KR100835964B1 - A sludge dry system using waste heat of from power generator - Google Patents

Abstract

A sludge drying system using waste heat of a cogenerator, comprising a sludge digester, a gas storage tank, a sludge dryer, a sludge dewaterer, a sludge transfer part, a cogenerator, a waste heat guide pipe, and an exhaust pipe, is provided to reduce drying cost of sludge and treat the sludge effectively at the same time by utilizing waste heat generated from a cogenerator for producing electricity. A sludge drying system using waste heat of a cogenerator comprises a sludge digester(10), a gas storage tank(20), a sludge dryer(30), a sludge dewaterer(40), a sludge transfer part(50), a cogenerator(60), a waste heat guide pipe(70), and an exhaust pipe(80), wherein the sludge dryer includes: a body having an injection port formed in a front side thereof to inject sludge into the body through the injection port, and a discharge port formed in a rear side thereof to discharge sludge from the body through the discharge port; a drying chamber which is spaced from an inner wall of the body and communicates with the injection port and the discharge port; an agitation screw installed in the drying chamber; a motor for rotating the agitation screw; a space part formed between the body and the drying chamber; and a plurality of holes formed in an inner wall of the drying chamber. The space part has the waste heat guide pipe communicated with a front side thereof, and the exhaust pipe communicated with a backside thereof. The sludge drying system further comprises a filter unit(90) for removing non-burnt gas and harmful gas contained in the digestion gas.

Description

A sludge dry system using waste heat of from power generator

The present invention relates to a sludge drying method using waste heat of a cogeneration generator.

Cogeneration was originally started in northern Europe, supplying enormous waste heat from thermal power plants as heating heat in the surrounding area. Recently, cogeneration has been used for power generation and heating in many countries. Such cogeneration is increasing in energy efficiency by using waste heat remaining after generating electricity, and thus its use is increasing.

On the other hand, the wastewater treatment plant purifies the wastewater generated at home and industrial complexes, and huge sludge is generated in this process. These sludges are transferred to other sites from wastewater treatment plants and then disposed of by incineration or landfill.

However, since the sludge generated in the wastewater treatment plant contains a lot of moisture, it has to be removed from the sludge in order to be transferred to another place. To this end, a hot air type sludge drying method for applying hot air to dry sludge has been introduced. However, enormous energy was consumed in the process of producing hot air, thereby resulting in excessive sludge treatment costs.

In particular, organic sludge in the sludge has high viscosity and strong water retention, making it difficult to remove moisture even by a hot air drying method. In addition, digestion gas is generated in the process of decomposing organic sludge by microorganisms, and since the digestion gas is highly flammable, a process of separately burning and extinguishing digestion gas was required, which in turn caused an increase in the sludge treatment cost. There was a problem.

The present invention was created in order to solve the above problems, and an object of the present invention is to provide a sludge drying system using waste heat of a cogeneration generator that can effectively treat sludge at a low cost by using waste heat generated from a cogeneration generator. do.

In order to achieve the above object, the sludge drying system using the waste heat of the cogeneration generator according to the present invention, by using the digestion gas generated as a byproduct in the process of refining the sludge as the fuel of the cogeneration generator, the sludge treatment cost more effectively It is to provide a sludge drying system using the waste heat of the cogeneration generator can be lowered.

In order to achieve the above object, the sludge drying system using the waste heat of the cogeneration generator according to the present invention, which is operated in conjunction with the waste water treatment plant, decomposes the transported sludge by microorganisms and at the same time generates digestive gas as a by-product. Sludge digestion tank 10; A gas storage tank 20 for storing the digested gas generated in the sludge digestion tank 10; A sludge dryer (30) for drying the introduced sludge; A sludge dehydrator 40 for dewatering the sludge via the sludge digester 10; A sludge feeder (50) for transferring the sludge dewatered from the sludge dehydrator (40) to the sludge dryer (30); A cogeneration generator (60) for generating electricity while simultaneously generating electricity by being driven by inflowing fuel or extinguishing gas stored in the gas storage tank (20); A waste heat guide tube (70) for guiding waste heat generated by the cogeneration generator (60) to the sludge dryer (30); And an exhaust pipe (80) for exhausting the waste heat via the sludge dryer (30).
The sludge dryer 30 includes: a main body 31 formed with an inlet 31a through which sludge is introduced in the front and an outlet 31b through which sludge dried at the rear is discharged; A drying chamber 32 installed to be spaced apart from an inner wall of the main body 31 and communicating with each of the inlets 31a and the outlets 31b; A stirring screw 33 installed in the drying chamber 32; A motor 34 for rotating the stirring screw 33; A space portion 36 formed between the main body 31 and the drying chamber 32; And a plurality of holes 32a formed in the inner wall of the drying chamber 32 and communicating with the space 36.
The front of the space 36 is in communication with the waste heat guide tube 70, the rear of the space 36 is characterized in that it is in communication with the exhaust pipe (80). At this time, further includes a filter unit 90 for removing the non-combustible gas and harmful gas contained in the extinguishing gas.

