KR20050102986A - Sludge drying system - Google Patents

Abstract

The base frame, a hot plate installed on the base frame and formed of a material having high thermal conductivity, so that the drying can be carried out in a short time and the sludge is transported in a state separated into small lumps to greatly increase the drying efficiency. A heating device installed at the bottom and heating the hot plate at a high temperature, a conveying device formed to have a height of 5 to 20 mm while being circulated in contact with the upper surface of the hot plate and having a plurality of spaces, and rotatably installed at the base frame. At least one brush device installed on the upper surface of the transfer device to be in contact with the brush member, a heat insulation wall installed to wrap at a predetermined distance from the base frame, an inlet is formed on one side, and an outlet is formed on the other side, A pair of pressing rollers formed by pressing the sludge installed and supplied at the inlet to form a thin sheet shape. Sludge drying system including a hopper to which the hopper is installed, an exhaust guide installed at the outlet of the insulation wall, an exhaust pipe installed at the upper portion of the insulation wall and exhausting air having high humidity inside, and a ventilation fan installed at the exhaust pipe. To provide.

Description

Sludge Drying System

The present invention relates to a sludge drying system, and more particularly, sludge is directly contacted with a hot plate heated to a high temperature to dry in a short time, and a sludge capable of maintaining the size of the sludge dry matter below a certain size using a manganese conveyor. It relates to a drying system.

In general, household sewage discharged from households, wastewater discharged from livestock farms or factories, etc. are treated in sewage treatment plants to make sludge. This sewage sludge or wastewater sludge (hereinafter referred to as "sludge") contains a large amount of water and is disposed of by landfilling or the like.

However, when landfill or sludge is landfilled, there is a danger of causing soil pollution and marine pollution, and environmental problems are raised. Since sludge contains a large amount of water, the unit weight is heavy, and thus a lot of energy and cost are required to transport the landfill to landfill. There is a problem that this takes. In addition, negotiations are underway to ban marine dumping internationally and plans to gradually ban marine dumping and land reclamation in Korea.

Therefore, in recent years, various applications have been studied such as dehydration and drying of water contained in sludge to reduce unit weight and volume to facilitate transportation, or to produce fertilizers or building materials using dried sludge dried material.

Conventionally, a method of drying the sludge includes a hot air drying method of blowing hot air into a sludge that moves hot air and a conductive heat drying method of drying the sludge in contact with a heated surface.

In the conductive heat drying method, a trap and agitating shaft and a blade are installed in a cylinder, and a cylindrical stirring dryer is dried while the sludge is in contact with them, and two kinds of disks of different sizes are arranged in the cylinder, and a stirring blade is installed on a rotating shaft in the center. By using the disk dryer to move the sludge outwards from the small disk side outwards and to the inner side of the large disk one by one, and to move it down sequentially, and to dry the sludge on the heated and rotating drum, and then scrape off with a scraper. do.

 In the conductive heat drying method, the viscous and sticky materials are dried by the flocculant included in the sludge, so that the sludge agglomerates to form agglomerates and is not easy to dry inside. In addition, as the sludge is dried, the shaft, the blade, the inner surface of the cylinder, the drum surface, etc. are attached to the sludge conveying path is narrowed, the operation is not smooth and there is a problem that causes the failure.

When the sludge is attached to the shaft or wings, it is very cumbersome to remove the work, and since the equipment must be completely disassembled and cleaned, it consumes a lot of time and manpower.

Korean Unexamined Patent Publication No. 2003-97163 and No. 10-395119 propose a hot air drying method as a method for solving the above problems.

The planar mobile hot air drying furnace of Korean Patent Laid-Open Publication No. 2003-97163 is configured to spray hot air while continuously transporting sludge using a conveyor belt installed in multiple stages, and has a plurality of vertical blades having guide vanes and hot air jet nozzles on the conveyor belt. A connecting pipe is formed in which the rod is formed in the transverse direction of the conveyor belt.

