JP2018122259A - Waste landfill processing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a waste landfill processing method capable of more stably performing semi-aerobic processing than conventional.SOLUTION: A waste landfill processing method performs processing of waste substance semi-aerobically by using a waste landfill processing facility that is provided with: a housing part housing the waste substance; a collection/discharge pipe part capable of discharging leachate from the waste substance housed in the housing part and passing the air; and a plurality of ventilation piping units which are branched from the collection/discharge pipe part and are arranged in the way that an end part protrudes above the waste substance. Density of hydrogen sulfide contained in gases discharged from end parts of the plurality of ventilation piping units is measured respectively, and the air is temporarily fed in the ventilation piping units from the end parts of the ventilation piping units where the density of the measured hydrogen sulfide is equal to reference value or higher.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a waste landfill treatment method.

  Conventionally, of the final landfill sites in Japan, the managed landfill sites and some stable landfill sites have landfilled with waste, and the landfilled waste is applied using the natural purification function and its decomposition mechanism. Aerobic processing methods are used.

  In this type of waste landfill treatment method, for example, it is possible to collect and discharge the storage part formed on the ground so that the waste is stored, and the leachate from the waste stored in the storage part Using a waste landfill treatment facility comprising a central drainage pipe section, and a plurality of ventilation pipe sections branched from the drainage pipe section and having tip portions protruding upward from the waste, The waste is stored in the storage part and processed semi-aerobically. In this case, the landfill process is performed by storing the waste for a relatively long period of time until it reaches the upper end from the bottom surface of the storage unit (see Patent Document 1).

JP 2004-351242 A

However, in the conventional waste landfill treatment method such as Patent Document 1, there is a portion where aerobicity is locally reduced and anaerobic property is improved in the waste, and a ventilation pipe portion passing through this portion. Therefore, hydrogen sulfide may be discharged.
Thus, when the aerobic property in the waste is reduced and hydrogen sulfide is generated, the aerobic property is further lowered and the anaerobic property is improved, and finally methane is generated. When methane starts to be generated, the environmental change from aerobic to anaerobic progresses further. As a result, it becomes difficult to return to an aerobic environment, and it becomes difficult to perform a semi-aerobic treatment stably.

  In view of the above circumstances, an object of the present invention is to provide a waste landfill treatment method that can perform semi-aerobic treatment more stably than in the past.

About the said subject, the present inventors conducted earnest research as follows.
That is, in the semi-aerobic waste landfill process, when the waste is decomposed aerobically, the temperature rises, and the temperature of the waste (that is, the internal environment) is higher than the temperature of the external environment. Thus, a temperature difference occurs between the two. Due to this temperature difference, the air present in the external environment is naturally (not forced) induced into the drainage pipe from the downstream end of the drainage pipe (leaching water outlet), Furthermore, the air that is naturally induced in the ventilation pipe section, and as a result, the air that is induced in the drainage pipe section and the air that is induced in the ventilation pipe section are introduced into the waste, respectively, and the introduced air. Is used for aerobic treatment in waste, and aerobic decomposition treatment proceeds.
When such a semi-aerobic decomposition treatment is functioning well, when the organic matter is decomposed (fermented) in the waste, the temperature of the portion rises, and air is supplied to the ventilation pipe at this portion. Ascending flow is generated, and air is further supplied from below (collection / drainage pipe). When such a relationship is maintained, an upward flow is generated at a location where a large amount of organic matter is present, that is, a location where air is required, so that air is selectively supplied to the location from below.

  However, if there is a lot of organic matter in the waste and the oxygen consumption exceeds the supply amount, the oxygen concentration will decrease at this point, and at the same time, this will be caused by fermentation inhibition accompanying the decrease in oxygen concentration. As a result, the temperature of the portion decreases, and as a result, hydrogen sulfide is generated, and as a result, methane is generated. In this way, the function of the semi-aerobic decomposition process is lowered.

