JPH11347594A - Method and system for treating sludge - Google Patents

Abstract

PROBLEM TO BE SOLVED: To simplify constitution and to improve overall energy efficiency by methane-fermenting sludge discharged from an excrement treating facility, dewatering an obtained residue is and drying the dewatered residue by indirect heating in a vacuum state to a desired water content. SOLUTION: Garbage and sludge after excrement treatment are methane- fermented in a methane fermentation apparatus 1. Next, the residue is dewatered/indirectly dried by a dewaterer 2 and an indirect drier 3 so that the water content is made a prescribed value. After that, the dewatered residue is molded by a molding apparatus 4 into RDF or fermented into compost by a compost apparatus 5, besides, methane obtained by methane fermentation is supplied to a cogeneration system 6 in order to obtain electric power and steam. The indirect drier 3 is constituted from a vacuum drier main body, a vacuum pump, a condenser, a receiver tank, and others. The dewatered residue is dried by indirect heating in a vacuum state.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a sludge treatment method and a sludge treatment system. More specifically, the present invention relates to an improvement in a sludge treatment method involving methane fermentation and a sludge treatment system.

[0002]

2. Description of the Related Art Conventionally, as shown in FIG. 4, a mixture of sludge from a night soil treatment facility and kitchen garbage such as garbage is subjected to methane fermentation, and the water content of the residue is adjusted. ) And that has been done. In addition,
In FIG. 4, reference symbol a denotes a methane fermentation device, reference symbol b denotes a dehydration device,
Symbol c indicates a dryer, symbol d indicates a molding device, symbol e indicates a composting device, and symbol f indicates a human waste treatment facility.

[0003] In the case of producing compost, it is necessary to reduce the water content of a residue after methane fermentation having a water content of 90% or more to about 60% by adjusting the water content. Conventionally, the water content is adjusted by dehydrating and drying the residue after methane fermentation, or by mixing an organic dry matter such as sawdust and bran with the residue after dehydration (dehydrated cake).

However, in the former method of dewatering and drying, since drying is often performed by a hot air rotary dryer c, it is difficult to adjust the water content after drying to about 60%. . Therefore, a part of the residue is over-dried, and the over-dried residue and the residue after dehydration are mixed to adjust the water content. Therefore, there is a problem that the manufacturing process is complicated. In addition, since high-quality fuel such as kerosene or gas is consumed for generating hot air in the hot-air rotary dryer c and the exhaust gas is treated, the total energy efficiency is reduced and the running cost is increased. There is also the problem of being invited. In addition, even if high-quality fuels such as kerosene and gas are used, in areas where regulations are strict, higher-level exhaust gas treatment must be performed, which leads to complications of facilities and further increases in running costs. is there.

[0005] On the other hand, in the latter method of adjusting the moisture content of the residue by mixing an organic dry matter with the residue after dehydration, the location conditions for the convenience of the procurement and storage of the organic dry matter are limited. There is also a problem that it is restricted and the equipment becomes large. In addition, there is also a problem that since organic dry matter is mixed into the residue, running costs are increased.

As shown in FIG. 5, "New Energy Utilization Technology—Toward Utilization of Unused Energy" published in the March 1992 special issue of "Energy Conservation (Issued by the Energy Conservation Center)" As a method of dewatering the residue, a multiple effect can evaporation method has been proposed. However,
In this method, there is a problem that the configuration of the system becomes complicated because heavy oil is mixed in the residue in order to secure the fluidity of the residue.

[0007]

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems in the prior art, and has a simplified structure and improved total energy efficiency and a sludge treatment system. It is intended to provide.

[0008]

A first aspect of the present invention is a method for treating sludge discharged from night soil treatment equipment, in which a residue obtained by subjecting sludge to methane fermentation is dewatered, and the dewatered residue is then dewatered. The present invention relates to a sludge treatment method characterized by drying by indirect heating in a vacuum state to obtain a desired moisture content.

A second aspect of the present invention is a method for treating sludge discharged from night soil treatment equipment, wherein garbage such as garbage is mixed into the sludge, and the sludge mixed with the garbage such as garbage is converted into methane. Fermentation, dehydrate the residue after methane fermentation,
Next, the present invention relates to a sludge treatment method characterized by drying the dehydrated residue by indirect heating in a vacuum state to obtain a desired moisture content.

