KR20190133968A - System of fuel organic and inorganic sludge - Google Patents

Abstract

According to the present invention, a system of converting organic and inorganic sludge (wastewater) into fuel has a double jacket structure to heat a sludge material using a plurality of heat sources and quickly transfer the sludge material so that a moisture content thereof can be lowered. The present invention relates to a hybrid type sludge heating apparatus configured to heat a sludge material so that high temperature gas of an external jacket can be reused as a heat source of an internal jacket. The apparatus comprises: an internal jacket configured to heat a sludge material by making direct contact with the sludge material; and an external jacket installed outside the internal jacket while surrounding the internal jacket, and configured to indirectly heat the sludge material. A communication passage of a first burner for heating the internal jacket is communicated with a discharge unit of high temperature gas (G2) supplied through a second burner installed on the external jacket so that the high temperature gas (G2) is joined with high temperature gas (G1) supplied from the first burner to be fed to the internal jacket.

Description

Fuel system using organic / inorganic (wastewater) sludge {System of fuel organic and inorganic sludge}

The present invention relates to a fuelization system using organic / inorganic (wastewater) sludge. Specifically, the present invention relates to a fuelization system using organic / inorganic (sewage / wastewater) sludge for heating and transporting sludge using a complex structure of an inner cylinder and an outer cylinder.

Waste from residential or industrial areas is fed to high water content sludge, solidified and discharged through drying and heating processes.

Several processes are known for drying and heating the sludge. For example, as shown in FIG. 4, Korean Patent No. 1610926, after preheating the sludge in the transfer screw (10 ') and passes through the jacket 21' of the heating device 20 'and stirred and heated, the second Disclosed is a combined drying apparatus for discharging solidified sludge by subsequent heating in a transfer screw (30 '). The jacket 21 'is a rotary kiln, and the so-called "indirect heating method" is adopted in which the gas supplied through the line 22' heats the outside of the jacket 21 'to heat the sludge. Therefore, the heating device 20 'here can actually be said to belong to a single heating device.

For example, Korean Patent No. 1496704 discloses a hybrid heating method using both inside and outside of a jacket. However, this patent is for drying soils containing contaminants, wherein the soils of low concentrations and low volatilities are heated directly to the inner jacket, and the soils of high concentrations of contaminants are indirectly heated to the outer jacket. The heat source inside and outside the jacket is not used at the same time.

Recently, as the amount of waste sludge generated during the treatment of wastewater in sewage treatment plants and wastewater treatment plants increases rapidly, there is a growing need to develop a hybrid type sludge conveying device capable of rapidly transporting a large amount of sludge. The present invention is devised in this respect.

Therefore, an object of the present invention is to provide a hybrid type sludge conveying apparatus capable of quickly conveying a large amount of sludge while heating, and in particular, can significantly lower the water content.

In order to achieve the above object, the present invention is a hybrid type sludge heating device for heating the sludge material, the device is installed on the outside surrounding the inner jacket and inner jacket for heating the sludge material in direct contact with the sludge material And an outer jacket for indirectly heating, and a communication path of the first burner for heating the inner jacket is in communication with a discharge portion of the hot gas G2 supplied through the second burner installed in the outer jacket so that the hot gas is discharged. The present invention provides a fuelization system using organic / inorganic (sewage / wastewater) sludge, which is joined to the hot gas (G1) supplied from one burner and supplied to an internal jacket.

The discharge portion of the hot gas is installed at the inlet side of the hybrid heating device, the opening and closing of the communication path of the first burner can be controlled by a rotary valve.

Pellets in which the sludge material is solidified may be used as a heat source of the first burner and the second burner.

A plurality of discharge portions of the hot gas may be installed outside the outer jacket, and the discharge portion except for the discharge portion connected to the communication path of the first burner may be closed during driving of the hybrid device.

The sludge material may be supplied with a water content of at least 50% or more, and the water content may be lowered to about 20% by simultaneous combined heating of the inner and outer jackets of the hybrid apparatus.

According to the present invention, since the sludge material is heated while being in direct contact and indirect contact, the water content can be significantly lowered.

According to the present invention, since the hot gas of the outer jacket is utilized as the heat source of the inner jacket, the resource regeneration rate is high and the thermal efficiency is improved.

According to the present invention, since the final pellet of the sludge material is used as a heat source of the burner, it is environmentally friendly and costs can be reduced.