In order to recover the deterioration of the function of the semi-aerobic decomposition process, it is conceivable to send air to a place where air is required, that is, forcibly supply air.
First, the present inventors pay attention to the fact that an air flow from the external environment to the collection / drainage pipe section and further to the ventilation piping section already exists as a method of feeding air, and follows this air flow. Thus, it was considered that air was fed from the downstream end of the drainage pipe part.
However, even if air is supplied from the collection and drainage pipe, it is very expensive to send air to the part of the waste where there is little air. Air is not always supplied to the place where it is done. That is, it is not efficient because the amount of air supplied to a necessary location is small with respect to the amount of air to be fed.

Next, the present inventors considered to send air from the front end portion of the ventilation piping portion so as to reverse the above-described original air flow as a method of sending air.
However, it is not efficient to send air from all the ventilation piping parts because it is very costly and the amount of air supplied to a necessary location is small relative to the amount of air to be sent.

  Therefore, the present inventors have further studied earnestly, capturing signs that the function of the semi-aerobic decomposition treatment is reduced, and supplying a relatively small amount of air to a place where air is required, thereby providing organic matter. It has been found that the above-described fermentation mechanism can be promoted to improve the original mechanism as described above. Furthermore, as an indication, hydrogen sulfide is used as an index, and the concentration of hydrogen sulfide contained in the gas discharged from a plurality of ventilation pipes is measured. On the other hand, it was considered to send air locally into the waste by sending air from its tip.

In this way, the aerobic deterioration is recovered by sending air from the tip of the ventilation pipe part where the concentration of hydrogen sulfide is rising in the direction opposite to the original air flow. As a result, it has been found that the function of the above-mentioned semi-aerobic decomposition treatment can be improved to the original mechanism. Moreover, even if air is not sent continuously from the tip, it is only temporarily sent in air, and even after the air supply is stopped, aerobicity is maintained for much longer than the time when air is supplied. It was found that aerobic treatment can be performed stably.
That is, when the concentration of hydrogenated hydrogen contained in the gas discharged from any one of the ventilation piping parts is higher than the reference value, the tip of the ventilation piping part It has been found that by temporarily sending air into the ventilation pipe section, it is possible to perform semi-aerobic treatment more stably than in the past, and the present invention has been completed.

That is, the waste landfill processing method according to the present invention is:
A storage section for storing waste;
A drainage pipe configured to collect and discharge leachate from the waste housed in the housing section in the lower region and allow air to pass through the upper region. And
Using a waste landfill treatment facility provided with a plurality of ventilation piping parts branched from the drainage pipe part and arranged such that a tip part projects upward from the waste,
A waste landfill processing method for storing the waste in the storage portion and processing the waste semi-aerobically,
The concentration of hydrogen sulfide contained in the gas discharged from the tip portion of the plurality of ventilation pipe portions is measured, and the measured concentration of the hydrogen sulfide is equal to or higher than a reference value. In this method, air is temporarily sent from the tip portion into the ventilation pipe portion.

According to such a configuration, the concentration of hydrogen sulfide contained in the gas discharged from the tips of the plurality of ventilation pipe portions is measured, and the concentration of hydrogen sulfide measured in any of the ventilation piping portions When the air pressure is greater than or equal to the reference value, by temporarily sending air from the tip of the vent pipe to the vent pipe, the air is insufficient in the waste and the aerobic property is reduced. In addition, it is possible to send air locally and efficiently, recover the decrease in aerobicity at this point, and promote aerobic treatment. In addition, even after the air supply is stopped, the aerobic treatment can be stably maintained for a longer time than the time during which the air was supplied.
Therefore, it is possible to perform the semi-aerobic process more stably than in the past.

In the waste landfill treatment method of the above configuration,
The reference value is preferably 2 ppm.

According to such a configuration, when the reference value is 2 ppm, it becomes possible to send air earlier after hydrogen sulfide starts to be generated.
Therefore, it is possible to perform the semi-aerobic process more stably than in the past.

In the waste landfill treatment method of the above configuration,
It is preferable to send air into the ventilation pipe part from the tip part for 1 to 7 hours.