In the first and second embodiments of the present invention, methane obtained by methane fermentation is used as fuel for a cogeneration system, and steam obtained from the cogeneration system is used as a heat source for indirect heating. It is preferable to use it, to form a dehydration residue having a desired moisture content to form a solid fuel, or to ferment the dehydration residue having a desired moisture content to obtain a compost.

According to a third aspect of the present invention, there is provided a sludge treatment system for subjecting sludge discharged from night soil treatment equipment to methane fermentation and dewatering and drying the residue, comprising a vacuum drying means of an indirect heating system, wherein the vacuum drying means is provided. The present invention relates to a sludge treatment system characterized in that dehydration residue is dried by the method.

A fourth embodiment of the present invention is directed to a sludge treatment system for subjecting a mixture of sludge discharged from night soil treatment equipment and kitchen waste such as garbage to methane fermentation and dehydrating and drying the residue, wherein a vacuum of an indirect heating method is used. The present invention relates to a sludge treatment system comprising a drying means, wherein the dehydration residue is dried by the vacuum drying means.

According to the third and fourth embodiments of the present invention, there is provided a molding means for molding a dehydrated residue after drying to obtain a solid fuel, or a fermentation of the dehydrated residue after drying to obtain a compost. It is preferable to include a composting means.

In the third and fourth embodiments of the present invention, a cogeneration system is provided, wherein methane obtained by the methane fermentation is used as fuel for the cogeneration system, and It is also preferable to use the steam obtained by the system as a heat source for the vacuum drying means.

Further, in the third and fourth embodiments of the present invention, the vacuum drying means is a water-cooled cooling means for cooling water vapor generated by evaporating water in the dehydration residue while drying the dehydration residue. It is preferable that a drain generated by cooling the water vapor by the water-cooled cooling means is used as makeup water for cooling water of the water-cooled cooling means, and the vacuum drying means is a microwave heating means. Is preferred.

[0016]

The sludge treatment method and the sludge treatment system of the present invention are configured as described above, so that the residue after methane fermentation can be dried at a desired moisture content. Therefore, when producing a solid fuel from the residue, the production of the solid fuel is performed smoothly and the quality is improved.
Also, when compost is produced from the residue, the production is performed smoothly and the quality is improved.

[0017]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described based on embodiments with reference to the accompanying drawings, but the present invention is not limited to only such embodiments.

Embodiment 1 FIG. 1 is a block diagram showing Embodiment 1 of a sludge treatment system S to which a sludge treatment method of the present invention is applied. In this sludge treatment system S, as shown in FIG. 1, kitchen waste such as garbage and sludge after human waste treatment are subjected to methane fermentation in a methane fermentation device 1, and the residue is removed by a dehydration device 2 and an indirect dryer 3. After dehydration and indirect drying to set the water content to a predetermined value, the residue (dehydration residue) is formed into RDF by molding with a molding device 4 or fermented into compost by a composting device (composting device) 5. On the other hand, methane obtained by methane fermentation is supplied to the cogeneration system 6 to obtain electric power and steam. Then, the obtained electric power is used for power in the office, and the steam is collected in the steam header 7 and then sent to, for example, the methane fermentation apparatus 1 or the indirect dryer 3 to be used as a heat source thereof.

Since the methane fermentation apparatus 1, dehydration apparatus 2, molding apparatus 4, composting apparatus 5, and cogeneration system 6 are the same as those conventionally known, detailed description thereof is omitted. Hereinafter, the indirect dryer 3, specifically, the indirect dryer 30 using steam heating will be described.

As shown in FIG. 2, the indirect dryer 30 includes a vacuum dryer main body 31, a vacuum pump VP, and a condenser 32 for cooling water vapor discharged from the vacuum dryer main body 31.
And a receiver tank 33 for storing water vapor liquefied by the condenser 32, that is, drain (water), and a drain pump for feeding the water stored in the receiver tank 33 to a waste water treatment device 34 for removing harmful components and the like in the drain. P
_2, a cooling tower 35 for cooling the cooling water of the condenser 32, the cooling water pump P _4, dispensing apparatus for cutting out quantitatively by storing the dehydrated residue from dewatering device 2 (e.g., rotary valve) lower section 36a , And a conveyor 37 for transporting the dehydrated residue quantitatively cut out from the raw material hopper 36 to the vacuum dryer main body 31 as main components.

