KR101198389B1 - Dryer for refuse derived fuel to avoid flying of waste - Google Patents

Abstract

PURPOSE: A drying apparatus for solid-fuelizing domestic waste is provided to effectively solid-fuelize domestic waste by efficiently condensing dried waste and preventing the dried waste from unintentionally scattering. CONSTITUTION: A drying apparatus for solid-fuelizing domestic waste includes a drum(20), a hot air supplying duct(40), and an exhaust duct(28). The drum includes a waste drying chamber(21) and a stirring unit(70). A least one scattering preventive unit(90) is protruded from the inner wall of the drying chamber. The scattering preventive unit includes a longitudinal membrane and a transversal membrane(95). The longitudinal membrane is extended along the circumferential direction of the drum. A part of the longitudinal membrane is cut to form a cut part. The transversal membrane is extended along the longitudinal direction of the drum. The hot air supplying duct includes a hot air distributing plate(45) and a hot air guiding member(60). The hot air distributing plate includes distributing holes(46). The hot air guiding member includes a plurality of hot air flow paths. The spraying directions of the hot air flow paths are different.

Description

DRYER FOR REFUSE DERIVED FUEL TO AVOID FLYING OF WASTE}

The present invention relates to a drying apparatus for effectively solidifying household waste through scattering prevention, and more particularly, to minimizing scattering of household waste through scattering prevention member, thereby minimizing scattering of household waste. It relates to a drying apparatus for fuelization.

Home and industrial sites generate significant amounts of waste daily, some of which are recycled and the rest is incinerated and landfilled. Recently, various types of industrial and household wastes are used to make solid fuels and used as fuel sources. Solid fuels produced by using waste are called RDF (Refuse Derived Fuel). In other words, RDF refers to solid fuel produced by drying, crushing, pulverizing and shaping combustibles selected from various kinds of household garbage, industrial waste and general waste in urban areas.

Since waste generally contains a large amount of water, the RDF manufacturing process is a pretreatment process, which transfers waste from landfills into a drying furnace, and goes through a drying process of removing water from a plateau heat source.

In general, a rotary hot air dryer is used for the drying process, and the hot air dryer uses a hot air energy generated by burning light oil as a heat source to dry wastes. These diesel fuels typically consume about 1000 liters to dry 10 tons of waste.

On the other hand, the waste water is removed through the drying furnace is discharged to the waste outlet is pulverized finely through the crushing and crushing process through the transfer device, and then to form a fuel of a constant solid shape through the molding apparatus.

However, a conventional drying furnace has a problem of causing scattering of wastes from which moisture is removed due to the nature of using hot wind energy. Accordingly, the dried waste is not discharged to the waste outlet but is discharged to the exhaust gas outlet or scattered by scattering from the waste outlet. There was a problem of being discharged.

The present invention has been made to solve the above problems is an embodiment of the present invention to provide a drying apparatus for the solid waste of domestic waste that can be condensed more efficiently by drying the waste in the drying chamber to prevent indiscriminate scattering. have.

Drying apparatus for solid waste fuel according to an aspect of the present invention is a drum having a drying chamber and a stirring device for stirring and transporting the waste put into the drying chamber, and one end of the drum to supply hot air to the drying chamber In the drying apparatus for solidifying the domestic waste solid fuel having a hot air supply duct provided in the exhaust air and the exhaust duct provided at the other end of the drum to discharge the waste gas drying the waste in the drying chamber, waste that is scattered by the hot air in the drying chamber At least one scatter preventing member protruding from the inner wall of the drying chamber to suppress the scattering of the waste as it collides while moving toward the exhaust duct, wherein the at least one scatter preventing member is to extend the longitudinal direction of the drum The diaphragm may further include a diaphragm extending along a predetermined length.

Here, the diaphragm may be disposed adjacent to the exhaust duct and spaced apart from each other by a predetermined interval along the circumferential direction and the longitudinal direction of the drum.

In addition, the at least one cutout portion of the at least one scatter preventing member disposed adjacent to the exhaust duct may be provided at a plurality of spaced apart at regular intervals along the circumferential direction of the scatter preventing member.

The at least one scattering prevention member may include a closure having an incision that extends along a circumferential direction of the drum and is partially cut.

