KR101473252B1 - A mechanical-ways drying equipment to dry the sewage and livestock manure - Google Patents

Abstract

The present invention relates to a mill-type drying apparatus for sewage and livestock manure waste, and relates to a drying apparatus for lowering the water content of sewage and livestock manure to a certain level in order to produce composted soil with sewage and livestock manure waste.
When the waste water having a high water content is fed into the rotating housing and the cylindrical oil jacket surrounding the housing is heated to supply sewage and livestock manure waste between the housing and the oil jacket, The present invention provides a simple mechanical drying apparatus in which a square screw and a grid attached to the inside of an oil jacket are mixed with air supplied from the outside so that the square screw and the grid plate are dried in a millstone-like manner.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a drying apparatus for dry-sewage and livestock manure,

The present invention relates to a drying device for sewage and livestock manure waste, and more particularly, to a drying device for sewage and livestock manure waste, and more particularly, The present invention relates to a drying apparatus for a matt type dryer of sewage and livestock manure waste which is supplied with waste in a housing and then supplies the waste to the housing so that the waste is simply mechanically dried between the screw of the housing and the oil jacket while grinding the residue like a millstone.

Sewage and livestock wastes have various treatment methods, the simplest of which is landfill treatment. However, the above-mentioned landfill treatment method has a fatal disadvantage of causing environmental pollution. Especially, landfill of sewage and livestock wastes cause soil pollution and many cases are dumping in the ocean. There is no difference from the landfill in that the sea is polluted and pollution is caused more in terms of pollutant diffusion. .

Accordingly, there has been developed a method of recycling the sewage and livestock wastes. In the aspect of recycling of resources, the composted soil is manufactured from sewage and livestock waste so as to prevent soil contamination due to the conventional landfill, I would like to.

As described above, there are various methods for producing the composted soil using sewage and livestock waste. The most commonly used method is to reduce the moisture content of the initial residue to 70% by using the paddle type drying device using steam It is a drying method in which steam of high temperature and pressure is injected. However, in the paddle type drying apparatus using steam, a large amount of steam is required because there is too much heat loss between the jacket and the paddle, and another initial dryer is required to improve the drying efficiency.

Another type of electroosmotic dryer is a dryer system that overcomes the disadvantages of the paddle dryer. However, it has a disadvantage in that the capacity to lower the drying ability of the residue or the moisture content of the residue such as the clogging of the caterpillar that penetrates the electricity is inferior.

On the other hand, the most commonly used method in Korea is the drying method using electric hot wind furnace. HSC sludge composting facility is the most typical facility. In the HSC sludge composting facility, the proportion of electric charges to generate hot wind in the rotary dryer is about 80% of the total cost, which is a big problem in operation management. Have.

In order to solve the problems of the prior art as described above, the impact crushing type drying system using the crushing effect of the crushing arm is disclosed in Japanese Patent No. 10-1404020. However, since the impact crushing type drying system physically crushes the residue having a high water content to widen the surface area where the residue receives heat, it is more effective than the conventional technology, but it is difficult to say that the electric power efficiency is high because of using the hot wind with high energy consumption The higher the water content, the more physical properties of the liquid, so that even if the residue is physically crushed, the residue becomes clogged with each other and the efficiency is lowered.

Meanwhile, the applicant of the present invention has proposed a method of solving the problems of the related art as described above in Patent Document No. 10-1404020, in which the screws in the housing are made different from each other to change the rotating force of the continuous driving motor, A drying device for soil preparation and a drying method are disclosed. However, the method of lowering the moisture content of the residue by using the rotational force variation as described above is a method of stopping and discharging the drive motor by using a batch type of waste not in a continuous discharge system in the housing. In this method, residue is put into the actual housing, As a result of the demonstration experiment as a mixing and compression step, the drying performance was found to be too low.