The vacuum dryer main body 31 has a substantially cylindrical body 31b whose both ends are closed by lid members 31a.
A steam jacket 31c mounted on the outside of the body 31b, and a hollow shaft 31e having both ends rotatably mounted on the lid member 31a and having a suitably shaped agitating member 31d at a position located inside the body 31b. Dehydration residue inlet 31g provided at the center of the upper part of the body 31b, dehydration residue outlet 31h provided at the center of the lower part of the body 31b, and exhaust provided at the upper end of the body 31b. And a mouth 31i.

A steam line 11 from the steam header 7 is connected to a steam inlet (not clearly shown) of the steam jacket 31c and a steam inlet (not clearly shown) of the hollow shaft 31e. Heating steam is supplied to the steam jacket 31c and the hollow shaft 31e (see FIG. 2), and the supplied steam indirectly heats the dehydration residue supplied from the raw material hopper 36 to the inside of the drum 31b via the conveyor 37. Also, a steam (drain) outlet (not clearly shown) of the steam jacket 31c and a steam (drain) outlet of the hollow shaft 31e,
Drain line 12 having a drain pump P ₁ in communication with the water supply tank cogeneration system 6 (not shown) is connected. Then, the steam that has been drained after the indirect heating by the drain pump P ₁ is collected in the water supply tank of the cogeneration system 6.

On the other hand, the moisture in the dehydration residue released as steam from the dehydration residue heated indirectly in the vacuum dryer main body 31 is discharged from the vacuum dryer main body 31 through the exhaust port 31i, and one end is connected to the exhaust port 31i. It is supplied to the condenser 32 by a communication duct which is connected and the other end is connected to the inlet of the condenser 32. The temperature of the steam supplied to the condenser 32 is measured by a thermocouple thermometer T provided in the communication duct.

The water vapor supplied to the condenser 32 is cooled by the condenser 32 and becomes a drain. The drain is fed to and stored in the receiver tank 33 by a communication pipe having one end connected to the outlet of the condenser 32 and the other end connected to the inlet of the receiver tank 33. The drain stored in the receiver tank 33 has a drain pipe 33 provided with a drain pump P ₂ having one end connected to the receiver tank 33 and the other end connected to a waste water treatment device 34.
a to the wastewater treatment device 34. The drain treated by the wastewater treatment device 34 is used as makeup water for the cooling water of the condenser 32 that is evaporated and lost in the cooling tower 35. That is, the wastewater treatment device 34
Treated drainage is supplied to the suction side of the cooling water pump P ₄ of the cooling water pipe 32a by makeup water pump P ₂ by. Therefore, the amount of wastewater discharged from the wastewater treatment facility 34 to the outside is almost nil. If excess drain still occurs, the excess drain is sent to the human waste treatment facility 8.

The receiver tank 33 has an exhaust pipe 33 having one end connected to the suction side of the vacuum pump VP.
The other end of b is connected. As a result, the vacuum dryer main body 31 is connected to the vacuum pump VP.
Therefore, by appropriately adjusting the suction force of the vacuum pump VP, the inside of the vacuum dryer main body 31 can be set to a desired degree of vacuum.

The gas in the vacuum dryer main body 31 sucked by the vacuum pump VP is deodorized by the exhaust pipe 33c having one end connected to the exhaust side of the vacuum pump VP and the other end connected to the deodorizer 38. And is deodorized by the deodorizing device 38 and released to the atmosphere. In this case, most of the gas discharged from the inside of the vacuum dryer body 31 when the dehydration residue is dried is water vapor in which moisture in the dehydration residue is vaporized, and most of the water vapor is drained by the condenser 32. Therefore, the amount of exhaust gas to be treated is very small. Therefore, the deodorizing device 38
Since the size is reduced, the running cost can be reduced.

Next, the drying process in the sludge treatment system S having such a configuration will be described. The following processes are performed according to instructions from a central control device (not shown).

(1) The dewatering residue is supplied from the dewatering device 2 to the raw material hopper 36.

(2) The raw material hopper 36 quantitatively cuts out the dehydrated residue on the conveyor 37 by the quantitative supply device 36a mounted at the lower end.