According to such a configuration, it is possible to recover the aerobic decrease and promote the aerobic treatment while the time for sending air is relatively short. Moreover, it is possible to maintain the aerobic treatment for a relatively long time after stopping the air feeding.
Therefore, it is possible to perform the semi-aerobic process more stably than in the past.

  As described above, according to the present invention, there is provided a waste landfill treatment method capable of performing semi-aerobic treatment more stably than in the past.

Schematic side sectional view of waste landfill treatment equipment used in a waste landfill treatment method according to an embodiment of the present invention The top view which shows the downstream edge part of the drainage pipe part of FIG. 1 from the right side of FIG. Schematic side cross-sectional view partially showing the state of measuring the gas discharged from the tip of the ventilation pipe part Schematic side cross-sectional view partially showing a state in which air is fed into the ventilation piping section from the tip of the ventilation piping section Schematic top view showing the measurement location of the waste landfill treatment equipment used in the examples The graph which shows the monitoring result in the point A of FIG. The graph which shows the monitoring result in the point B of FIG. The graph which shows the monitoring result in the point C of FIG.

  Hereinafter, embodiments of the present invention will be described.

The waste landfill treatment method of this embodiment is
A storage section 5 formed on the ground so that waste is stored;
The leachate from the waste 15 accommodated in the accommodating part 5 can be collected and discharged in the lower area, and the collection area is configured such that air can pass through the upper area. Drainage pipe section 13;
Using the waste landfill treatment facility 1 provided with a plurality of ventilation piping parts 14 branched from the drainage pipe part 13 and arranged so that the tip part 14a protrudes above the waste 15;
A waste landfill processing method for storing the waste 15 in the storage unit 5 and processing the waste 15 semi-aerobically,
The concentration of hydrogen sulfide contained in the gas discharged from the distal end portion 14a of the plurality of ventilation pipe portions 14 is measured, and the measured concentration of hydrogen sulfide is equal to or higher than a reference value S. In this method, air is temporarily sent from the tip end portion 14 a of the piping portion 14 into the ventilation piping portion 14.

  First, the waste landfill treatment facility 1 used in the waste landfill treatment method of the present embodiment will be described.

As shown in FIGS. 1 to 4, the waste landfill treatment facility 1 is
A storage section 5 formed on the ground 3 so that the waste 15 is stored;
The leachate 17 from the waste 15 stored in the storage unit 5 can be collected and discharged in the lower region, and air can pass through the upper region. Drainage pipe section 13;
A water collection pit 19 for collecting the leachate 17 discharged from the water collection / drainage pipe section 13;
And a leachate treatment unit 20 for treating the leachate 17 collected in the water collecting pit 19.

The accommodating portion 5 accommodates the waste 15 and is formed in the ground 3 in a concave shape. The accommodating part 5 can be formed in a concave shape by excavation or embankment, for example.
The bottom part of the accommodating part 5 is formed so as to incline from one side to the other. In addition, a drainage pipe portion 13 that extends from the inside to the outside of the housing portion 5 and communicates between the inside and the outside is disposed along the inclination of the bottom surface portion. By arranging the drainage / drainage pipe part 13 in this way, the drainage / drainage pipe part 13 is inclined downward from the inner side to the outer side of the housing part 5. The infused leachate 17 is discharged to the outside from the housing part 5 (see the broken line arrow in FIG. 1).
A water-impervious sheet (not shown) may be disposed on the bottom surface and the side surface of the container 5, and the waste 15 may be configured to contact the bottom surface and the side surface via the water-impervious sheet. .

  On the bottom surface of the storage part 5, a drainage pipe part capable of collecting and discharging leachate 17 from the waste 15 stored in the storage part 5 through the above-described water shielding sheet (not shown). 13 is provided.

