KR20140059037A - A drying device having variable internal pressure for organic sludge using destruction of cellular walls - Google Patents

Abstract

The present invention relates to a device for drying organic sludge using cell wall destruction and homogenization conditions. More specifically, the present invention relates to a device for drying sludge, comprising: a variable pressure-type dryer that changes a pressure that is applied to sludge and dries the sludge, wherein a supply pipe for supplying the sludge and a discharge pipe for discharging the dried sludge are disposed on one of the side surfaces of the variable pressure-type dryer, respectively and an agitator for agitating the supplied sludge is formed in the variable pressure-type dryer; an air compressor that is connected with one side of the variable pressure-type dryer and pressurizes the inside of the variable pressure-type dryer; a vacuum pump that is connected with one side of the variable pressure-type dryer and depressurizes the inside of the variable pressure-type dryer; and a ventilator that is connected with one side of the variable pressure-type dryer and provides the variable pressure-type dryer with air so as to dry the sludge. The device for drying sludge of the present invention, instead of landfill or ocean disposal, performs ventilation in order to dry organic sludge at low cost, so that the organic sludge can be used as a fertilizer or fuel.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an organic sludge drying apparatus using a transformer drier,

The present invention relates to an organic sludge drying apparatus, and more particularly, to a drying apparatus for drying sludge so as to enable recycling and energy conversion.

Sludge is a generic term for suspended solids in sewage treatment plants, water treatment plants, and factory wastewater treatment facilities. Sewage sludge is narrowly defined as primary sludge, excess sludge, transport sludge, concentrated sludge, and digested sludge. Also included are needlework, screen scum and scum.

The sewage treatment process includes a pretreatment process, a main treatment process, and an advanced treatment process. Sewage sludge is inevitably produced in the process of treating wastewater. In the pretreatment process, raw sludge is generated in the primary settling basin through the infiltration pond and through the infiltration pond. In the main treatment process, activated sludge called so-called microbial bodies is produced in the final settling basin as the final byproduct of the biological treatment process using the microorganisms in the aeration tank. In the final settling basin, some of the total activated sludge is sent to the aeration tank to keep the microbial concentration in the biological treatment process constant. This is called a conveying sludge. If the raw sludge is a primary sludge containing inorganic matter, the activated sludge can be easily understood as an aggregate of microorganisms generated during the processing of the biological treatment process. These sludges are sent to the concentrator, which is a sludge treatment process, and processed through a process of removing water which is a dehydration process. Apart from the dehydration process, it is treated after the reduction in the digester, but the sludge is also generated in the digester. In recent years, policies for promoting energy conversion by sludge generated in a digester have been promoted. However, in some 400 sewage treatment plants in Korea, large-scale reduction of the digesters is possible, but in places where the digesters are not installed, they are processed by heat treatment. In the meantime, the sludge in the sewage treatment plant has been recycled as cement raw materials, landfill materials, compost for agricultural land, and fuel for thermal power plants after drying through the dehydration process mentioned above or after reduction through digestion tank. If recycling or landfilling is difficult due to local characteristics, it is treated by incineration method. Mixed incineration is also allowed when sewage sludge exclusive incinerator and municipal waste incineration facility are available.

Sewage sludge contains 80% of organic matter mainly composed of protein, fat, cellulosic and carbohydrate, and inorganic matter (ash) that can be used as building material. In case of organic matter, calorific value is 5,000kcal / kg, It can be used as an energy source because it is similar to the calorific value, and the inorganic material can be used as materials such as asphalt filler, buried filler, and light aggregate. Conventional sewage sludge was treated mainly by ocean dumping method, but due to recent environmental problems, it is planned to treat the whole land with sewage treatment method.

Conventional sewage sludge disposal apparatus adopts a method of incinerating or drying sewage sludge by using incineration heat of an incinerator such as "Waste and sludge incineration apparatus and incineration method" of Korean Patent No. 10-0733942, Resulting in an economic cost loss due to fuel consumption. Conventionally, sewage sludge is dried and incinerated using the high temperature of the incinerator because the sewage sludge is mostly organic sludge, and the water present in the organic waste is divided into free water and combined water depending on the physical state. This is because it is formed by cell walls of cells forming sludge particles, and dehydration is not easy. That is, the water that can be removed by mechanical dehydration is free water and pore water, and the surface water and the coupling water can not be removed by mechanical dehydration, and the high temperature drying or incineration method is adopted to dry the surface water and the combined water. When drying with a high temperature gas, generally at a speed of 20 to 90 m / s and a temperature range of 100 to 350 ° C. When using a high-speed and high-temperature gas, the contact time of the sewage sludge and gas It is too short to allow absorption and drying, and even in this case, there is a problem that the non-consolidated water is mainly dried.

