nitrogen concentration can be lowered to less than 1500 mg / L. The fermentation state in the methane fermenter was able to be maintained stably.

  Thereby, even if it is the waste garbage with a remarkable component change, since the ammonia nitrogen concentration in a fermenter can be grasped | ascertained correctly, the stable methane fermentation process can be performed.

  The methane fermentation treatment method of the present invention is suitably used for treating organic waste such as manure, raw garbage, food processing residue and the like.

It is a schematic block diagram which shows one Embodiment of the methane fermentation processing apparatus used by the reference example of this invention. It is a flowchart figure which shows the arithmetic processing and control method by PLC40. It is the graph which calculated | required the correlation of slurry solid content concentration and electrical conductivity. It is the graph which calculated | required the correlation of slurry solid content concentration and ammonia nitrogen concentration. It is a schematic block diagram which shows one Embodiment of the methane fermentation processing apparatus used in the Example of this invention. It is a flowchart figure which shows the arithmetic processing and control method by PLC41. It is the graph which showed the electrical conductivity when the dilution rate of garbage was made constant. It is the graph which measured the time-dependent change of the electrical conductivity in the slurry adjustment tank in Reference Example 1, and the ammonia nitrogen concentration in a methane fermentation tank. It is the graph which measured the time-dependent change of the difference of the electrical conductivity in Example 1 , and the ammonia nitrogen concentration in a methane fermenter.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Crush processing tank 11 Tap water tank 12 Slurry adjustment tank 13 Methane fermentation tank 14 Waste liquid processing tank 20 Paste supply pump 21 Tap water supply solenoid valve 22 Slurry supply pump 23 Slurry extraction pump 24 Treatment liquid circulation supply pump 30, 31 Electrical conductivity 40, 41 PLC (Programmable Logic Controller)

Claims (2)

The paste-like organic waste is slurried in a slurry adjustment tank and put into a methane fermentation tank. After anaerobic microorganisms produce methane by fermenting methane, the fermentation broth is taken out in a waste liquid treatment tank. In the methane fermentation treatment method to be treated,
The electrical conductivity of the slurry adjustment tank is measured, and the organic waste supply amount and / or dilution water supply amount to the slurry adjustment tank is controlled so that the electrical conductivity of the slurry adjustment tank falls within a predetermined range. While measuring the electrical conductivity of the methane fermenter, so that the difference between the electrical conductivity of the methane fermenter and the electrical conductivity of the slurry adjustment tank does not exceed a predetermined value, A method for methane fermentation treatment, characterized in that the dilution water supply amount is controlled . Wherein when the difference in electric conductivity of more than 9 mS / cm, according to claim 1 methane fermentation method according supplying dilution water to the methane fermentation tank.