In addition, the position of the cutout formed in one of the at least one end of the at least one scatter preventing member may be formed differently from the position of the cutout formed in the other end of the adjacent one.

The at least one scattering preventing member may be disposed at a predetermined interval along a transport path through which the hot air is exhausted.

In addition, the at least one scattering prevention member may be arranged at equal intervals along the longitudinal direction of the drum.

The at least one scattering preventing member may extend in a direction intersecting with the longitudinal direction of the drum, but may be disposed so as not to interfere with the stirring device.

In addition, the stirring device may include a stirring shaft extending in the longitudinal direction of the drum and rotationally driven, and a plurality of stirring wings spaced apart from each other and protruding in a direction crossing the longitudinal direction of the stirring shaft.

In addition, the stirring device may be disposed to be deflected below the drying chamber.

In the drying apparatus for solid waste fuel of the embodiment of the present invention, it is possible to significantly reduce the flow of waste dried in the drying chamber into the exhaust gas outlet.

1 is an external perspective view of a drying apparatus for solid waste fuel according to an embodiment of the present invention.
Figure 2 is a perspective view showing the interior of the drying chamber of the drying apparatus for solid waste fuel according to an embodiment of the present invention.
3 is a cross-sectional view of a drying apparatus for solid waste fuel according to an embodiment of the present invention.
Figure 4 is a perspective view showing a hot air guide member of the drying apparatus for solid waste fuel according to an embodiment of the present invention.
5 illustrates the direction of hot air discharged by the hot air guide member according to an exemplary embodiment of the present invention.
6 is a side view of a drying apparatus for solid waste fuel according to an embodiment of the present invention.
FIG. 7 is a cross-sectional view taken along line II of FIG. 3.
8 is a cross-sectional view taken along line II-II of FIG. 3.
9 is a cross-sectional view taken along line III-III of FIG. 3.
FIG. 10 is a cross-sectional view taken along line IV-IV of FIG. 3.
11 is a perspective view showing a scattering preventing member according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an external perspective view of a drying apparatus for solid waste fuel according to an embodiment of the present invention, Figure 2 is a perspective view showing the interior of the drying apparatus for solid waste fuel according to an embodiment of the present invention, 3 is a cross-sectional view of a drying apparatus for solid waste fuel according to an embodiment of the present invention.

1 to 3, the drying apparatus 10 for solid waste fuel according to an embodiment of the present invention includes a drum 20 and a drum 20 having a drying chamber 21 into which waste is introduced. It includes a frame 15 for supporting the rotation drive device 30 is installed on the frame 15 to rotatably drive the drum 20.

The drum 20 includes a body cap 22 and a front cap 23 and a rear cap 24 which seal the open ends of the body 22 and the body 22 in a cylindrical shape having both sides open and having long lengths from side to side. do.

The front cap 23 and the rear cap 24 are slidably coupled to the outer circumferential surface of the body portion 22 via a bearing, and the body portion 22 is driven by the rotation driving device 30 installed in the frame 15. Can be rotated. That is, the front cap 23 and the rear cap 24 remain fixed without being rotated together with the body portion 22.

The rotary drive device 30 is a ring motor for driving the drum motor 31, the ring gear 33 installed around the outer circumferential surface of the drum 20, and the drum motor 31, the driving force of the drum motor 31 installed outside the body portion 22; It may be configured to include a power transmission mechanism 35 for transmitting to (33).

The power transmission mechanism 35 is for transmitting the rotational force of the drum motor 31 to the ring gear 33, and may be applied to a conventional belt, pulley and gear. In addition, the power transmission mechanism 35 may further include a reducer (not shown) connected to the drum motor 31 to reduce the rotation speed of the drum motor 31 at a predetermined ratio.

The rotary drive device 30 may be controlled by a controller (not shown) not shown, thereby adjusting the rotational speed of the drum 20 to adjust the time for the waste to stay in the drying chamber 21.

Both sides of the rotary drive device 30 may be provided with a pair of support rollers 37 for the stable support of the drum 20 that is rotated by the rotary drive device (30). The pair of support rollers 37 may be installed to make a rolling contact with the pair of rims 29 provided on the outer circumferential surface of the drum 20.