In order to solve the problems of the prior art described above, the present invention has been made to solve the above-mentioned problems of the prior art by enlarging the cross-sectional area of the housing for drying the residue as much as possible and attaching an angular spiral screw having a small length to the housing as a rotating body, Heating the jacket temperature to 300 ° C using an oil heating jacket and installing a grating inside the oil heating jacket so that the residue is dried between the grating and the screw and dried in the same manner as a millstone, The object of the present invention is to provide a drying apparatus for a slurry dryer of sewage and livestock manure waste which can keep the water content constant during inflow of debris of different water content so that the discharged debris can be reintroduced into the inlet through a return pipe .

In order to accomplish the object of the present invention as described above,

A device for treating sewage and livestock manure waste,

A cylindrical housing with a helical screw attached thereto; A motor for rotating the cylindrical housing; An oil jacket which surrounds the cylindrical housing and moves the hollow cylindrical heat; A boiler for supplying heat; A dirt inlet located at one end of the housing to supply sewage and livestock manure to an outer wall of the housing; A grating plate attached to the inner wall of the oil jacket and positioned between the housing and the oil jacket to receive heat; An outlet located at an opposite end of the housing to the dirt inlet; The present invention provides a drying apparatus for a slurry type sludge of sewage and livestock poultry, characterized in that sewage and livestock manure waste are put between a cylindrical housing and a lattice plate and dried.

A return pipe is connected to one surface of the discharge port and an opposite end of the return pipe is connected to one surface of the discharge port.

Preferably, the boiler supplies heat so that the temperature of the oil jacket is about 300 ° C.

It is preferable that a conveying screw provided inside the conveyance pipe and a motor for driving the conveying screw are installed in the conveyance pipe.

According to the present invention, since the cross-sectional area of the housing through which sewage and livestock manure waste pass is wide, sufficient heat can be supplied, thermal energy received from a high temperature oil heating jacket in a narrow moving space, A high water content can be expected to be reduced and a high water content residue can be expected to have a constant water content by lowering the water content again using the drying device through the return pipe.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view of a mill-type drying apparatus for sewage and livestock waste sludge of the present invention. FIG.
FIG. 2 is an enlarged view of the dotted line portion of FIG. 1; FIG.
FIG. 3 is a flow chart of the procedure for using the mill-type drying apparatus of the sewage and livestock waste sludge of the present invention. FIG.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings. The following description is provided to assist the understanding and implementation of the present invention, but the present invention is not limited thereto. It will be understood by those skilled in the art that various changes and modifications may be made therein without departing from the spirit of the invention as set forth in the following claims.

1 is a schematic view of a mill-type drying apparatus for sewage and livestock manure waste residue of the present invention. The mill-type drying apparatus 1000 of the present invention mainly comprises an inner housing 100 and an outer body 200. The inner housing 100 can be rotated in a cylindrical shape and rotated in a specific direction along the rotation axis LINE in the mill-type drying apparatus 1000 of the present invention. Here, the housing rotation motor 120 is arranged along the rotation axis LINE with the housing rotation motor 120 to provide power to the housing reducer 130 and the housing rotation motor 120 to rotate the inner housing 100 in a specific direction. And the housing reducer 130 is also aligned with the rotation axis LINE so as to be connected to the inner housing 100 to provide power for rotating the inner housing 100, 120 and the housing reducer 130 and the housing reducer 130 and the inner housing 100 are connected to each other by using a conventional method and finally the housing rotation motor 120 is rotated to connect the inner housing 100, To rotate. In addition, a helical screw gear 110 is mounted on the outer wall of the inner housing 100, and the screw gear 110 has a rectangular blade shape with an angular edge.

Also, the outer body 200 is fixed and formed into a cylindrical shape surrounding the cylindrical inner housing 100. Here, the outer body 200 is made of a heat insulating material that does not escape heat. The contact surface 210 between the outer body 200 and the inner housing 100 is sealed using conventional means so as not to be disturbed by the rotation of the inner housing 100,

A cylindrical oil jacket 220 surrounding the inner housing 100 is installed in the outer body 200. The oil jacket 220 is connected to the outer heat medium boiler 230 and the inside of the outer jacket 220 is heat- Oil (+) will be inserted. A cylindrical lattice 250 is attached to the inside of the cylindrical oil jacket 220 and a fan heater 240 is connected to the lattice 250 to blow hot air. A helical disk 260 is attached to the inside of the cylindrical grid 230 and the helical disk 260 is attached in a continuous spiral shape to the cylindrical grid 250.

