JP2003275722A - System and method for treating waste - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a system and a method for treating waste, in which the cost necessary for treating the waste containing organic waste can be reduced remarkably by making the amount of fuel to be supplied from the outside as small as possible. <P>SOLUTION: This waste treating system is provided with a gasification furnace 4 for heat-treating all or a part of the waste 1 containing organic waste and a bio-gas generating apparatus 3 for generating bio-gas by fermenting all or a part of the organic waste. The gas generated from the apparatus 3 can be supplied to the furnace 4 when the waste 1 is heat-treated in the furnace 4. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a waste treatment system and a waste treatment method, and more particularly to a waste treatment system containing organic waste and a waste treatment method capable of reducing the supply of external fuel.

[0002]

2. Description of the Related Art Conventionally, when incinerating waste including organic waste, there is so-called low-calorie waste that requires fuel from the outside depending on the quality of the waste. For incineration of such waste, for example, as shown in FIG. 2, a waste 20 containing low-calorie waste is incinerated or gasified in a furnace 2.
1 and at the same time, fuel (external fuel) 22 such as heavy oil, kerosene, natural gas, etc. is externally supplied and burned, and after making necessary combustion conditions, that is, the furnace outlet exhaust gas temperature above a certain level, This exhaust gas is sent to the boiler equipment 23. Then, it is introduced into the exhaust gas treatment facility 24, detoxified and released into the atmosphere. The steam generated by the boiler equipment 23 is sent to the power generation / waste heat recovery mechanism 25, and is used for power generation, heat recovery for heating, hot water supply, and the like.

Thus, in the waste incineration process,
The treatment facility is designed based on the waste calorie (low calorific value) as the treatment factor. However, since the quality and type of waste are various and inconsistent, the waste collection form, regional characteristics, seasonal fluctuations, etc. It is necessary to set the width of processing in consideration of the fluctuation factors of.

For example, in a general waste treatment facility,
Waste quality can be set separately for three types: low quality, standard, and high quality, and when low quality waste (low calorie waste) increases, external fuel can be supplied for the purpose of completely burning the waste and raising the combustion temperature. In order to achieve this, external fuel burners, etc. are installed in the treatment facility.

[0005]

However, in such a conventional treatment facility, since the external fuel is supplied, a considerable fuel cost must be borne,
In particular, in areas where much low-calorie waste is generated throughout the year, the operation cost is almost always supplied with auxiliary fuel, so that the treatment cost is high. Similarly, in the case of burning waste and using the waste heat to generate power, if external fuel is supplied in order to secure the required amount of heat, the power generation cost will increase, and the treatment in the waste treatment system will increase. The cost could not be reduced so much, and there was a strong demand for improvement.

Therefore, in view of the above problems of the prior art, an object of the present invention is to reduce the supply of external fuel as much as possible when treating wastes including organic wastes, and to significantly reduce the treatment cost. It is to provide a waste treatment system and a waste treatment method that can be reduced.

[0007]

The above objects can be achieved by the inventions described in the claims. That is, the characteristic configuration of the waste treatment system according to the present invention is a heat treatment device that heat-treats all or part of waste containing organic waste, and ferment all or part of the organic waste. And a biogas generator that generates biogas is provided, and the gas generated from the biogas generator can be supplied to the heat treatment device when the heat treatment is performed by the heat treatment device. .

According to this structure, when the waste containing the organic waste with varying properties is treated by the heat treatment apparatus, the biogas is generated from all or part of the organic waste by the biogas generator. As a result, the caloric shortage that occurs as a result of waste treatment by the heat treatment device can be appropriately compensated, and the supply of external fuel can be reliably reduced. It was possible to provide a waste treatment system capable of significantly reducing the treatment cost by reducing the supply of wastewater as much as possible.

Before the heat treatment of the waste, it has a separating mechanism for separating the low-calorie waste and the other wastes according to the property of the waste, and the sorted low-calorie wastes are It is preferably adapted to be fed into a biogas generator.