In addition, the sewage and wastewater sludge drying apparatus of Korean Patent Publication No. 10-395119 is formed into a plate-type sludge sheet by using a sludge supplied through a hopper, and the sludge sheet is formed into a bundle of noodles and dropped into gravity. It is configured to break the strands into small grains, and blow dry the hot air while transporting the mesh belt.

Since the conventional hot air drying method is configured to dry the sludge by applying a high temperature dry hot air, it is difficult to supply while maintaining the temperature of the hot air at 300 ℃ or more, the drying of the sludge is not sufficiently made, the drying time takes a long time, drying It is very difficult to keep the water content of the sludge below 20%.

In particular, even when the sludge is formed by feeding the sludge into the form of a noodle bundle or stirring the sludge to be transported by installing the guide vane, as the drying proceeds, the sludge aggregates to form a large mass, and there is a high possibility that the mass is not dried at all.

In addition, when sludge is transported using a mesh belt made of a metal plate with a plurality of holes perforated to pass hot air, the sludge debris may fall through the hole and contaminate the inside of the facility. It's a hassle to do it often.

An object of the present invention is to solve the above problems, by directly contacting a thin sheet-like sludge to a hot plate heated to a high temperature to dry in a short time and in a state in which the sludge is separated into small chunks using a network conveyor It is to provide a sludge drying system that greatly increased the drying efficiency by transferring.

The sludge drying system proposed by the present invention includes a base frame, a hot plate installed on the base frame and formed of a material having high thermal conductivity, a heating device installed under the hot plate and heating the hot plate at a high temperature, and the hot plate. The transfer device is formed to have a height of about 5 to 20 mm and circulates in contact with the upper surface of the transport device, and is formed to be rotatable on the base frame and installed to contact the brush member on the upper surface of the transport device. It consists of one or more brush devices.

The heating apparatus may be configured by using a heating wire that is heated as power is supplied. The heating apparatus may be configured to burn a gas or fuel to heat it, or may use a heat medium.

The conveying apparatus is formed by using a network conveyor, and a plurality of spiral members formed by spirally winding a metal wire between the planes positioned at predetermined intervals (height), and wave the metal wires to connect the spiral members to each other. It consists of a plurality of connecting members formed in a shape.

And the sludge drying system of the present invention is installed so as to wrap at a predetermined interval from the base frame, the insulator is formed on one side and the outlet is formed on the other side, the hopper is installed at the inlet of the insulation wall, and It further comprises a discharge guide installed at the outlet of the insulating wall.

The hopper is provided with a pair of pressing rollers formed by pressing the sludge supplied to form a thin sheet.

In addition, an exhaust pipe for discharging air having high humidity is installed at an upper portion of the heat insulation wall, and a ventilation fan is installed at the exhaust pipe.

Next, a preferred embodiment of the sludge drying system according to the present invention will be described in detail with reference to the drawings.

First, one embodiment of the sludge drying system according to the present invention, as shown in Figures 1 to 3, the base plate 10, the hot plate 30 is installed on the base frame 10 and formed of a high thermal conductivity material ), A heating device 32 installed below the hot plate 30 and heating the hot plate 30 to a high temperature, and circulating in a state of being in contact with the upper surface of the hot plate 30. At least one conveying device 22 formed to have a height and a plurality of spaces and rotatably installed on the base frame 10 and installed to contact the brush member 27 on the upper surface of the conveying device 22. It comprises a brush device 26.

As shown in FIG. 3, the base frame 10 includes a pair of horizontal frames 14 having the hot plates 30 installed on both sides of the base plate 30 in a length direction of the hot plates 30, and the horizontal frames 14. ) And a plurality of vertical frames 12 supporting a predetermined height.

Although not shown in the drawings, the pair of horizontal frames 14 are provided with a plurality of connection members connected to each other and integrally supported.

As shown in FIGS. 4 and 5, the heating device 32 is configured using a heating wire 25 that generates heat as power is supplied.