Accordingly, in Korean Patent No. 10-1172702, Korean Patent No. 10-1172702 discloses a method of separating cell walls and separating cells by a continuous process of high pressure and low pressure by forming a low pressure condition using high pressure air pressure and a vacuum pump by an air compressor, Drying sludge having a moisture content of 10% or less in order to produce an auxiliary fuel, an organic fertilizer, a block, etc. through a cyclone process of drying and solid-liquid separation. However, there is a continuing need to improve the drying performance of the drying apparatus.

Therefore, a problem to be solved by the present invention is to provide a sludge drying apparatus with improved drying performance.

According to an aspect of the present invention, there is provided a sludge treatment apparatus including a sludge supply pipe and a discharge pipe for discharging dried sludge, the sludge supply pipe including a stirrer for stirring the supplied sludge therein, A transformer drier for changing and drying the transformer; An air compressor connected to one side of the transformer dryer for pressurizing the inside of the transformer dryer; A vacuum pump connected to one side of the transformer dryer for reducing the pressure inside the transformer dryer; And a blower connected to one side of the transformer dryer for supplying gas to the transformer dryer for drying the sludge.

According to an embodiment of the present invention, the sludge drying apparatus of the present invention may further include a condenser disposed between the vacuum pump and the transformer dryer for condensing moisture discharged from the transformer dryer.

According to a preferred embodiment of the present invention, the sludge drying apparatus of the present invention is connected to the discharge pipe so that the dried sludge is drawn in, the outlet of the dried sludge is located at the bottom, And a cyclone connected to one side of the transformer drier for re-supplying the fine particles of the sludge.

The present invention is characterized in that a supply pipe for supplying sludge and a discharge pipe for discharging dried sludge are disposed on one side of each other, and a stirrer for stirring the supplied sludge and a heater for heating the sludge are contained therein, A transformer drier for changing and drying; An air compressor connected to one side of the transformer dryer for pressurizing the inside of the transformer dryer; A vacuum pump connected to one side of the transformer dryer for reducing the pressure inside the transformer dryer; And a blower connected to one side of the transformer dryer for supplying gas to the transformer dryer for drying the sludge.

The present invention also provides a method for producing a sludge, comprising the steps of: (S1) pressurizing sludge supplied through a feed pipe to a transformer dryer using an air compressor, and agitating the sludge using an agitator; (S2) depressurizing the pressurized sludge using a vacuum pump and stirring the sludge using an agitator; (S3) stirring the sludge using an agitator while supplying gas to the decompressed sludge using a blower and drying the same; And (S4) discharging the supplied gas by using a vacuum pump.

The present invention relates to a sludge drying apparatus, and it is advantageous in that organic sludge can be used as fertilizer, fuel, etc. by blowing and drying treatment at a low cost without landing or dumping in the sea. In addition, since the existing storage tank and dryer are integrally constructed, the process of transferring the sludge from the storage tank to the drier is omitted, thereby improving the drying efficiency.

In addition, it is possible to repeatedly perform pressurization and depressurization to break organic sludge so that the internal water can be dried only by air blowing at room temperature instead of hot air. The fine particles are conveyed to a dryer through a cyclone, mixed with the dried sludge, .

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate exemplary embodiments of the invention and, together with the description of the invention, It should not be construed as limited.
1 illustrates a sludge drying apparatus according to an embodiment of the present invention.
2 shows a sludge drying apparatus according to an embodiment of the present invention.
FIG. 3 illustrates a sludge drying apparatus according to an embodiment of the present invention.
4 illustrates a sludge drying apparatus according to an embodiment of the present invention.

It is to be understood that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the invention in any way, and the singular forms "a," "an," and "the" include plural referents unless the context clearly dictates otherwise. There are a plurality of embodiments of the present invention, and redundant explanations are omitted in the description.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings, so that those skilled in the art can easily carry out the present invention.

1 illustrates a sludge drying apparatus according to an embodiment of the present invention.

Referring to FIG. 1, the sludge drying apparatus 100 of the present invention includes a supply pipe 11 for supplying sludge and a discharge pipe 12 for discharging dried sludge, A transformer drier (10) including an agitator (13) therein for changing the pressure applied to the sludge and drying the same; An air compressor (20) connected to one side of the transformer dryer and pressing the inside of the transformer dryer; A vacuum pump connected to one side of the transformer dryer for reducing the pressure inside the transformer dryer; And a blower (40) connected to one side of the transformer dryer and supplying gas to the transformer dryer for drying the sludge. The transformer dryer (10) of the present invention is a structure in which a conventional storage tank and a dryer are integrally formed, and the process of transferring the sludge from the storage tank to the drier is omitted, thereby improving the drying efficiency.