On the other hand, one end of the drum 20, that is, the front cap 23, the hot air supply duct for supplying hot air for drying the waste into the inlet 25 and the drying chamber 21 into the waste into the drying chamber (21) 40 may be provided.

The inlet 25 is connected to the hopper 50, which is a conical container in which waste is stored, and the waste stored in the hopper 50 is transferred through the waste transfer device 51 connected to the lower portion of the hopper 50 and then the inlet ( It is dropped into the drying chamber 21 through the 25).

The inlet 25 may be disposed at a position higher than the rotation center of the drum 20.

The waste conveying apparatus 51 includes a connecting pipe 53 installed at the lower portion of the hopper 50 so as to be connected to the inlet 25, and a conveying screw 55 rotatably installed inside the connecting pipe 53. do.

The connecting pipe 53 is to connect the inlet 25 and the hopper 50, one end may be in communication with the inlet 25, the other end may be provided to communicate with the hopper 50.

The transfer screw 55 is rotatably installed in the connection pipe 53 by a transfer motor (not shown) and transfers the waste stored in the hopper 50 into the drying chamber 21. In addition, the transfer screw 55 may be rotated at a predetermined rotation speed by a transfer motor (not shown) to enable a quantitative supply of waste introduced into the drying chamber 21.

The hot air supply duct 40 is disposed in parallel with the inlet 25 and supplies hot air to dry the waste introduced into the drying chamber 21.

The hot air supply duct 40 may be provided to be connected to the combustion chamber 41 and the hot air line 43 to generate a high temperature hot air to receive the hot air generated by the combustion chamber 41.

The combustion chamber 41 may be provided as an oil burner or a gas burner that burns fuel to generate hot hot air, and generates hot hot air by energy thermodynamically calculated according to the initial moisture content, the input amount, and the target dry rate of the waste. .

On the other hand, although not shown in the present embodiment, the hot air supplied from the combustion chamber 41 may be configured to be mixed with the exhaust gas is dried in the drying chamber 21 and then exhausted.

The hot air supplied from the combustion chamber 41 is discharged to the drying chamber 21 through the hot air supply duct 40. The hot air supply duct 40 is disposed inclined upwardly at one end of the drum 20 so as to increase the drying efficiency by supplying hot air toward the waste accumulated in the lower portion of the drying chamber 21 from the inlet 25. It may be configured to discharge the hot air toward the bottom.

As shown in FIG. 4, the hot air distribution plate 45 having the plurality of distribution holes 46 is provided at the end of the hot air supply duct 40 so that the hot air supplied into the drying chamber 21 may be evenly distributed. Can be.

In addition, the hot air supply duct 40 is supplied to the hot air supply duct 40 to be discharged through the hot air distribution plate 45 so as to spray the hot air toward the inlet 25 arranged in parallel to the inlet 25 Hot air guide member 60 for guiding in the vicinity may be provided.

3 to 5, the hot air guide member 60 is a pipe having a plurality of hot air flow passages 61 with different spray directions so as to spray the hot air evenly toward the falling path of the waste falling from the inlet 25 Is formed in, a plurality of hot air flow passage 61 may be provided to protrude through the distribution hole 46 of the hot air distribution plate 45.

Such a plurality of hot air flow passage 61 is one or more first flow passage (61a) to guide toward the upper side (arrow A) of the inlet 25, one to guide toward the inlet 25 (arrow B) The second channel 61b may include the second channel 61b and one or more third channels 61c guiding toward the lower side (arrow C) of the inlet 25.

The first flow path 61a, the second flow path 61b, and the third flow path 61c may be provided to have the same hot-air jet angle in the section of the predetermined region of the hot air guide member 60, respectively.

Meanwhile, in the present exemplary embodiment, a plurality of hot air flow passages 61 are formed to face the top, bottom, and the inlet 25 of the inlet 25 in a predetermined region, but this is just an example and faces the inlet 25. Of course, the plurality of hot air flow passages 61 may be configured to have different injection angles. That is, a part of the plurality of hot air flow passages 61 may be provided to inject hot air in the longitudinal direction of the drum, and the other part may be provided to be sprayed toward the falling path of the waste falling from the inlet 25.