  Specifically, the drainage pipe part 13 is formed with a plurality of holes (not shown) through which the leachate 17 can pass from the outside to the inside of the drainage pipe part 13, and leached through the holes. Water 17 is allowed to flow into the drainage pipe section 13. The leachate 17 that has flowed into the drainage pipe section 13 is collected in the lower area of the drainage pipe section 13 and flows into the water collection pit 19 through the lower area (the broken line in FIG. 1). See arrow). On the other hand, as shown in FIG. 2, air flows into the downstream end portion of the drainage pipe portion 13 from the external environment in the catchment pit 19. Part of the air that has flowed into the drainage / drainage pipe 13 flows through the upper region of the drainage / drainage pipe 13 in the direction opposite to the flow direction of the leachate 17 and passes therethrough. The air flowing in the drainage pipe section 13 flows into the waste 15 from the hole of the drainage pipe section 13, and the rest flows into the ventilation pipe section 14 (see solid line arrows in FIG. 1). ).

Further, as described above, the drainage pipe portion 13 is arranged so as to extend from the inside to the outside of the housing portion 5 and to be inclined downward from the inside to the outside. As a result, the leachate 17 that has flowed into the drainage pipe part 13 passes through the drainage pipe part 13 and is discharged to the outside of the housing part 5.
The material and thickness of the drainage pipe section 13 are not particularly limited, but can be set as appropriate according to the weight of the waste 15 to be accommodated.

  The waste landfill treatment facility 1 of the present embodiment may include a crushed stone portion in which crushed stones are arranged so as to surround the drainage pipe portion 13. Such a crushed stone portion can suppress clogging of the hole portion of the drainage pipe portion 13.

As shown in FIGS. 1, 3, and 4, the ventilation piping part 14 branches and extends from the drainage pipe part 13, and the tip part 14 a is a waste housed in the housing part 5. It protrudes above 15 and is arranged so as to be exposed to the external environment.
That is, the ventilation piping part 14 is configured to communicate the drainage pipe part 13 and the external environment, and to allow ventilation between the waste 15 and the external environment.

As the waste 15 is landfilled, the ventilation piping section 14 is lengthened by extension or the like according to the amount of the waste 15. The tip end portion 14 a is always exposed above the waste 15.
The quantity of the piping part 14 for ventilation | gas_flowing is not specifically limited. Moreover, one ventilation piping part 14 may extend from the other ventilation piping part 14.

A plurality of holes are formed in the ventilation pipe portion 14, and the leachate 17 flows into the inside through the holes, and the leachate 17 that has flowed into the drainage pipe portion 13. To flow into. On the other hand, the air that has flowed into the drainage pipe section 13 from the external environment in the water collection pit 19 further flows into the ventilation pipe section 14 and is supplied to the waste 15 through the holes of the ventilation pipe section 14. (See the solid arrow in FIG. 1). Further, the gas generated in the waste 15 flows into the ventilation pipe section 14 and is discharged to the external environment from the tip end section (end on the side opposite to the drainage pipe section 13) 14a of the ventilation pipe section 14. (See the white arrow in FIG. 1).
The material and thickness of the ventilation pipe portion 14 are not particularly limited, but can be appropriately set according to the weight of the waste 15 to be accommodated.

The water collection pit 19 collects and stores the leachate 17 discharged from the water collection / drainage pipe section 13. As the water collecting pit 19, a conventionally known one can be used.
The leachate treatment unit 20 treats the leachate 17 discharged from the drainage pipe unit 13 and collected in the catchment pit 19.
As the leachate treatment unit 20, a conventionally known water treatment device can be used. The treated water treated by the leachate treatment unit 20 is released to the external environment.

  Next, the waste landfill processing method of this embodiment using the waste landfill processing facility 1 will be described.

The waste landfill treatment method of this embodiment is
Using the above-mentioned waste landfill treatment facility 1,
A waste landfill processing method for storing the waste 15 in the storage unit 5 and processing the waste 15 semi-aerobically,
The concentration of hydrogen sulfide contained in the gas discharged from the distal end portion 14a of the plurality of ventilation pipe portions 14 is measured, and the measured concentration of hydrogen sulfide is equal to or higher than a reference value S. In this method, air is temporarily sent from the tip end portion 14 a of the piping portion 14 into the ventilation piping portion 14.