The heating device 32 has a case 33 fixedly installed on the base frame 10 and / or the hot plate 30, and a groove provided in the case 33 and for installing the heating wire 25 is formed. And a heat ray support member 34 formed of a material such as a ceramic having heat resistance and insulation.

In the case 33, a fixing hole 36 for fastening bolts or screws for fixing to the base frame 10 and / or the hot plate 30 is formed at a predetermined position.

The heating device 32 is installed over the entire length of the hot plate 30, it is also possible to install the heating device 32 by dividing the hot plate 30 into a plurality of zones.

As shown in Fig. 8, the heating device 32 may be configured by using a nozzle 38 for injecting a gas or fuel such as natural gas (LNG) or liquefied petroleum gas (LPG). That is, the heating device 32 is configured to burn the gas or fuel from the lower surface of the hot plate 30 while injecting the gas or fuel through the nozzle 38 to directly heat the hot plate 30 to a predetermined temperature by the heat of combustion. It is also possible.

Although the heating device 32 is not shown in the drawing, it is also possible to configure the heating plate 30 to be heated to a predetermined temperature by using various heat mediums heated at a high temperature.

The heating device 32 is configured to heat the temperature of the hot plate 30 to a high temperature of about 700 ℃ or more, preferably the temperature of the hot plate 30 is configured to maintain a high temperature of about 700 ~ 1,000 ℃ range Good to do.

When the temperature of the hot plate 30 is lower than 700 ℃ in the above, the drying speed of the sludge takes a lot of processing time, the length of the hot plate 30 is long, the overall size of the equipment is inefficient, it is inefficient, There is not enough drying to the inside of the sludge.

The hot plate 30 uses a metal plate made of a material such as copper (copper plate) and titanium having excellent thermal conductivity and heat resistance at high temperature.

The transfer device 22 is made using a network conveyor or the like.

As shown in FIGS. 6 and 7, the conveying apparatus 22 includes a plurality of spiral members 23 formed by spirally winding metal wires between planes positioned at predetermined intervals (height), and the spirals. It consists of a plurality of connecting members 24 for forming a metal wire in a wavy shape to connect the members 23 to each other.

The spiral member 23 is preferably formed by setting the height H of the upper and lower surfaces to about 5 to 20 mm.

In the case where the height H of the spiral member 23 is formed to be less than 5 mm, there is a fear that the sludge dry matter 74 in which drying proceeds moves over the spiral member 23 to the adjacent space. When the sludge dry matter 74 is moved together, they form a larger mass by agglomerating by cohesive force, and there is a possibility that drying to the inside is not sufficiently performed.

In addition, when the height H of the spiral member 23 is larger than 20 mm, the size (diameter) of the sludge dry matter 74 is increased to 20 mm or more, and drying to the inside is not sufficiently performed.

Since the transfer device 22 moves in contact with or close to the upper surface of the hot plate 30, it is preferable to form the material having excellent wear resistance and heat resistance.

In addition, the transfer device 22 is preferably formed of a material having excellent thermal conductivity so as to be easily heated to a high temperature by the heat of the hot plate 30.

As shown in FIG. 3, the conveying apparatus 22 includes a plurality of conveying rollers 40 rotatably supported through a bearing or the like on the horizontal frame 14 and / or the vertical frame 12 of the base frame 10. By circular motion.

One of the feed rollers 40 is provided with a driven sprocket 41 and the chain 44 is connected to the driven sprocket 43 and the driven sprocket 41 installed in the drive motor 42 so that rotation is performed. Configure.

In the above, the rotational force of the driving motor 42 is described as being transmitted to the feed roller 40 using the chain 44. However, the present invention is not limited thereto, and the rotational force may be transmitted using a belt or a gear. Do.

The vertical frame 12 is provided with a support bracket 16 for supporting the shaft of the feed roller 40 as needed. The support bracket 16 is provided with a bearing (not shown) for rotatably supporting the shaft of the feed roller 40.