The transformer dryer (10) of the present invention includes a supply pipe (11) for supplying sludge and a discharge pipe (12) for discharging dried sludge, and a stirrer (13) for stirring the supplied sludge . Generally, the dehydrated sewage sludge which is generated in the sewage treatment plant and has undergone some dehydration process has a water content of about 80%, and in order to be recycled as fuel, the moisture content should be less than 10%. This sewage sludge is supplied to the interior of the transformer dryer using a supply pipe. Then, the dried sludge is discharged through a discharge pipe.

The inside of the transformer drier is provided with a stirrer 13 for stirring the supplied sludge to uniformly dry the sludge. The type of such an agitator is not particularly limited, but it is preferable to use a generally used impeller. During the pressurization and depressurization process of the transformer dryer, the stirrer operates steadily to stir the sludge. The stirrer serves to homogenize the sewage sludge supplied through the supply pipe with agitation, and to perform not only mixing but also crushing the sludge. In addition, there is a characteristic that the sludge is crushed rapidly because there is no air resistance under the reduced pressure state.

The transformer dryer (10) of the present invention can increase the drying efficiency of the sludge by repeating the pressurization and the carburization. Most of the sewage sludge is organic sludge. The moisture present in the organic sludge is divided into free water and coupled water depending on the physical state, and the water contained in the organic waste is composed of pore water, gap water number, surface adhesion water number and granular water number, It is formed by the cell wall of the forming cells, and dehydration is not easy. Using the transformer dryer of the present invention, which repeatedly pressurizes and decompresses, the cell walls and pore water (binding state of microbes) of the microorganisms are destroyed even at a high temperature, and the internal water of the microorganisms is discharged.

Particularly, in the pressurizing process of the transformer dryer, since the heat generated by the anaerobic reaction of the sludge and the frictional heat due to the continuous stirring can be maintained at a constant temperature without using a separate heating source, energy waste .

The inside of the transformer drier is connected to one side of the transformer dryer and is connected to an air compressor for pressing the interior of the transformer dryer and a vacuum pump connected to one side of the transformer dryer for reducing the pressure inside the transformer dryer . The inside of the transformer drier is stirred by a stirrer while maintaining the inside of the transformer drier at a high pressure (for example, 2 atmospheric pressure or higher) for a predetermined time by the air compressor 20, and thereafter the inside of the transformer drier is reduced to a low pressure The microbial cell wall and pore water (binding state of the cell liquid) may be destroyed, and the internal water of the microorganism may be discharged. (For example, 1,400 mmHg or more) by using an air compressor and the reduced pressure is maintained in a low-pressure state (for example, 360 to 560 mmHg) by using the vacuum pump 30. [

Further, the moisture due to the drying of the sludge can be removed through the exhaust gas discharged under the reduced pressure. Further, in order to efficiently remove water, a condenser may be further provided. Referring to FIG. 2, the condenser 31 is located between the vacuum pump 30 and the transformer dryer 10, and can condense moisture of the exhaust gas discharged to the transformer dryer. The shape of the condenser 31 is not particularly limited, and any type of condenser may be used as long as it has a necessary level of condensing performance.

In addition, the sludge drying apparatus 100 of the present invention includes a blower 40 for supplying gas to the transformer dryer for drying the sludge. The gas can be supplied to the inside of the variable-pressure dryer through the blower 40 to form an impinging air flow, and more preferably, a strong airflow can be formed by using a gas discharge nozzle designed to generate a jet flow . By forming such an impinging air flow, the sludge agitated in the transformer drier can be broken more effectively, and the sludge particles sinking to the lower portion of the transformer dryer are brought into direct contact with the jet stream provided from a gas discharge nozzle (not shown) So that sedimentation of such sludge particles can be prevented.

Further, in order to effectively form an impinging air flow, a gas discharge nozzle may be disposed on a sidewall of the interior of the transformer dryer so as to face upward. A plurality of gas discharge nozzles are disposed in the lower portion of the transformer drier in order to more effectively prevent deposition of particles, and the gas discharge nozzles formed at the lower portion are formed in diagonal directions so as to be directed toward the gas discharge nozzles formed on the side walls, The sludge particles raised in the lower portion of the transformer drier are raised again by the gas discharge nozzles formed on the sidewalls and are continuously circulated in the transformer drier so that the contact area in direct contact with the jet stream is maximized .