  Here, semi-aerobically treating the waste 15 means that air is naturally induced in the waste 15 from the external environment due to a temperature difference between the waste 15 and the external environment. This means that the waste 15 is aerobically decomposed by the air.

Specifically, first, the transported waste 15 is put into the storage unit 5. After the introduction, the concentration of hydrogen sulfide is measured using the concentration measuring device 31 for the gas discharged from the tip end portion 14 a of each ventilation pipe portion 14.
Examples of the concentration measuring device 31 include devices described in Examples described later.
In addition to the hydrogen sulfide concentration, the concentration measuring device 31 may measure the oxygen concentration and the methane concentration, or measure the gas temperature.

As a result of measuring the concentration of hydrogen sulfide for each ventilation pipe portion 14, when the concentration of hydrogen sulfide is equal to or higher than the reference value S, air is introduced from the tip end portion 14 a into the ventilation piping portion 14 using the air feeding device 33. Send in.
That is, of the plurality of ventilation pipe portions 14, air is fed into the ventilation piping portion 14 from the tip end portion 14 a of the ventilation piping portion whose measured hydrogen sulfide concentration is equal to or higher than the reference value S. .

  The reference value S of the hydrogen sulfide concentration can be appropriately set in consideration of the generation state of hydrogen sulfide, the influence on the aerobic property in the waste 15 and the like. For example, the reference value S is preferably 10 ppm as the volume concentration, more preferably 5 ppm, and even more preferably 2 ppm. That is, when the concentration of hydrogen sulfide is 10 ppm or more, it is preferable to send air from the distal end portion 14a of the ventilation piping portion 14 to the ventilation piping portion 14. When the concentration of hydrogen sulfide is 5 ppm or more, the ventilation piping portion It is more preferable to send air from the tip end portion 14a of the vent pipe 14 to the vent pipe portion 14. When the concentration of hydrogen sulfide is 2 ppm or more, air is sent from the tip end portion 14a of the vent pipe portion 14 to the vent pipe portion 14. More preferably, it is fed.

  As the air feeding device 33, for example, a portable air feeding device can be used. Examples of such a portable air feeding device include a conventionally known portable blower.

The flow rate of the air sent from the distal end portion 14a into the ventilation pipe portion 14 is in consideration of the generation state of hydrogen sulfide, the influence on the aerobic property in the waste 15, the diameter and length of the ventilation pipe portion 14, and the like. It can be set appropriately. For example, the flow rate of the air to be fed can be set to 0.5 to 1.5 m ³ / S.
The time for sending air from the distal end portion 14a into the ventilation piping portion 14 is not particularly limited, and can be set as appropriate. Here, if the time for sending in air is lengthened, the inside of the waste 15 can be made a more aerobic environment, but the workability tends to be lowered.
Therefore, for example, considering this viewpoint, the time for feeding air is preferably 1 to 7 hours, more preferably 2 to 6 hours, and further preferably 3 to 5 hours.
In addition, when sending in air, you may send in air for the said time per day, and this may be performed over several days. In addition, when air is fed in for the above time, air may be blown continuously so that the above time is reached, or air may be intermittently fed so that the total time is reached.

  Thus, by sending air from the front end portion 14a into the ventilation pipe portion 14, the aerobic property of the waste 15 that has been reduced can be recovered, and the aerobic environment is converted to and maintained. Can be made.

  In the present embodiment, when the concentration of hydrogen sulfide contained in the gas discharged from the ventilation pipe portion 14 is equal to or higher than the reference value S, air is fed from the tip end portion 14a of the ventilation pipe portion 14. In addition to this, in addition to this, when the concentration of hydrogen sulfide is less than the reference value S, it is possible to adopt a mode in which air is fed from the tip portion 14a.

Further, in the present embodiment, in addition to the concentration of hydrogen sulfide contained in the gas discharged from the ventilation pipe section 14, the concentration of oxygen is measured. When the concentration of oxygen is equal to or less than the reference value T, the ventilation You may employ | adopt the aspect which sends in air from the front-end | tip part 14a of the piping part 14 for an object.
In this embodiment, the reference value T of oxygen can be set to 10 vol%, for example. That is, when the concentration of oxygen contained in the gas discharged from the ventilation pipe portion 14 is 10 vol% or less, air may be fed from the tip end portion 14 a of the ventilation pipe portion 14.