1 to 3 again, the waste dropped into the drying chamber 21 through the inlet 25 is agitated and transported by the stirring device 70 rotatably installed in the drying chamber 21 and at the same time by hot air. After being dried, it is discharged to a waste outlet 26 located at the lower end of the drum 20.

The stirring device 70 is a direction in which the stirring shaft 71 extending along the longitudinal direction L of the drum 20 is spaced apart from each other along the stirring shaft 71 and crosses the longitudinal direction of the stirring shaft 71. It includes a plurality of stirring blades 73 protruding.

The stirring shaft 71 is supported through a bearing through both ends of the drum 20, and may be configured to receive power by the stirring driver 75 disposed outside the drum 20.

The stirring drive unit 75 includes a stirring motor 76, a drive gear 77 coupled to the shaft of the stirring motor 76, a driven gear engaged with the drive gear 77 and provided at an end of the stirring shaft 71. (78).

The plurality of stirring blades 73 are disposed in a helical shape along the axial direction of the stirring shaft 71, and the waste located in the lower portion of the drying chamber 21 when the stirring shaft 71 is rotated by the stirring driver 75. Transported to the upper portion, and the waste transported to the upper portion is transported to the waste outlet 26 by the plurality of stirring blades 73 while falling by its own weight.

The waste outlet 26 is connected with a screw conveyor 80 for discharging the waste discharged by drying in the drying chamber 21 to the next process.

Referring to FIGS. 3 and 6, the discharging screw conveyor 80 includes a conveyor housing 81 and a discharging screw 83 rotatably installed inside the conveyor housing 81.

The discharge screw 83 may be provided to be rotated by receiving the rotational force of the driving motor 85 installed in the frame 15 through a power transmission member 87 such as a conventional belt.

Referring again to FIGS. 1 to 3, the hot air supplied into the drying chamber 21 through the hot air supply duct 40 supplies thermal energy to wet waste introduced into the drying chamber 21 to dry the waste drum 20. That is, the other end of the rear cap 24 is moved to the exhaust duct 28 through the exhaust gas outlet 27 located on the upper side is discharged to the outside.

The exhaust duct 28 may be provided with a filter 28a to remove odor generated from the exhaust gas exhausted after the waste is dried.

The filter 28a may be formed of an active filter, a carbon filter, a prefilter, etc. having excellent deodorizing performance. In addition, the exhaust duct 28 may be provided with an air control unit 28b such as a conventional damper that can control the amount of air discharged to the outside.

On the other hand, the waste stirred and transported in the drying chamber 21 can be discharged to the outside through the exhaust duct 28 as it is scattered in the drying chamber 21 when the moisture is removed by the hot air. In order to prevent the waste which is dried through the exhaust duct 28 to flow out, in the drying chamber 21 of the present embodiment, when the flying products move along the moving path S of the hot air, the flying products collide with each other. At least one scattering preventing member 90 may be provided to prevent the waste from scattering by proceeding along (S).

7 is a cross-sectional view taken along line II of FIG. 3, FIG. 8 is a cross-sectional view taken along line II-II of FIG. 3, FIG. 9 is a cross-sectional view taken along line III-III of FIG. 3, and FIG. 10 is FIG. Sectional view taken along line IV-IV.

2, 3, 7 to 10, at least one scattering prevention member 90 is spaced apart at predetermined intervals along the transport path (S) through which the hot air is exhausted and protrudes from the inner wall of the drum (20) It can be provided with a plate in the form of a ring.

The at least one scattering member 90 has a plurality of spaced apart a predetermined interval along the longitudinal direction (L) of the drum 20, each of the plurality of scattering member 90 is the inner wall of the drum (20) Including a vertical end 91 protruding in the radial direction of the drum 20 in the circumference extending in the circumferential direction, the circumferential portion of the vertical end portion 91 is formed by cutting to allow the hot air to pass through It may be provided.

In addition, the cutouts 93 formed on each of the plurality of shatterproof members 90 may be provided so as not to match the positions of the cutouts 93 of other adjacent shatterproof members 90. This is to allow the flying products passing along one of the cutouts 93 and traveling along the transport path S to be collided by another adjacent scattering preventing member 90.