(3) The steam from the steam header 7 is supplied to the steam jacket 31c and the hollow shaft 31e, and the conveyor 37 conveys and supplies the dewatered residue to the heated vacuum dryer main body 31. The dehydration residue is supplied to the vacuum dryer main body 31 through a dehydration residue input port 31g.

(4) The raw material hopper 36 is
When a predetermined amount of the dehydrated residue is supplied to 1, the supply is stopped.

(5) The lid for the dewatering residue input port 31g is covered, and stirring of the dehydration residue in the vacuum dryer main body 31 by the stirring device 31f is started.

(6) The vacuum pump VP is operated while stirring the dehydration residue, and the inside of the vacuum dryer main body 31 is set to a predetermined degree of vacuum.

(7) The temperature of the exhaust gas (water vapor) is measured by a thermocouple thermometer T provided in the communication duct.

(8) When the value measured by the thermocouple thermometer T becomes stable, it is determined that predetermined drying has been achieved, and the operation of the vacuum pump VP is stopped.

(9) The dewatering residue discharge port 31h of the vacuum dryer main body 31 is opened to discharge the dehydration residue having a predetermined water content.

The residue whose water content is set to a predetermined value is formed by the forming device 4 into RDF (solid fuel) or composted by the composting device 5.

As described above, according to the first embodiment,
Since the moisture content of the residue is set to a predetermined value, the molding in the molding device 4 can be performed smoothly, or the production of compost in the composting device 5 can be easily performed, and the quality thereof is improved. Therefore, the operation rate and productivity of the sludge treatment system S are improved. In addition, since the steam used for drying is obtained by burning the methane obtained by the sludge treatment system S, there is no need to burn high-quality fuel such as kerosene from the outside, and the running cost is significantly reduced. .

Further, since the drying is performed by indirect heating, the gas discharged from the vacuum dryer main body 31 is almost the water vapor of the moisture in the dehydration residue, and the water vapor is collected as drain by the condenser 32. Therefore, the amount of gas substantially discharged from the dryer 3 is reduced to about 1/100 as compared with that of the conventional hot-air rotary dryer. Therefore, the processing apparatus for the gas containing the odor component discharged from the dryer 3, for example, the deodorizing device 38 is downsized, and the running cost is significantly reduced. That is, productivity and energy efficiency in the dryer 3 are significantly improved.

Further, in the first embodiment, methane obtained by sludge treatment is used as fuel for the cogeneration system 6 to obtain electric power and steam, and the power and utility in the sludge treatment system S are thereby obtained. Because of the steam, energy efficiency is significantly improved.

Second Embodiment FIG. 3 is a block diagram of a main part of a sludge treatment system S according to a second embodiment of the present invention. The second embodiment is a modification of the first embodiment, in which a microwave generator (microwave heating means) 31k is provided in the indirect dryer 30, and the radio wave energy from the microwave generator 31k is heated. The energy is converted into energy to improve the drying speed. The remaining configuration of the second embodiment is the same as that of the first embodiment.

As described above, in the second embodiment, the indirect dryer 30 is provided with the microwave generator 31k, and the radio wave energy generated therefrom is converted into heat energy to improve the drying speed. The drying time can be reduced and the size of the vacuum dryer main body 31 can be reduced.

As described above, the present invention has been described based on the embodiments. However, the present invention is not limited to only such embodiments, and various modifications are possible. For example, in the present embodiment, methane is supplied to the cogeneration system, but the supply destination of methane is not limited to the cogeneration system. For example, power generation having a boiler and a back pressure turbine It may be equipment. Further, in the embodiment, methane fermentation is performed by mixing kitchen waste such as garbage with sludge discharged from night soil treatment equipment, but methane fermentation can be performed using only sludge discharged from night soil treatment equipment. Good.

[0044]

As described above, according to the present invention, the following excellent effects can be obtained.

(1) Since the heating steam and the required power are obtained by burning the methane obtained by the sludge treatment system of the present invention, the running cost of the sludge treatment system can be significantly reduced.

(2) Since the inside of the vacuum dryer main body is set to a desired degree of vacuum and the dehydration residue is dried by indirect heating using steam, desired drying can be performed while preventing burning and ignition of the dehydration residue. . In addition, since there is almost no variation in the water content of the dewatered residue after drying, it is possible to smoothly perform molding in a molding apparatus and to obtain compost with stable quality. As a result, the operation rate and productivity of the sludge treatment system are improved.