In the above, the transfer device 22 has been described as cyclically moving through the transfer roller 40. However, the present invention is not limited thereto, and may be configured to circulately move using a gear or a sprocket.

As shown in FIG. 3, the brush device 26 is rotatably supported by a bearing or the like on a support bracket 18 installed on the horizontal frame 14 of the base frame 10.

The brush device 26 is installed to rotate in the same direction as the conveying direction of the conveying device 22 by a motor 28 installed in the base frame 10. That is, the motor 28 is installed on the support bracket 19 installed on the base frame 10, and the brush device 26 is rotated by using power transmission means such as a chain and a sprocket.

The brush device 26 may be installed to rotate in the opposite direction to the conveying direction of the conveying device 22.

The base frame 10 is provided with a fixing bracket 19 to which the motor 28 is installed.

In the above description, all the brush devices 26 are rotated using one motor 26. However, the present invention is not limited thereto, and each brush device 26 is provided with a motor 28, respectively. In addition, it is possible to configure to rotate by using the rotational force of the drive motor 42 to which the transfer device 22 is connected.

The brush device 26 is provided with a plurality of brush members 27 along the circumference of the shaft, the brush member 27 is formed using a heat-resistant wire brush or the like.

The sole member 27 may be provided in the entire circumference of the shaft, or may be provided in the longitudinal direction at a predetermined interval (divided in the circumference).

And one embodiment of the sludge drying system according to the invention is installed to wrap at a predetermined interval from the base frame 10, as shown in Figure 1 and 2, the inlet is formed on one side and the outlet on the other It further comprises a heat insulating wall (2) formed, a hopper (3) installed at the inlet of the heat insulating wall (2), and a discharge guide (4) provided at the outlet of the heat insulating wall (2).

The inlet in which the hopper 3 is provided in the said heat insulation wall 2 is formed in the upper surface of one side in the longitudinal direction, and the outlet is formed in the side surface of the longitudinal direction opposite to the said hopper 3 provided.

The hopper 3 is provided with a pair of pressing rollers 20 for pressing the sludge 70 to be supplied to form a thin sheet shape.

The pressing roller 20 is installed so that the interval t through which the sludge 70 passes is maintained in a range of about 5 to 20 mm.

The interval t of the pressing roller 20 is preferably set corresponding to the height H of the transfer device 22.

Therefore, the sludge sheet 72 formed by passing the sludge 70 supplied through the hopper 3 through the pressing roller 20 has a thickness t of about 5 to 20 mm.

In the case where the thickness t of the sludge sheet 72 is formed to be less than 5 mm, drying is easily performed, but the treatment capacity is limited, resulting in poor economic efficiency.

In addition, when the thickness t of the sludge sheet 72 is formed to be larger than 20 mm, there is a fear that the drying to the inside may not be sufficiently performed, and it takes a long time to dry and adversely affect the productivity.

And the upper part of the heat insulating wall (2) is provided with exhaust pipes (6), (7) for discharging the air with high humidity inside.

The exhaust pipe 7 is divided into a plurality of zones along the longitudinal direction of the hot plate 30, the exhaust pipe 6 is vertically installed in each zone, and the exhaust pipe 6 is connected to exhaust the exhaust pipe 7. It is also possible to install.

The exhaust pipe 7 discharged to the outside is provided with a ventilation fan (8).

The ventilation fan 8 can also be installed in each exhaust pipe 6. In this case, however, the ventilation fan 8 may be damaged by the high heat of the hot plate 30, and it is preferable to install the ventilation fan 8 at a predetermined distance from the heat source.

The exhaust pipe 6 is preferably installed at the rear of the traveling direction so as to discharge the internal heat as little as possible, and it is preferable to install one or the minimum number in a range capable of sufficiently discharging moisture.

Discharge guide 4 is installed at the outlet of the heat insulating wall (2) is installed in close proximity to the transport device 22 to the bottom so that the sludge dry matter 74 transferred through the transport device 22 does not fall to the floor. It is preferable.