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The sludge drying system using the waste heat of the cogeneration generator according to the present invention uses waste heat generated by the cogeneration generator that generates electricity, thereby reducing the drying cost of the sludge and effectively treating the sludge. There is.

Hereinafter, a sludge drying system using waste heat of a cogeneration generator according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram of a sludge drying system using waste heat of the cogeneration generator according to the present invention, Figure 2 is a schematic configuration diagram of the sludge dryer of FIG.

The sludge drying system using the waste heat of the cogeneration generator according to the present invention is operated in conjunction with the wastewater treatment plant, for this purpose is installed in or near the wastewater treatment plant.

Sludge drying system using the waste heat of the cogeneration unit, as shown, sludge digestion tank 10 for decomposing the transported sludge by the microorganism and generates digestive gas as a by-product; A gas storage tank 20 for storing the digested gas generated in the sludge digestion tank 10; A sludge dryer 30 for drying the introduced sludge; A sludge dehydrator 40 for dewatering the sludge via the sludge digester 10; A sludge conveying unit 50 for transferring the sludge dewatered from the sludge dehydrator 40 to the sludge dryer 30; A cogeneration generator 60 that generates electricity while simultaneously generating electricity by being driven by the ingested gas stored in the fuel or gas storage tank 20 that is introduced; A waste heat guide pipe (70) for guiding the waste heat generated by the cogeneration generator (60) to the sludge dryer (30); An exhaust pipe (80) for exhausting the waste heat via the sludge dryer (30); It includes; and a filter unit 90 for removing the non-combustion gas and harmful gas contained in the digestion gas.

In the wastewater treatment plant, a sedimentation basin and a hydraulic pump station, a distribution tank, an initial settler, an aeration tank, a final settler, a sludge concentration tank, and an outlet are installed to purify the incoming wastewater. In this wastewater treatment plant, sludge generated during the purification of wastewater is concentrated in the sludge concentration tank.

The sludge digestion tank 10 is one or two or more sludges, and is a place for stabilizing and reducing the sludge flowing from the sludge concentration tank by gasification, liquefaction, and inorganicization under the action of anaerobic or aerobic microorganisms. In this embodiment, the sludge digestion tank has been described as an example of being composed of two sludge primary digestion tanks and a sludge secondary digestion tank.

The gas storage tank 20 is a tank for storing the digested gas generated in the sludge digestion tank 10. The digested gas is once stored in the gas storage tank 20 and then supplied to the cogeneration plant and used as a fuel source. That is, the digestion gas is generated in the process of decomposing the organic sludge by the microorganism, the digestion gas is stored in the gas storage tank (20).

On the other hand, the extinguishing gas generated in the sludge digestion tank 10 has a composition containing 60 to 70% of methane and 30 to 40% of carbon dioxide and other nitrogen, hydrogen and hydrogen sulfide. At this time, the digestion gas, sulfuric acid gas, moisture, traces of harmful substances are contained, and the pollution load is high, so when used without purification, the calorific value is low, the toxicity is strong and severe odor is generated. Furthermore, it strongly corrodes iron, zinc, copper, etc. to corrode the mechanism of the cogeneration machine. Based on this problem, the sludge digestion tank 10 or the gas storage tank 20 is provided with a filter unit 90 for removing non-combusted gas and harmful gas contained in the extinguishing gas. By employing such a filter unit 90 can be stored in the gas storage tank 20 while effectively removing the harmful gases and non-combustion gas contained in the extinguishing gas. The filter unit 90 may be implemented in various forms. For example, the filter unit 90 may be implemented with activated carbon having a plurality of pores formed therein.

The sludge dryer 30 is for drying the sludge by waste heat guided through the waste heat guide pipe 70. The sludge dryer 30 may be implemented in various ways, for example, a main body 31 having an inlet 31a through which sludge is introduced in the front and an outlet 31b through which the sludge dried out is discharged; A drying chamber 32 installed to be spaced apart from the inner wall of the main body 31 and communicating with each of the inlets 31a and the outlets 31b; A stirring screw 33 installed in the drying chamber 32; A motor 34 for rotating the stirring screw 33; It may include a chain 35 for transmitting the rotational force of the motor 34 to the stirring screw 33. At this time, the space portion 36 is formed between the main body 31 and the drying chamber 32, and a plurality of holes 32a communicating with the space portion 36 are formed in the inner wall of the drying chamber 32. And the front of the space 36 is in communication with the waste heat guide pipe 70, the rear of the space 36 is in communication with the exhaust pipe (80).

The sludge dehydrator 40 is a device for reducing the amount of water contained by dewatering sludge decomposed by microorganisms in the sludge digestion tank 10. By passing through such sludge dehydrator 40, sludge turns into cake form.

The sludge conveying unit 50 is for conveying the sludge in the form of cake conveyed by the sludge dehydrator 40 to the sludge dryer (30). The sludge conveying unit 50 may be implemented in various forms, for example, it may be implemented as a conveyor belt, or may be implemented in a screw embedded structure along the pipe.