(3) Since the drying is performed by indirect heating, most of the gas discharged from the vacuum dryer main body is steam in which moisture in the dehydration residue is vaporized, and the steam is collected as drain by a condenser. So
The amount of gas substantially discharged from the dryer is reduced to about 1/100 as compared with that from the conventional hot air rotary dryer. Therefore, the processing apparatus for the gas containing the odor component discharged from the dryer is reduced in size, and the running cost is significantly reduced. That is, productivity and energy efficiency of the dryer are significantly improved.

(4) The methane obtained by the sludge treatment is used as fuel for the cogeneration system, and the required power is covered by the electric power from the cogeneration system, and the required steam is supplied by the steam from the cogeneration system. According to the preferred embodiment, the energy efficiency of the sludge treatment system is significantly improved.

[Brief description of the drawings]

FIG. 1 is a block diagram of an embodiment of a sludge treatment system of the present invention.

FIG. 2 is a schematic diagram of an example of an indirect dryer used in the processing system.

FIG. 3 is a schematic view of another example of the indirect dryer used in the processing system.

FIG. 4 is a block diagram of a conventional sludge treatment system.

FIG. 5 is a block diagram of a sludge treatment system proposed for energy saving.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Methane fermentation apparatus 2 Dehydration apparatus 3 Indirect dryer 30 Indirect dryer by steam heating 4 Molding apparatus 5 Compost apparatus 6 Cogeneration system 7 Steam header 8 Human waste treatment equipment S Sludge treatment system

Claims (13)

[Claims] 1. A method for treating sludge discharged from night soil treatment equipment, comprising: dehydrating a residue obtained by subjecting sludge to methane fermentation; drying the dehydrated residue by indirect heating in a vacuum state; A sludge treatment method characterized by a content ratio. 2. A method for treating sludge discharged from night soil treatment equipment, comprising mixing garbage such as garbage into sludge and subjecting the sludge mixed with garbage such as garbage to methane fermentation.
A sludge treatment method comprising dewatering the residue after the methane fermentation and then drying the dehydrated residue by indirect heating in a vacuum to obtain a desired water content. 3. The method according to claim 1, wherein methane obtained by methane fermentation is used as a fuel for a cogeneration system, and steam obtained from the cogeneration system is used as a heat source for indirect heating. 2. The method for treating sludge according to 2. 4. The sludge treatment method according to claim 1, wherein the dewatered residue having a desired water content is formed into a solid fuel. 5. The compost obtained by fermenting a dehydrated residue having a desired water content to produce a compost.
The sludge treatment method described in the above. 6. A sludge treatment system for subjecting sludge discharged from a human waste treatment facility to methane fermentation and dewatering and drying the residue, comprising a vacuum drying means of an indirect heating method, wherein drying of the dehydrated residue is performed by the vacuum drying means. A sludge treatment system characterized by being made. 7. A sludge treatment system for subjecting a mixture of sludge discharged from night soil treatment equipment and kitchen waste such as garbage to methane fermentation, and dehydrating and drying the residue, comprising a vacuum drying means of an indirect heating method, A sludge treatment system, wherein the dehydration residue is dried by the vacuum drying means. 8. The sludge treatment system according to claim 6, further comprising forming means for forming a dewatered residue after drying to obtain a solid fuel. 9. The sludge treatment system according to claim 6, further comprising composting means for fermenting the dehydrated residue after drying to make compost. 10. A cogeneration system, wherein methane obtained by said methane fermentation is used as fuel for said cogeneration system, and steam obtained by said cogeneration system is used as a heat source for said vacuum drying means. The sludge treatment system according to claim 6, wherein the sludge treatment system is used. 11. A vacuum drying means, comprising: a water-cooled cooling means for cooling water vapor generated by evaporating water in the dewatered residue while drying the dewatered residue; The sludge treatment system according to claim 6 or 7, wherein the drain generated by cooling is used as makeup water for cooling water of the water cooling type cooling means. 12. The sludge treatment system according to claim 6, wherein the vacuum drying means includes a microwave heating means. 13. A solid fuel or compost obtained from a dehydrated residue dried by indirect heating in a vacuum.