BRIEF DESCRIPTION OF THE DRAWINGS The figure which shows the whole process of the sludge processing system containing the hybrid heating apparatus of this invention.
2 is a side view of the hybrid heating device of the present invention;
3 is a side view showing the gas flow of the apparatus of FIG. 2; And
4 is a side view of the sludge heating apparatus of the prior art.

Some embodiments of the invention will now be described in detail with reference to the accompanying drawings. In adding reference numerals to the elements of each drawing, it should be noted that the same elements are designated by the same reference numerals as much as possible even though they are shown in different drawings. In describing the present embodiment, when it is determined that a detailed description of a related well-known configuration or function may obscure the gist of the present embodiment, the detailed description thereof will be omitted.

In describing the components of the present embodiment, symbols such as first, second, i), ii?), A), and b) may be used. These symbols are only to distinguish the components from other components, and the nature, order or order of the components are not limited by the symbols. In addition, when a part of the specification is said to include or include any component, this means that it may further include other components, except to exclude other components unless expressly stated to the contrary. do. In addition, the term 'connection', 'installation' or 'attachment' in the specification does not only mean direct connection or direct installation or attachment between components, but also includes connection, installation or attachment through indirect or other components. As broadly as possible.

1 is a view showing the entire process of the sludge treatment system 1 including the hybrid heating device 50 of the present invention.

The sludge treatment system 1 includes a hopper-shaped sludge storage unit 10 for receiving and storing sludge and a storage silo 20 for receiving auxiliary material, for example, wood flour. The sludge and the auxiliary material are fermented and dried while passing through the sludge drying and conveying device 30, heated in the hybrid heating device 50 through the conveyor 40 to lower the moisture content, and then collected in the hopper-shaped intermediate storage 60. After passing through the second sludge drying and conveying device 70, the product is naturally dried and cut in the pellet forming machine 80 and discharged into standardized pellets. Auxiliary materials may include non-wood fly ash or inorganic or organic solids.

2 is a side view of the hybrid heating device 50 of the present invention. The sludge material before being introduced into the hybrid heater 50 is in a state of being fermented to some extent. The hybrid heating device 50 of the present invention lowers the water content of the sludge material by utilizing both the inner and outer jackets at the same time.

The hybrid heating device 50 is supported by the stand 800 as a dual structure in which a jacket 520 is formed as an inner jacket 520a constituting an inner cylinder and an outer jacket 520b constituting an outer cylinder. The sludge material falls through the feed hopper 400 and is moved forward by the feed screw 402 to be supplied to the inner jacket 520a.

A motor 522 and a rotating gear 524 connected to the motor 522 by a pulley are installed on an outer surface of the casing of the outer jacket 520b at a central portion of the jacket 520 in a longitudinal direction, and the rotating gear 524 is an inner jacket ( It is connected to the inner jacket 520a via a suspension cable 526 installed around the outer casing of 520a. When the motor 522 rotates, the suspension cable 526, which serves as a pulley by the rotation of the rotary gear 524 is rotated to rotate the inner jacket (520a). Thus, the inner jacket 520a functions like a rotary kiln. The outer jacket 520b does not need to rotate because it is not in direct contact with the sludge material.

Inside the inner jacket 520a, a guide 528 like a blade is formed along the inner surface of the casing in the longitudinal direction. A first burner 600a that provides heat is attached to the front (left side of the drawing) inlet of the inner jacket 520, and the hot gas burned by the first burner 600a passes through the communication path 602a. 520a is supplied inside. A discharge part 630 is installed at a rear (right side of the drawing) exit side of the inner jacket 520, and a lid for opening and closing the gas discharge part 632 and the gas discharge part 632 at an upper part of the discharge part 630 ( 634, a sludge discharge part 636 and a lid 638 for discharging the sludge material are disposed below the discharge part 630. Lids 634 and 638 remain open during operation of hybrid heater 50.

The sludge material is heated by the hot gas while moving rearward (right side of the drawing) along the guide 528 as the inner jacket 520a rotates, and the hot gas is heated through the gas discharge part 632 to solidify the sludge material. Is supplied to the atmospheric hopper 700a through the sludge discharge unit 636. The sludge material moving in the inner jacket 520a is directly contacted and heated by hot gas.