The cogeneration generator 60 includes a generator for generating electricity from digestive gas stored in the gas storage tank 20 and primary energy such as petroleum, coal, and natural gas, an engine for driving the generator, and an engine generated from the engine. And a waste heat recovery portion for recovering heat. The electricity generated from the cogeneration generator 60 is supplied to Korea Electric Power, or used as an electric source in the wastewater treatment plant, and the heat recovered from the waste heat recovery unit is transferred to the sludge dryer 30 through the waste heat guide pipe 70 to be sludge. It is used to dry it.

The waste heat guide pipe 70 is for guiding heat generated in the cogeneration generator to the sludge dryer 30, and the exhaust pipe 80 is for exhausting waste heat used for drying the sludge in the sludge dryer 30 to the outside. . The waste heat guide pipe 70 and the exhaust pipe 80 is installed in front and rear of the sludge dryer 30.

By the above structure, the sludge generated in the process of purifying the wastewater from the wastewater treatment plant is precipitated in the final settler and then concentrated in the sludge concentration tank and transferred to the sludge digestion tank 10. Since sludge is digested by the action of anaerobic or aerobic microorganisms in the sludge digestion tank 10, the digestion gas is generated, the digested gas is purified in the filter unit 90 and then transferred to the gas storage tank 20 and stored. The digested sludge decomposed is transferred to the sludge dehydrator 40 and then dehydrated in the sludge dehydrator 40 to form a cake. The cake-type sludge is transferred to the sludge dryer 30 via the sludge conveying part 50.

Meanwhile, the digestion gas stored in the gas storage tank 20 is transferred to the cogeneration generator 60 and used as an energy source. The cogeneration generator 60 generates electricity by 400 to 650 degrees after generating electricity. Huge waste heat is generated.

This waste heat is delivered to the sludge dryer 30 via the waste heat guide pipe 70. Then, the sludge introduced into the sludge dryer 30 is dried by the waste heat (high heat) transmitted from the cogeneration generator 60, and thus the amount of sludge is drastically reduced. That is, in the present application, since the digestion gas generated during the treatment of the sludge is used as an energy source of the cogeneration generator 60, and the waste heat generated by the cogeneration generator 60 is used to dry the sludge in the sludge dryer 30, As in the related art, energy for driving the cogeneration generator 60 can be saved, and further, a device for generating hot air or energy for producing hot air can be saved.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom.

1 is a block diagram of a sludge drying system using the waste heat of the cogeneration generator according to the present invention,

Figure 2 is a schematic diagram of the sludge dryer of Figure 1;

<Description of the symbols for the main parts of the drawings>

10 ... sludge digester 20 ... gas storage tank

30 ... sludge dryer 31 ... body

31a ... inlet 31b ... outlet

32 ... drying chamber 32a ... hole

33 ... stirring screw 34 ... motor

35 ... chain 36 ... space

40 ... sludge dehydrator 50 ... sludge feeder

60 ... Cogeneration Generator 70 ... Waste Heat Guide Tube

80 ... exhaust pipe 90 ... filter unit

Claims (3)

It works in conjunction with wastewater treatment plants, A sludge digestion tank 10 which decomposes the transported sludge by the microorganism and generates digestion gas as a by-product; A gas storage tank 20 for storing the digested gas generated in the sludge digestion tank 10; A sludge dryer (30) for drying the introduced sludge; A sludge dehydrator 40 for dewatering the sludge via the sludge digester 10; A sludge feeder (50) for transferring the sludge dewatered from the sludge dehydrator (40) to the sludge dryer (30); A cogeneration generator (60) for generating electricity while simultaneously generating electricity by being driven by inflowing fuel or extinguishing gas stored in the gas storage tank (20); A waste heat guide tube (70) for guiding waste heat generated by the cogeneration generator (60) to the sludge dryer (30); And an exhaust pipe (80) for exhausting the waste heat via the sludge dryer (30).  The sludge dryer 30, A main body 31 in which an inlet 31a for injecting sludge is formed in the front and an outlet 31b for discharging the dried sludge in the rear; A drying chamber 32 installed to be spaced apart from an inner wall of the main body 31 and communicating with each of the inlets 31a and the outlets 31b; A stirring screw 33 installed in the drying chamber 32; A motor 34 for rotating the stirring screw 33; A space portion 36 formed between the main body 31 and the drying chamber 32; And a plurality of holes 32a formed in the inner wall of the drying chamber 32 and communicating with the space 36. The front of the space portion 36 is in communication with the waste heat guide pipe (70), the rear of the space portion 36 is the sludge drying system using the waste heat of the cogeneration generator, characterized in that the communication with the exhaust pipe (80). The method of claim 1, Sludge drying system using the waste heat of the cogeneration generator, characterized in that it further comprises a filter unit (90) for removing the non-combustion gas and harmful gas contained in the extinguishing gas. delete

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