An inlet 300 for introducing sewage and livestock manure is located at one side of the outer body 200. The inlet 300 is connected to the outer body 200, the oil jacket 220, And is connected to a gap between the grating 250 and the inner housing 100 through the grating 250. The discharge port 310 is connected to an external test chamber 320 and is connected to the test chamber 320 through a discharge port 310 through which the treated sewage and livestock manure are discharged. The user can check the state of the discharged sewage and livestock manure () and the like by opening the lid of the inspection room 320. A gas discharge port 390 for discharging steam and gas generated by the drying process is connected to an external gas treatment facility (not shown) at an upper end of the outer body 200.

Here, the test chamber 320 is connected to two valves 330 and 340 having different directions. Here, the discharge valve 330, which is manually controlled by the user, can discharge the dried sewage and livestock manure waste to the outside The re-feed valve 340 controlled by the other user is connected to the return pipe 350 and the other end of the return pipe 350 is connected to one side of the feed port 300. In addition, a conveying screw 360 is installed in the conveying pipe 350 to convey sewage and livestock manure, and the conveying screw 360 is rotated to convey sewage and livestock manure. A conveying motor 370 and a conveying motor speed reducer 380 are provided to provide power to the conveying screw 360.

FIG. 2 is an enlarged view of the dotted line portion GRIND in FIG. In Fig. 2, the arrow indicates the movement flow of sewage and livestock manure (1). 2, the screw gear 110 is made slightly thicker than the spiral disk 260 and the screw gear 110 and the spiral disk 260 are spaced apart from each other, Thereby preventing the disc 260 from being engaged.

FIG. 3 is a flow chart of a procedure of using the millstone type drying apparatus 1000 of the present invention shown in FIG. Hereinafter, an operation example of the present invention will be described with reference to FIG. 1 and FIG.

First, the user operates the boiler 230, the fan heater 240, the housing rotation motor 120, and the housing speed reducer 130 of the mill-type drying apparatus 1000 of the present invention to dry the sewage and livestock waste sludge (I) The temperature of the oil jacket 220 of FIG. 1 is increased by heating the oil (+) inside the boiler 230. The proper rising temperature of the oil jacket 220 is 300 ° C., Adjust the temperature. After completing the above procedure (A), the user puts in an appropriate amount of sewage and livestock manure (B) (B) At this time, the water content of newly introduced sewage and livestock manure () is generally 80 to 80% . The sewage and livestock manure (2) charged is dried in the millstone type drying apparatus (1000). (C) The sewage and livestock manure (2) And heated while moving between the housing 100 and the grid 250 and the spiral disc 260 installed in the oil jacket 220. Here, since there is a gap between the screw gear 110 installed on the outer wall of the inner housing 100 and the spiral disk 260, the two are not engaged with each other.

The introduced sewage and livestock manure (2) is separated from the screw gear (110) of the rotating inner housing (100) by a narrow gap between the lattice (250) and the spiral disk (260) inside the heated oil jacket At the same time as it receives heat, it is barked and dried in the same manner as a millstone. Here, a fan heater 240 is connected to the grid 250 so that the fan heater 240 provides air through the grid 250, and the air supplied through the fan heater 240 is supplied to the oil jacket 220 And is moved through the grid 250 to come into contact with the sewage and livestock manure (1), so that the drying rate of the sewage and livestock manure (2) is further increased. In addition, the steam and gas generated through the drying process are processed in an external gas treatment facility (not shown) through a gas discharge port 390, where the gas treatment facility can use conventional techniques.