As shown in FIG. 1, the heat insulating wall 2 is preferably provided with an entrance door 9 for the worker to enter and exit for maintenance, maintenance, cleaning, and the like.

When the heat insulation wall 2 is installed as described above, heat efficiency is improved because the heat inside is not leaked to the outside, and the odor generated while the sludge 70 itself and the sludge 70 is dried is not leaked to the outside. However, it is also possible not to install the said heat insulation wall 2 as needed.

When the heat insulating wall 2 is not installed, the hopper 3 and the discharge guide 4 are installed to be supported by the base frame 10.

Next, the drying process of the sludge according to an embodiment of the sludge drying system according to the present invention configured as described above will be described.

First, when the sludge 70 generated from the sewage treatment plant or the wastewater treatment plant is supplied through the hopper 3, the supplied sludge 70 is compressed by the pressing roller 20 to form a thin sheet-like sludge sheet 72. ) Is supplied to the transfer device 22 and the hot plate 30.

When the thin sludge sheet 72 is in contact with the hot plate 30 as described above, since the hot plate 30 is heated to a high temperature by the heating device 32, it sizzles instantaneously and the surface dries to condense and agglomerate. Will form. At this time, the lumps coming off while being condensed from the sludge sheet 72 by the spiral member 23 and the connecting member 24 of the transfer device 22 are separated from each other and positioned in different spaces.

In the above state, the agglomerated sludge according to the circulating movement of the conveying device 22 continuously rolls in a predetermined space formed by the spiral member 23 and the connecting member 24 of the conveying device 22. Drying is made evenly in contact with 30), and sludge dry matter 74 is formed.

The larger size of the sludge dry matter 74 is broken down in contact with the brush member 27 of the brush device 26 that rotates in the same direction as the conveying direction of the conveying device 22, and the size is reduced again, and drying to the inside is performed. That's enough.

In addition, the sludge building material 74 attached to the spiral member 23 and the connection member 24 of the transfer device 22 also falls while contacting the brush member 27 of the brush device 26.

In the above, a preferred embodiment of the sludge drying system according to the present invention has been described, but the present invention is not limited thereto, and various modifications can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. This also belongs to the scope of the present invention.

According to the sludge drying system according to the present invention made as described above, since the sludge is deformed into a thin sheet shape and each small lump is separated and dried by the spiral member and the connecting member of the transfer apparatus, the drying efficiency is greatly improved. It is possible to obtain a sludge dry material having a low moisture content in a short drying time.

In addition, according to the sludge drying system according to the present invention, the sludge dry matter, which is agglomerated again by the brush device and becomes large, is pulverized into small pieces, so that sufficient drying can be performed.

According to the sludge drying system according to the present invention, the sludge dried material is transported while being separated and positioned in each space formed by the connecting member and the spiral member of the transfer device, and is transported while being rolled by the spiral member and the connecting member. Drying takes place evenly.

According to the sludge drying system according to the present invention, since the cold sludge is instantaneously contacted with the hot plate heated to 700 ° C. or more, the surface of the sludge dries to form a small mass and does not occur on the hot plate. Furthermore, since it moves while being rolled apart in each space by the conveying apparatus, the sludge adheres hardly to a hotplate or a conveying apparatus. In addition, the sludge dried partly attached to the conveying device is removed by the brush device, so the interval between cleaning, maintenance, and repair work becomes long even when used continuously.

In addition, according to the sludge drying system according to the present invention, since the sludge dried material is moved and discharged through the discharge guide by the transfer device moving on the hot plate, debris and the like of the sludge dry matter is prevented from scattering or falling inside the heat insulation wall. It is possible to keep clean at all times.

And according to the sludge drying system according to the present invention, the sludge is dried while the sludge is in direct contact with the hot plate heated to 700 ℃ or more, it is possible to obtain a very dry sludge dry water content of 20% or less, water content of 10% or less It is also possible to keep as. As described above, it is possible to greatly reduce the unit weight and volume of the sludge discharged by minimizing the water content of the sludge dry matter, and it is possible to minimize the transportation and landfill costs.