Through this configuration, the wastes scattered in one region divided by the plurality of finishes 91 in the drying chamber 21 collide with the finish 91 while moving along the transport path S, and thus the lower side of the drying chamber 21. As it falls to the next zone, the progression to the next area is suppressed and at the same time as the agitation with the waste being agitated by the stirring device 70, the amount of scattering of the waste is significantly reduced.

Meanwhile, as shown in FIG. 7, the cutouts 93 of the scattering preventing member 90 provided at a position adjacent to the exhaust gas outlet 27 are spaced apart at regular intervals along the circumferential direction of the closing film 91. The length extending in the radial direction may be provided to be relatively smaller than the length of the other closing film (91). This is to prevent a pressure drop of the hot air flowing through the exhaust gas outlet 27 to the exhaust duct 28.

In addition, the at least one scattering prevention member 90 may further include a diaphragm 95 extending a predetermined length along the longitudinal direction (L) of the drum (20).

The diaphragm 95 may be disposed to be adjacent to the exhaust duct 28, and may be provided in a plurality of intervals along the circumferential direction and the longitudinal direction of the drum 20. The diaphragm 95 is intended to suppress the flow of the hot air in the radial direction of the drum 20 in the portion adjacent to the exhaust duct 28 and to reduce the exhaust pressure of the hot air due to the pressure drop. .

The at least one scatter preventing member 90 is provided to extend in the direction intersecting with the longitudinal direction (including the vertical direction) of the drum 20 so as to suppress the scattering of the fly flow along the transport path through which the hot air is exhausted However, it is preferable to extend to have a length such that it does not interfere with the stirring device 70 that is rotationally driven in the drying chamber 21. In addition, the stirring device 70 may be disposed to be relatively biased to the lower side of the drying chamber 21 so that the hot air may move smoothly toward the upper portion of the drying chamber 21.

On the other hand, in the present embodiment 91 is provided with four along the longitudinal direction (L) of the drum 20, but the number of such shatterproof member 90 may be changed according to the design matters, of course. to be. In addition, it is clear that the spacing of the scattering preventing member 90 may be arranged at equal intervals or may have different intervals.

In addition, as shown in FIG. 11, at least one or more scattering preventing members 90 may be configured as a vertical film 91 except for the diaphragm 95.

Hereinafter, the operation and effects of the drying apparatus for solid waste fuel of the present invention will be described with reference to FIG.

First, the waste stored in the hopper 50 is introduced into the drying chamber 21 at a speed determined through the waste transfer device 51 to the inlet 25 of the drum 20 which is being rotated by the rotary drive device 30. . At this time, the inlet 25 is disposed in a relatively higher position than the stirring device 70, the waste introduced through the inlet 25 is dropped to the lower portion of the drying chamber (21).

Then, the stirring shaft 71 is transmitted to the power by the stirring drive unit 75 is rotated, while stirring the waste while rotating the stirring blades 73 with the rotation of the stirring shaft 71 and at the same time waste outlet 26 Transport it.

When the waste is introduced into the drying chamber 21, the hot hot air supplied from the combustion chamber 41 is introduced into the drying chamber 21 through the hot air supply duct 40. At this time, the hot air supply duct 40 can smoothly supply the hot air toward the lower portion of the drying chamber 21 to be accumulated apart from the inlet 25 as the inclined upward slope. In addition, the hot air discharged from the hot air supply duct 40 disposed in parallel with the inlet 25 is evenly guided by the hot air guide member 60, evenly across the entire fall path of the wet waste falling directly from the inlet 25. Since the hot air can be injected, it is possible to improve the drying efficiency of the waste by smoothly supplying thermal energy to the waste which is relatively high in water.

The hot air supplied to the drying chamber 21 moves along the longitudinal direction L of the drum 20, and supplies heat energy to the waste agitated by the stirring device 70, and then discharges the exhaust gas of the drum 20. It is discharged to the outside through (27).