When the drying process C is completed, the user opens the lid of the test chamber 320 connected to the discharge port 310 at the lower right of the millstone type drying apparatus 1000, A part of the livestock manure (2) is sampled to measure the water content of the sewage and livestock manure (2) that have undergone the present drying process by using a conventional method such as an external water content meter (not shown) (2) can be treated differently depending on the water content of the sludge and livestock manure (2) which have undergone the drying process, and (E) the sewage and livestock manure If the water content is less than 65% (E1), the user locks the reclosing valve 340 connected to the test chamber 320 and opens the discharge valve 330 to (F) the sewage and livestock manure ■) Disconnect the power supply (G)

If the water content of the sludge and livestock manure through the drying process is in the range of 65 to 70%, the user opens the re-feed valve 340 and locks the discharge valve 330 so that the sewage and livestock After the manure (2) is prevented from being discharged to the outside, the conveying process is performed for the sewage and livestock manure (2) which have undergone the drying process through the conveyance pipe (350) The conveying motor 370 and the conveying motor speed reducer 380 are operated so that the conveying screw 360 is moved to the inside of the conveying pipe 350 so that the total amount of the sewage and livestock manure 10% of the total amount of the sewage and livestock manure (2) that have been subjected to the drying process is introduced into the millstone drying apparatus 1000 through the inlet 300. (I) After the I procedure, The re-dosing valve 340 is closed and the discharge valve 330 is opened, (J) J After the procedure has been completed, the user will be returned to the site when the procedure A is performed for the drying of new sewage and livestock manure (■) and the procedure B is performed Considering the amount of sewage and livestock manure in the state, the appropriate amount of new sewage and livestock manure (1) is put in and the rest of the procedure is performed.

If the water content of the sludge and livestock manure through the drying process becomes 70% or more, the H-process is performed as described above to open the re-feed valve 340 and discharge valve 330, The conveying motor 370 and the conveying motor speed reducer 380 are operated so that the conveying amount becomes a level of 10-15% which is slightly more than the I procedure. (K) After the conveying is completed, After discharging the sewage and livestock manure through the drying process, return to the procedure A and carry out the rest of the procedure.

The present invention is focused on lowering the water content of sewage and livestock manure having a moisture content of the order of 80 to 83% to 65% or less to be suitable for microbial fermentation. Therefore, it is difficult to achieve a proper water content by performing the process once. However, the procedure of the flow chart of FIG. 3 is repeatedly performed to treat a large amount of sewage and livestock manure, so that the average moisture content of the treated sewage and livestock manure is suitable for microbial fermentation So that the water content can reach 55 ~ 65%.

100: Internal housing. 110: Screw gear. 120: housing rotation motor.
130: Housing reducer. 200: External body. 210: Contact surface. 220: Oil jacket.
230: Thermal oil boiler. 240: Fan heater. 250: Grid. 260: Spiral disk.
300: Inlet. 310: Outlet. 320: Laboratory. 330: Discharge valve.
340: Re-entry valve. 350: The return pipe. 360: Return Screw. 370: Transfer motor.
380: Conveyor motor speed reducer. 390: Gas outlet. 1000: Drying system with millstone.
+: Oil. ■: Sewage and livestock manure.

Claims (4)

In a mill-type drying apparatus for sewage and livestock manure waste,
A cylindrical housing with a helical screw attached thereto;
A motor for rotating the cylindrical housing;
An oil jacket which surrounds the cylindrical housing and moves a hollow cylindrical heat;
A boiler for supplying heat;
A dirt inlet located at one end of the housing to supply sewage and livestock manure to an outer wall of the housing;
A grating plate attached to the inner wall of the oil jacket and positioned between the housing and the oil jacket to receive heat;
An outlet located at an opposite end of the housing to the dirt inlet; A drain pipe is connected to a return pipe, the opposite end of the return pipe is connected to one surface of the dirt receiving port, and the drain pipe is connected to the drain pipe, Wherein the boiler supplies heat to the oil jacket so that the temperature of the oil jacket is 300 ° C, and the conveying pipe further includes a motor for driving the conveying screw and the conveying screw installed in the conveying pipe. Drying device for mill type. delete delete delete

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