The outer jacket 520b is installed around the entire exterior of the inner jacket 520a, and a second burner 600b for providing heat is attached to the front inlet side, and the hot gas burned by the second burner 600b is in communication. It is supplied into the outer jacket 520b through the furnace 602b. As shown in the figure, three external discharge parts 606a of the hot gas are provided from the left side. The leftmost discharge portion 606a is in communication with the induction pipe 608, and the induction pipe 608 is in communication with the communication path 602a on the inlet side again. A rotary valve 610 for controlling opening and closing of the flow path is installed between the discharge part 606a and the induction pipe 608. During operation of the hybrid heater 50, the rotary valve 610 is set to ON so that the discharge part 606a and the induction pipe 608 at the left end communicate with each other, and the remaining two discharge parts 606a are closed.

Hereinafter, the hot gas flow of the jacket 520 will be described with reference to FIG. 3.

When the hybrid heating device 50 is operated, as described above, the hot gas G1 of the inner jacket 520a is discharged to the outside through the gas discharge part 632 while heating the sludge material. In addition, the hot gas G2 of the outer jacket 520b gathers into the discharge part 606a at the left end, which is the only outlet, while indirectly heating the sludge material indirectly, and enters the communication path 602a to join the hot gas G1. It is used as a heat source for heating by direct contact with sludge material. Since the hot gas G2 is regenerated and utilized without being discharged to the outside through the other two discharge units 606a, the thermal efficiency can be greatly improved.

On the other hand, as a heat source of the first burner 600a and the second burner 600b, liquefied gas or coal, which is a solid raw material having a high calorific value, may be used. However, in the present invention, the pellet cut by the pellet molding machine 80 is burned. It is desirable to recycle as a heat source. By recycling sludge as fuel, eco-friendly green system can be saved while reducing costs.

After the driving of the hybrid heating device 50 is finished, the flow path is closed by the rotary valve 610, and the remaining two discharge parts 606a are opened to discharge the hot gas G2 to the outside.

Reference numeral 604 is a mounting table for firmly mounting the outer jacket (520b) to the stand (800).

Applicants' test showed that by applying the hybrid heating device 50, the water content of the sludge material could be drastically lowered from 50 to 60% to 20% at the time of introduction. Since the sludge material is subsequently passed through the second sludge drying and conveying device 70, the water content is further lowered and discharged into the solid pellets, so that the sludge material can be used as a heat source of the hybrid heating device 50 of the present invention as described above. .

Although the preferred embodiment of the present invention has been described above, the present invention may be modified in various ways, for example, by arranging a return path of the inner jacket 520a of the hot gas G2 at the inlet side instead of the inlet side.

Although the embodiments of the present invention have been described as an example, they do not limit the scope of the present invention, and various changes or modifications may be made to the present invention, and these also belong to the scope of the present invention. The scope of the invention extends to the same or equivalent area as the claims described below.

(1): sludge treatment system 50: hybrid heating device (520a): inner jacket (520b): outer jacket (600a): first burner (600b): second burner (606a): discharge section

Claims (5)

A hybrid type sludge heater for heating sludge material, the apparatus includes an inner jacket for heating the sludge material in direct contact with the inner jacket and an outer jacket installed outside the inner jacket and indirectly heating the sludge material. The communication path of the first burner that heats the jacket communicates with the discharge portion of the hot gas G2 supplied through the second burner installed in the outer jacket so that the hot gas G2 is supplied from the first burner ( A fueling system using organic / inorganic (sewage / wastewater) sludge that is joined to G1) and supplied to the inner jacket.
The organic / inorganic (sewage / wastewater) according to claim 1, wherein the discharge portion of the hot gas G2 is provided at an inlet side of the hybrid heating device, and the opening and closing of the first burner through the communication path is controlled by a rotary valve. Fuel system using sludge.
The fueling system using organic / inorganic (sewage / wastewater) sludge according to claim 2, wherein pellets in which sludge material is solidified are used as heat sources of the first burner and the second burner.
The organic / inorganic composition of claim 2, wherein a plurality of discharge portions of the hot gas G2 are installed outside the outer jacket, and the discharge portions except for the discharge portion connected to the communication path of the first burner are closed during operation of the hybrid device. (Sewage / wastewater) Fuel system using sludge.
5. The organic and inorganic material according to claim 4, wherein the sludge material is supplied with a water content of at least 50% or more, and the water content is lowered to about 20% by simultaneous combined heating of the inner and outer jackets of the hybrid apparatus. Sewage / wastewater) sludge fuelization system.

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