At this time, the waste dried in the drying chamber 21 is scattered along the conveying path (S) of hot air by hot air, but with a plurality of scattering preventing members 90 disposed in the longitudinal direction (L) of the drum 20. The amount of waste that is dropped as the waste is dropped to the lower portion of the drying chamber 21 by the collision and is stirred and transported by the stirring device 70 and is scattered again is significantly reduced. Accordingly, the amount of fly ash contained in the exhaust gas of the hot air drying the waste in the drying chamber 21 is introduced into the exhaust gas outlet 27 in a significantly reduced state and then discharged to the outside through the exhaust duct 28.

In the above, specific embodiments have been illustrated and described. However, the present invention is not limited only to the above embodiments, and those skilled in the art may make various changes without departing from the spirit of the technical idea of the invention as set forth in the claims below. will be.

10: drying apparatus, 20: drum,
21: drying chamber, 25: inlet,
26: waste outlet, 27: exhaust outlet,
28: exhaust duct, 30: rotary drive,
40: hot air supply duct, 45: hot air distribution plate,
46: distribution hole, 50: hopper,
60: hot air guide member, 61: hot air flow path,
61a: first euro, 61b: second euro,
61c: third euro, 70: agitator,
71: stirred out, 73: stirring blade,
80: screw conveyor for discharge, 90: shatterproof member,
91: ending, 93: incision,
95: diaphragm.

Claims (10)

In the drying apparatus 10 for effectively solidifying the domestic waste through the prevention of scattering,
A drum (20) having a drying chamber (21) into which waste is introduced through the inlet (25) and a stirring device (70) for stirring and transferring the waste put into the drying chamber (21);
A hot air supply duct 40 provided at one end of the drum 20 to supply hot air to the drying chamber 21; And
And an exhaust duct 28 provided at the other end of the drum 20 to discharge the waste gas of the drying chamber 21 from the waste gas.
At least one scattering prevention protruding from the inner wall of the drying chamber 21 so that the scattering of the waste is suppressed as the waste scattered by the hot air collides while moving toward the exhaust duct 28 in the drying chamber 21. A member 90,
The at least one scattering preventing member 90 extends along the circumferential direction of the drum 20 and has a closing portion 91 having a cutout portion 93 in which a portion thereof is cut and a longitudinal direction of the drum 20. A diaphragm 95 is formed to extend along a predetermined length,
The finishing membrane 91 is disposed in a plurality of spaced apart along the longitudinal direction of the drum 20, the diaphragm 95 is disposed in a plurality of spaced apart along the circumferential direction of the drum 20 at a position adjacent to the exhaust duct 28. ,
The hot air supply duct 40 has a different spraying direction so that the hot air distribution plate 45 having a plurality of distribution holes 46 and the hot air discharged from the hot air distribution plate 45 are sprayed in different directions. Drying apparatus (10) for the domestic waste solid fuel, characterized in that the hot air guide member (60) having a plurality of hot air flow passage (61) is provided. delete The method of claim 1,
The plurality of incisions 93 of the closing membrane 91 disposed adjacent to the exhaust duct 28 among the closing membranes 91 are spaced apart at regular intervals along the circumferential direction of the closing membrane 91. Drying apparatus for solidifying waste fuel (10). delete The method of claim 1,
The location of the cutouts 93 formed in any one of the plurality of finishes 91 is an incision 93 formed in the other end 91 adjacent to any one of the finishes 91. Drying apparatus for solidifying the domestic waste solid fuel is formed differently from the position (10). delete The method of claim 1,
The plurality of closures (91) is a drying device for the domestic waste solid fuel is disposed at equal intervals along the longitudinal direction of the drum (10) (10). The method of claim 1,
The plurality of finishing membranes 91 extend in a direction intersecting with respect to the longitudinal direction of the drum 20, wherein the drying apparatus 10 for solidifying the domestic waste solid fuel, characterized in that disposed so as not to interfere with the stirring device (70). ). The method of claim 1,
The stirring device 70 extends in the longitudinal direction of the drum 20 and a plurality of stirring shafts 71 which are rotated and spaced apart from each other and protrude in a direction crossing with respect to the longitudinal direction of the stirring shaft 71. Drying apparatus (10) for domestic waste solid fuel comprising a stirring blade (73). The method of claim 9,
The agitation device (70) is a drying device (10) for the domestic waste solid fuel is arranged to be deflected below the drying chamber 21.

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