According to this structure, even when a large amount of waste is treated, it can be efficiently treated by separating it into low-calorie waste and other waste in advance.

It is preferable that either one or both of the gas generated from the heat treatment device and the gas generated from the biogas generation device be fed to an external power source so that the power source can be driven.

According to this structure, an external power source such as a power generator can be effectively used, and the overall processing cost can be reduced, which is convenient. However, when the required amount of heat cannot be secured, all or part of the generated gas may be sent to the gasification furnace.

Further, the characteristic constitution of the waste treatment method according to the present invention is that all or part of the waste containing organic waste is heat-treated and all or part of the organic waste is fermented. When biogas is generated by performing heat treatment with a heat treatment apparatus, the generated biogas is supplied to the heat treatment apparatus.

According to this structure, it is possible to provide a waste treatment method capable of significantly reducing the treatment cost by treating the waste including the organic waste by reducing the supply of the external fuel as much as possible. .

Before the heat treatment of the waste, the waste is separated into low-calorie waste and other wastes according to the properties of the waste, and the selected low-calorie waste is fermented to generate biogas. Is preferred.

It is preferable that either one or both of the gas generated from the heat treatment device and the biogas be supplied to an external power source.

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 shows a schematic overall structure of a waste treatment system according to this embodiment. First, a part or all of the waste 1 containing organic waste (hereinafter, may be simply referred to as waste) is converted into low-calorie waste (mainly garbage) 5 and other waste 6 And the low-calorie waste 5 is fed to the biogas generator 3, and other waste (hereinafter,
The "high-calorie waste" is sometimes charged into the gasification furnace 4, which is one type of heat treatment device for heat-treating and gasifying. The waste quality separation treatment can be performed by, for example, using a sorting device capable of sorting and taking out only high-calorie waste, and sorting it with other waste, but does not particularly require a sorting device. It may be separated in advance at the stage of collecting garbage.

The biogas generator 3 into which the low-calorie waste 5 is put may be either aerobic fermentation or anaerobic fermentation. In the case of the former, it is preferable to install a device for feeding oxygen or air into the fermenter (bioreactor) and to be able to appropriately add aerobic hydrogen-producing bacteria and aerobic methanogenic bacteria. It is characterized by its high speed. When the latter anaerobic fermentation is carried out, there is an advantage that a large-scale device for preventing the emission of odor is not necessary and the equipment cost can be reduced. In this case, it is convenient to load pruned branches of crushed plants into the fermenter because the fermentation is significantly promoted. The fermentation tank may be either vertical or horizontal, and it is preferable to provide a fixed bed for culturing and maintaining the fermentation bacteria in the fermentation tank. Further, a mechanism for stirring the contents in the fermentation tank may be provided, and a heating device such as a heater or a hot water jacket for heating to an appropriate temperature to promote fermentation may be attached.

On the other hand, the high-calorie waste (high-calorie waste 6) from which the low-calorie waste has been removed by separation is crushed to a predetermined size by a crusher (not shown) as necessary, and crushed to be discarded. The product is dried by a dryer (not shown) so that the water content is not more than a predetermined amount. However, a dryer is not particularly necessary, and is used for improving combustion efficiency when gasified, and various conventional dryers can be used. The dried waste is put into a gasification furnace 4, which is one type of gasifier, and is heated and decomposed to be gasified.

Biogas generated from the biogas generator 2 is appropriately charged into the gasification furnace 4 in accordance with the calorific value thereof. In other words, in burning the waste in the gasification furnace 4, although low-calorie wastes have been separated and removed from the waste in advance, variations in the properties of the waste are unavoidable, and the heat generated from the waste is relatively low-calorie. When a certain amount is generated, by introducing an appropriate amount of biogas generated from the biogas generator 3 into the gasification furnace 4, the supply of external fuel can be made unnecessary or insignificant, and the external fuel is originally required. Even if the supply of heat is unnecessary, the amount of heat recovered by the boiler equipment can be increased, and if it is supplied to a gas engine etc.,
This is preferable because heat can be recovered with higher efficiency. The introduction of biogas generated from the biogas generator 3 into the gasification furnace 4 is detected by a temperature sensor or the like installed in the gasification furnace 4 to detect the temperature in the gasification furnace 4 and the like. Correspondingly, the valve operation may be automatically performed, the valve operation may be manually performed, or all the operations may be manually performed.