  In this aspect, for example, when the concentration of hydrogen sulfide contained in the gas discharged from the ventilation piping section 14 is equal to or higher than the reference value S and the oxygen concentration is equal to or lower than the reference value T, the ventilation piping section The air may be fed from the 14 tip portions 14a. Further, for example, when the concentration of hydrogen sulfide contained in the gas discharged from the ventilation pipe portion 14 is less than the reference value S, when the oxygen concentration is equal to or less than the reference value T, the ventilation pipe portion 14 Air may be fed from the tip portion 14a.

As described above, the waste landfill treatment method of the present embodiment is
A storage section 5 formed on the ground so that the waste 15 is stored;
The leachate 17 from the waste 15 stored in the storage unit 5 can be collected and discharged in the lower region, and air can pass through the upper region. Drainage pipe section 13;
Using the waste landfill treatment facility 1 provided with a plurality of ventilation piping parts 14 branched from the drainage pipe part 13 and arranged so that the tip part 14a protrudes above the waste 15;
A waste landfill processing method for storing the waste 15 in the storage unit 5 and processing the waste 15 semi-aerobically,
The concentration of hydrogen sulfide contained in the gas discharged from the distal end portion 14a of the plurality of ventilation pipe portions 14 is measured, and the measured concentration of hydrogen sulfide is equal to or higher than a reference value S. In this method, air is temporarily sent from the tip end portion 14 a of the piping portion into the ventilation piping portion 14.

According to such a configuration, the concentration of hydrogen sulfide contained in the gas discharged from the tip portions 14a of the plurality of ventilation pipe portions 14 is measured, and the measured sulfide is measured in any of the ventilation piping portions 14. When the concentration of hydrogen is equal to or higher than the reference value S, air is insufficient in the waste 15 by temporarily sending air from the distal end portion 14a of the ventilation piping portion 14 into the ventilation piping portion 14. Thus, it is possible to efficiently and locally send air to a location where aerobicity is reduced, to recover the decrease in aerobicity at this location, and to promote aerobic treatment. In addition, even after the air supply is stopped, the aerobic treatment can be stably maintained for a longer time than the time during which the air is supplied.
Therefore, it is possible to perform the semi-aerobic process more stably than in the past.

In the waste landfill treatment method of the present embodiment,
The reference value S is preferably 2 ppm.

According to this configuration, when the reference value S is 2 ppm, it becomes possible to send air earlier after hydrogen sulfide starts to be generated.
Therefore, it is possible to perform the semi-aerobic process more stably than in the past.

In the waste landfill treatment method of the present embodiment,
It is preferable to send air into the ventilation pipe portion 14 from the tip portion 14a for 1 to 7 hours.

According to such a configuration, it is possible to recover the aerobic decrease and promote the aerobic treatment while the time for sending air is relatively short. Moreover, it is possible to maintain the aerobic treatment for a relatively long time after stopping the air feeding.
Therefore, it is possible to perform the semi-aerobic process more stably than in the past.

  As described above, according to this embodiment, there is provided a waste landfill treatment method that can perform semi-aerobic treatment more stably than in the past.

Construction of a waste landfill facility (landfill capacity 470,000 m ³ ) having a storage section having a top view shape as shown in FIG. 5, a drainage pipe section, a water collection pit and a leachate treatment section as shown in FIG. did.
A pipe having an inner diameter of 150 mm was used as the drainage pipe part and the ventilation pipe part.
The ventilation piping portion is arranged so as to be distributed in the entire accommodation portion, and FIG. 5 shows a part of the ventilation piping portion.

  After that, from February 1 to October 28 of the year, it is contained in the gas released from the tip of the ventilation piping section at points A, B, and C among the ventilation piping sections in FIG. The concentration of hydrogen sulfide, the concentration of oxygen, and the concentration of methane were measured, and the temperature of the gas (gas) was measured.