In addition, according to the sludge drying system according to the present invention, it is also possible to use the sludge dry matter as a fertilizer, etc. by using various organic materials contained in the dried sludge dry matter, it is also possible to use the sludge dry matter as a building material to replace sand. Therefore, it is very beneficial for environmental pollution prevention and nature protection.

In addition, according to the sludge drying system according to the present invention, since the dried sludge dried material exhibits the composition of the carbide which has passed through the carbonization system, it is excellent in adsorption and can be used as a water purification agent such as pollutant adsorbent, river, lake, etc. It can be used as a snow melting agent (snow removing agent) in winter by replacing calcium chloride that causes pollution, and can be used as a soil improver in flower gardens. Therefore, it is possible to use the sludge dry matter for various purposes, which is very beneficial for environmental pollution prevention and nature protection.

1 is a perspective view showing an embodiment of a sludge drying system according to the present invention.

2 is a cross-sectional view showing an embodiment of a sludge drying system according to the present invention.

Figure 3 is a perspective view showing the configuration of the base frame and the hot plate in one embodiment of the sludge drying system according to the present invention.

Figure 4 is a cross-sectional view showing the installation state of the heating apparatus in one embodiment of the sludge drying system according to the present invention.

5 is a perspective view showing a heating apparatus in an embodiment of the sludge drying system according to the present invention.

Figure 6 is a partially enlarged perspective view showing a network conveyor in an embodiment of the sludge drying system according to the present invention.

7 is a cross-sectional view taken along the line A-A of FIG.

Figure 8 is a partially enlarged side view showing another heating apparatus in an embodiment of the sludge drying system according to the present invention.

Claims (10)

A base frame comprising a pair of horizontal frames and a plurality of vertical frames supporting the horizontal frames at a predetermined height; A hot plate installed on the base frame and formed of a material having high thermal conductivity, A heating device installed below the hot plate and heating the hot plate to a high temperature; A transfer device which is formed to have a height of 5 to 20 mm and circulates in contact with the upper surface of the hot plate and has a plurality of spaces therein; Sludge drying system comprising at least one brush device rotatably installed on the base frame and installed to contact the brush member on the upper surface of the transfer device. The method according to claim 1, The heating device is a sludge drying system for heating the temperature of the hot plate to a high temperature of 700 ℃ or more. The method according to claim 1 or 2, The heating apparatus includes a heating wire that generates heat as power is supplied, a heating wire supporting member formed of a ceramic material having a groove for installing the heating wire, and having heat resistance and insulation, and a case in which the heating wire supporting member is inserted and installed. Sludge drying system. The method according to claim 1 or 2, The heating device is a sludge drying system configured by using a nozzle for injecting gas or fuel. The method according to claim 1 or 2, The transfer device is made using a network conveyor, The conveying apparatus is a sludge drying comprising a plurality of spiral members formed by spirally winding a metal wire between planes positioned at predetermined intervals and a plurality of connecting members forming a wavy metal wire to connect the spiral members to each other. system. The method according to claim 5, The spiral member is formed by setting the height of the upper surface and the lower surface to 5 to 20mm. The method according to claim 1 or 2, The brush device is a sludge drying system is installed to rotate in the same direction as the conveying direction of the conveying device. The method according to claim 1 or 2, A heat insulation wall installed to wrap at a predetermined interval from the base frame, and an inlet is formed on one side and an outlet on the other; A hopper installed at the inlet of the heat insulation wall; Sludge drying system further comprises a discharge guide installed at the outlet of the insulating wall. The method according to claim 8, And a pair of pressing rollers formed by pressing the sludge supplied to the hopper into a sheet shape having a thickness of 5 to 20 mm. The method according to claim 8, The upper part of the heat insulation wall is installed exhaust pipe for discharging the air of high humidity, Sludge drying system to install a ventilation fan in the exhaust pipe.