Of the biogas generated from the biogas generator 3, those other than those introduced into the gasification furnace 4 are introduced into the gas engine 7 for use in the power generator which is one of the external power sources.

The power and exhaust gas obtained from the gas engine 7 are sent to the power generation / waste heat recovery mechanism 8 and used as power for the generator or heat. Gas engine 7
Instead of the above, other power generators such as a gas turbine, a micro gas turbine, and a fuel cell may be used.

The dehydrated residue fermented and dehydrated by the biogas generator 3 may be composted 11 and used as a fertilizer, or may be put into the gasification furnace 4 together with the high-calorie waste 6.

As a specific example, for example, about 45 selected
3 tons of garbage (water content about 64%)
Then, about 5800 Nm ³ / day of biogas was produced and 19.7 t of dehydration residue was obtained. The generated biogas is the gasification furnace 4 along with most of the dehydration residue.
, And some of the dehydrated residue was further dehydrated and used as compost.

Exhaust gas generated by the gasification furnace 4 is used in a boiler facility 9 for power generation or other heat utilization.
Is introduced into and heat exchanged. The steam generated by the boiler equipment 9 is sent to the power generation / waste heat recovery mechanism 8 and is recovered to be used for power generation or for heat use such as heating and hot water supply. The exhaust gas used in the boiler equipment 9 is then introduced into the exhaust gas treatment equipment 10, detoxified and released into the atmosphere.

As described in detail above, according to the waste treatment system of this embodiment, low-calorie waste having a small calorific value is separated and removed, and high-calorie waste having a large calorific value is mainly gasified. As a result, the external fuel introduced into the gasification furnace 3 can be minimized and gasification can be efficiently performed. Therefore, when steam is generated by passing exhaust gas through the boiler facility and the steam is sent to the steam turbine to generate power, a high power generation effect can be exhibited.

[Other Embodiments] The gasifier which can be used in the present invention is not particularly limited, and a stoker furnace,
Kiln type, fluidized bed type, shaft furnace type, gas reforming type and other various gasification and melting furnaces, gasification furnaces, and other various incinerators that can heat and heat waste including organic waste If

[Brief description of drawings]

FIG. 1 is a schematic block diagram of a waste treatment system according to an embodiment of the present invention.

FIG. 2 is a schematic block diagram of a conventional waste treatment system.

[Explanation of symbols]

1 waste 3 Biogas generator 4 Heat treatment equipment 5 Low-calorie waste 6 High calorie waste

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Claims (6)

[Claims] 1. A heat treatment apparatus for heat-treating all or part of waste including organic waste, and a biogas generator for fermenting all or part of the organic waste to generate biogas. A waste treatment system comprising: and a gas generated from the biogas generator when the heat treatment is performed by the heat treatment apparatus. 2. A selected low-calorie waste having a separation mechanism for separating the low-calorie waste from other wastes according to the property of the waste before the waste is heat-treated. The waste treatment system according to claim 1, wherein the waste gas is introduced into the biogas generator. 3. Either or both of the gas generated from the heat treatment device and the gas generated from the biogas generation device are fed to an external power source so that the power source can be driven. 1 or 2 waste treatment system. 4. A heat treatment apparatus which heat-treats all or a part of waste including organic waste and ferments all or a part of the organic waste to generate biogas. The waste treatment method of supplying the generated biogas to the heat treatment apparatus. 5. Before the heat treatment of the waste, the waste is separated into low-calorie waste and other wastes according to the property of the waste, and the selected low-calorie waste is fermented to generate biogas. The waste treatment method according to claim 4, wherein 6. The waste treatment method according to claim 4, wherein either one or both of the gas generated from the heat treatment apparatus and the biogas is fed to an external power source.