The concentration of hydrogen sulfide, oxygen, and methane was measured at the opening of each ventilation pipe using a portable multi-gas monitor (GX-2012, manufactured by Riken Keiki Co., Ltd.).
The temperature of the gas was measured at the opening of each ventilation pipe using a handy type thermometer (HD-1000 series, manufactured by Anritsu Keiki Co., Ltd.).

When the concentration of hydrogen sulfide is equal to or higher than the reference value S (2 ppm), a portable blower (handy jet HJF-300S, manufactured by Trusco Nakayama Co., Ltd., power supply 100V, power consumption 405W / 560W ( 50/60 Hz)), a portable blower and a ventilation pipe were connected by bellows piping, and air was fed at 60 m ³ / min (60 Hz) for 3 to 4 hours.
The measurement results at points A, B, and C are shown in FIGS. 6, 7, and 8, respectively. Moreover, in FIGS. 6-8, the time of sending in air is shown by "(triangle | delta)" or "□" in each graph.

(Point A)
As shown in FIG. 6, at the point A, when the concentration of hydrogen sulfide is higher than the reference value (2 ppm), when air is sent from the tip part to the ventilation pipe part for 4 hours (March 16), The concentration of hydrogen sulfide decreased below the standard value. Along with this, the oxygen concentration increased, the gas temperature increased, and the methane concentration decreased. As a result, the inside of the waste was converted to an aerobic environment, and after the concentration of hydrogen sulfide fell below the reference value, it was kept below the reference value for about one month.

  After that, although the concentration of hydrogen sulfide repeatedly increased and decreased, it gradually fell below the reference value, and the state below the reference value was stably maintained until October 28th. Along with this, it was found that the increase in the concentration of methane generated from hydrogen sulfide was suppressed and stabilized at 0 LEL%, and the oxygen concentration increased and stabilized at about 20%. As a result, it is presumed that the aerobic environment can be stably maintained by continuing as it is after October 28th.

(Point B)
As shown in FIG. 7, at the point B, when the concentration of hydrogen sulfide is higher than the reference value (2 ppm), when air is sent from the tip part to the ventilation pipe part for 3 hours (March 15), The concentration of hydrogen sulfide decreased below the standard value. Along with this, the oxygen concentration increased, the gas temperature increased, and the methane concentration decreased. As a result, the inside of the waste was converted to an aerobic environment, and after the hydrogen sulfide concentration fell below the reference value, it was kept below the reference value for about two days.

  Thereafter, although the concentration of hydrogen sulfide repeatedly increased and decreased, the frequency of increasing the concentration of hydrogen sulfide tended to decrease. Then, on July 22, when air was sent again for 3 hours, the concentration of hydrogen sulfide decreased, and after the air was sent, it was kept below the reference value for about two weeks.

  Thereafter, although the concentration of hydrogen sulfide repeatedly increased and decreased, the frequency of increasing the concentration of hydrogen sulfide tended to decrease. Then, when air was sent for 5 hours on October 18, the concentration of hydrogen sulfide decreased below the reference value and maintained below the reference value for about 9 days. Thereafter, the increase in hydrogen sulfide until October 28 I was not able to admit.

As described above, it was found that the frequency of increasing the concentration of hydrogen sulfide tends to decrease by repeating the air feeding. As the hydrogen sulfide concentration decreased, the methane concentration also decreased, the gas temperature increased, and the oxygen concentration tended to increase.
As a result, it is speculated that by repeating the air feeding after October 28, the frequency of the increase in the concentration of hydrogen sulfide further decreases, and that the aerobic environment can be stably maintained finally. The

(Point C)
As shown in FIG. 8, at the point C, when the concentration of hydrogen sulfide is higher than the reference value (2 ppm), when air is sent from the tip part to the ventilation pipe part for 3 hours (March 2), The concentration of hydrogen sulfide decreased below the standard value. Along with this, the oxygen concentration increased, the gas temperature increased, and the methane concentration decreased. As a result, the inside of the waste was converted to an aerobic environment, and after the hydrogen sulfide concentration fell below the reference value, it was kept below the reference value for about one week.