In addition, moisture due to drying of the sludge can be removed through the exhaust gas discharged in the drying process by the blower 40. Further, in order to efficiently remove moisture, a condenser 31, which is located between the vacuum pump and the transformer drier, for condensing the exhaust gas discharged to the transformer dryer can be used. The shape of the condenser 31 is not particularly limited, and any type of condenser may be used as long as it has a necessary level of condensing performance.

The dried organic sludge can be converted into fuel after mixing with an additive (waste oil, waste synthetic resin, sawdust, etc.), and can be used as fertilizer without additional additives or with additional nutrients.

According to a preferred embodiment of the present invention, the sludge drying apparatus may further include a cyclone capable of separating the fine particles of the sludge. Referring to FIG. 3, the sludge drying apparatus 300 of the present invention is connected to the discharge pipe 12 to draw the dried sludge, an outlet 52 of the dried sludge is located at a lower portion, The cyclone 50 may further include a transfer tube 51 connected to one side of the transformer dryer 10 to re-supply the dried sludge.

The cyclone 50 is cylindrical in shape and has a hopper shape so that heavy particles are collected and discharged. A discharge port 52 is formed at the lower end of the hopper shape. A conveyance pipe 51 is formed at the upper part of the cylindrical shape, And the sludge differential is returned to the transformer drier 10. A part of the dried sludge which has been drawn into the cyclone 50 from the transformer dryer 10 is conveyed to the transformer dryer 10 through the conveyance pipe 51 and the remaining sludge is discharged to the discharge port 52.

The transformer drier 10 and the conveyance pipe 51 are connected to each other and supplied to the transformer dryer for mixing the sludge dried in the transformer dryer 10 and the dried sludge derivative conveyed from the cyclone 50, The return pipe 51 may be connected to the sludge supply pipe 11. That is, the sludge dried in the transformer dryer 10 is conveyed to the cyclone 50 and passes through a particle separation process. At this time, the dried sludge fine particles are conveyed to the transformer dryer 10 through the conveyance pipe 51, It can be mixed with the sludge in the dryer to increase the drying efficiency. In addition, by returning the fine powder, there is no need for a separate dust treatment facility, and the construction cost can be reduced.

According to a preferred embodiment of the present invention, the sludge drying apparatus may include a heater in the transformer drier to improve drying efficiency.

Referring to FIG. 4, the sludge drying apparatus 400 of the present invention includes a supply pipe 11 for supplying sludge and a discharge pipe 12 for discharging dried sludge, and a stirrer (10) which includes therein a heater (13) for heating the sludge and a heater (15) for heating the sludge, and changes the pressure applied to the sludge to dry it; An air compressor (20) connected to one side of the transformer dryer and pressing the inside of the transformer dryer; A vacuum pump connected to one side of the transformer dryer for reducing the pressure inside the transformer dryer; And a blower (40) connected to one side of the transformer dryer and supplying gas to the transformer dryer for drying the sludge.

In the pressurizing process of the transformer dryer, since the heat generated by the anaerobic reaction of the sludge and the frictional heat due to the continuous stirring can be maintained at a constant temperature without the need of a separate heater, energy waste due to the use of the separate heater Can be reduced. However, it is also possible to use the transformer dryer 10 in which the heater 15, which is used as an auxiliary, is located inside to further increase the drying efficiency. Such a heater 15 is not particularly limited in its form, but may be a heat exchanger type using a heat source or an external heat source. In particular, a heater capable of receiving thermal energy through an oil heater or the like can be used.

According to a preferred embodiment of the present invention, the sludge drying apparatus 400 including the heater is disposed between the vacuum pump 30 and the transformer drier 10, And a condenser 31 for condensing moisture. According to a preferred embodiment of the present invention, the sludge drying apparatus including the heater 15 is connected to the discharge pipe 12 to draw the dried sludge, and the outlet 52 of the dried sludge And a cyclone (50) located at an upper portion of the transfer drum (51) is connected to one side of the transformer dryer (10) to re-supply the fine particles of the dried sludge inside can do.

Hereinafter, a method of drying the sludge using the drying apparatus of the present invention will be described.

First, the sludge supplied to the transformer dryer through a supply pipe is pressurized using an air compressor, and the sludge is stirred using an agitator (step S1).

Generally, the dehydrated sewage sludge which is generated in the sewage treatment plant and has undergone some dehydration process has a water content of about 80%, and in order to be recycled as fuel, the moisture content should be less than 10%. This sewage sludge is supplied to the interior of the transformer dryer using a supply pipe.