  After that, since the concentration of hydrogen sulfide increased, when air was sent again from the tip to the ventilation pipe section for 3 hours (March 19), the concentration of hydrogen sulfide decreased below the reference value, and the concentration of hydrogen sulfide decreased. It fell below the standard value. After the concentration of hydrogen sulfide became below the reference value, it was kept below the reference value for about 2 days.

  Thereafter, although the concentration of hydrogen sulfide repeatedly increased and decreased, the frequency of increasing the concentration of hydrogen sulfide tended to decrease gradually. And when air was sent for 3 hours on July 26, August 2, August 4, and August 19, an increase in the concentration of hydrogen sulfide was suppressed. Furthermore, when air was sent for 3 hours on October 7, the concentration of hydrogen sulfide was kept below the reference value, and then kept below the reference value for about 4 days.

  When this result is combined with the above-mentioned inference regarding the points A and B, the frequency of increasing the concentration of hydrogen sulfide further decreases by repeating the air feeding after October 28, and finally aerobic. It is assumed that a stable environment can be maintained stably. On March 19, air was also sucked in. However, the air sucking did not provide the same effect as when intake air was sent.

As described above, when the concentration of hydrogen sulfide contained in the gas discharged from any one of the ventilation pipe portions arranged at different points is higher than the reference value, the ventilation pipe is used. By sending air from the tip of the piping part to the ventilation piping part, the aerobic deterioration is recovered at the place where the aerobic property inside the waste is reduced, and the aerobic environment is changed to the aerobic environment. I knew I would get.
In addition, although not shown in figure, in the point A, the ground outside the accommodating part is a slope, whereas in the points B and C, the outside of the accommodating part is not a slope, that is, The point A has a relatively small ground thickness separating the external environment and the waste than the points B and C. From this, the amount of oxygen supplied into the waste from the point A is higher than the points B and C, and as a result, the environment is more anaerobic than the points B and C. It is presumed that it has become easier to convert to an aerobic environment.
6-8, there are times when the concentration of hydrogen sulfide is reduced in addition to when air is sent in, but these are improved by the original mechanism of the semi-aerobic decomposition process described above. According to the present invention, it is possible to promote the improvement of the location where air is insufficient due to this original mechanism.

  Although the embodiment of the present invention has been described above, it is also planned from the beginning to combine the features of the embodiment as appropriate. In addition, it should be considered that the embodiments disclosed herein are illustrative and non-restrictive in every respect. The scope of the present invention is shown not by the above-described embodiment but by the scope of claims for patent, and is intended to include all modifications within the meaning and scope equivalent to the scope of claims for patent.

  1: waste landfill treatment equipment, 3: ground, 5: housing part, 13: drainage pipe part, 14: ventilation pipe part, 14a: tip part, 15: waste, 17: leachate, 19: water collection Pit, 20: leachate treatment unit, 31: concentration measuring device, 33: air feeding device

Claims (3)

A storage section for storing waste;
A drainage pipe configured to collect and discharge leachate from the waste housed in the housing section in the lower region and allow air to pass through the upper region. And
Using a waste landfill treatment facility provided with a plurality of ventilation piping parts branched from the drainage pipe part and arranged such that a tip part projects upward from the waste,
A waste landfill processing method for storing the waste in the storage portion and processing the waste semi-aerobically,
The concentration of hydrogen sulfide contained in the gas discharged from the tip portion of the plurality of ventilation pipe portions is measured, and the measured concentration of the hydrogen sulfide is equal to or higher than a reference value. A waste landfill treatment method, wherein air is temporarily sent from the tip portion into the ventilation pipe portion.   The waste landfill treatment method according to claim 1, wherein the reference value is 2 ppm.   The waste landfill processing method according to claim 1 or 2, wherein air is fed into the ventilation pipe portion from the tip portion for 1 to 7 hours.