The inside of the transformer drier can be agitated by an air compressor while maintaining the inside of the transformer dryer at a high pressure (for example, about 2 atmospheric pressure) for a certain period of time. More specifically, it is preferable to pressurize to a high pressure (for example, 1,400 mmHg or more) using an air compressor.

Thereafter, the pressurized sludge is depressurized using a vacuum pump, and the sludge is stirred using an agitator (step S2).

When the process of stirring the inside of the transformer dryer with a vacuum pump while keeping the inside of the transformer dryer at a low pressure (for example, 0.5 atm) or less for a predetermined time is repeated continuously, the organic sludge, that is, cell walls and pore water Destroyed, and the internal water of the microorganism can be drained. It is preferable that the reduced pressure is maintained at a low pressure state (for example, 360 to 560 mmHg) by using a vacuum pump.

Then, the gas is supplied to the decompressed sludge using a blower and dried, and the sludge is agitated using an agitator (step S3).

In order to effectively form an impinging air flow, a gas discharge nozzle may be disposed on a side wall of the transformer dryer so as to face upward. In order to more effectively prevent precipitation of particles, a plurality of gas discharge nozzles are disposed in the lower portion of the transformer drier, and a gas discharge nozzle formed at the lower portion is formed in a diagonal direction so as to be directed toward the gas discharge nozzle formed on the side wall, And the sludge particles raised in the lower portion of the transformer drier rises again by the gas discharge nozzles formed on the sidewalls so that the structure is continuously circulated in the transformer drier and the contact area in direct contact with the jet stream is maximized can do.

Finally, the supplied gas is discharged using a vacuum pump (step S4).

The moisture due to the drying of the sludge can be removed through the exhaust gas discharged in the drying process. Further, in order to efficiently remove water, a condenser which is located between the vacuum pump and the transformer dryer and condenses the exhaust gas discharged to the transformer dryer can be used. The dried organic sludge can be converted into fuel after mixing with an additive (waste oil, waste synthetic resin, sawdust, etc.), and can be used as fertilizer without additional additives or with additional nutrients.

10: Transformer dryer 11: Sludge supply pipe
12: sludge discharge pipe 13: stirrer
15: heater 20: air compressor
30: Vacuum pump 31: Condenser
40: blower 50: cyclone
51: Return pipe 52:
100, 200, 300, 400: Sludge drying device

Claims (7)

A transformer dryer in which a supply pipe for supplying sludge and a discharge pipe for discharging dried sludge are disposed at one side and a stirrer for agitating the supplied sludge is contained in the sludge;
An air compressor connected to one side of the transformer dryer for pressurizing the inside of the transformer dryer;
A vacuum pump connected to one side of the transformer dryer for reducing the pressure inside the transformer dryer; And
And a blower connected to one side of the transformer dryer for supplying gas to the transformer dryer for drying the sludge. The method according to claim 1,
Further comprising a condenser disposed between the vacuum pump and the transformer dryer for condensing the exhaust gas discharged to the transformer dryer. The method according to claim 1,
The drying sludge is connected to the discharge pipe to draw the dried sludge. The outlet of the dried sludge is located at the lower part. In order to re-supply the dried sludge, The sludge drying apparatus further comprising a cyclone in which the pipe is located at the top. A sludge supply pipe and a discharge pipe for discharging dried sludge are disposed on one side of the sludge tank, respectively, and an agitator for agitating the supplied sludge and a heater for heating the sludge are contained therein, and the pressure applied to the sludge is changed Transforming dryer to dry;
An air compressor connected to one side of the transformer dryer for pressurizing the inside of the transformer dryer;
A vacuum pump connected to one side of the transformer dryer for reducing the pressure inside the transformer dryer; And
And a blower connected to one side of the transformer dryer for supplying gas to the transformer dryer for drying the sludge. 5. The method of claim 4,
Further comprising a condenser disposed between the vacuum pump and the transformer dryer for condensing the exhaust gas discharged to the transformer dryer. 5. The method of claim 4,
The drying sludge is connected to the discharge pipe to draw the dried sludge. The outlet of the dried sludge is located at the lower part. In order to re-supply the dried sludge, The sludge drying apparatus further comprising a cyclone in which the pipe is located at the top. (S1) pressurizing the sludge supplied through the supply pipe to the transformer dryer using an air compressor, and agitating the sludge using an agitator;
(S2) depressurizing the pressurized sludge using a vacuum pump and stirring the sludge using an agitator;
(S3) stirring the sludge using an agitator while supplying gas to the decompressed sludge using a blower and drying the same; And
(S4) discharging the supplied gas using a vacuum pump.

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