KR20100120813A - Organic waste drying apparatus using hot wind - Google Patents

Abstract

PURPOSE: An organic waste drying device using hot wind is provided to sufficiently dry organic waste regardless of the change and load of organic waste by pulverizing the organic waste without a lump. CONSTITUTION: A hopper(10) stores organic waste. A transfer unit(20) is installed on the lower side of the hopper and supplies organic waste stored in the hopper. A rotary drying unit(30) is pivotally installed on one side of the transfer unit, rotates organic waste supplied to the inside of the transfer unit, and discharges the organic waste to a waste outlet. A hot wind supply unit(40) is installed on one side of the transfer unit and supplies hot wind to the rotary drying unit to dry the organic waste.

Description

Organic waste drying apparatus using hot wind}

The present invention relates to an organic waste treatment drying apparatus capable of drying organic waste such as sewage sludge, and more particularly, to an organic waste drying apparatus using hot air capable of efficiently drying organic waste.

Recently, the sewage throughput has increased as the sewage penetration rate has improved. Accordingly, the amount of sewage sludge is also increased along with the increase in the amount of sewage treatment.

Currently, most of these sewage sludges are treated with ocean dumping. In other words, sewage sludge is currently being treated by 71% ocean dumping, 15% reuse, 13% incineration, and 1% landfill. Marine dumping is the cheapest method of treating sewage sludge, but it is also the most dangerous method for marine ecosystems. Therefore, dumping at sea is also forbidden worldwide. Therefore, a method for stably treating and disposing sewage sludge having an increased amount must be urgently prepared.

Incineration and recycling of sewage sludge are recommended in the case of incineration in order to reduce sludge and recover heat energy, but incineration containing heavy metals, large quantities of air pollutants such as sulfur oxides and nitrogen oxides, or There are problems such as the emission of harmful gases such as dioxin. Therefore, the current treatment of sewage sludge has been promoted in the direction of using sewage sludge as a resource, that is, in the direction of recycling sewage sludge.

In the case of sewage sludge recycling, there are various methods such as composting, gasification, and fuelization. However, there are many problems such as recovery of specific substances due to heavy metals contained in sewage sludge and various property differences. Recently, the method of recycling gas generated by pyrolysis as fuel and the method of recycling final carbide through carbonization of sewage sludge have been highlighted. It is becoming.

Sewage sludge from wastewater treatment plants is first discharged after dewatering. However, dewatered sludge after the dehydration process has a water content of over 80%. Therefore, a drying process that lowers the moisture content is essential for reuse of sewage sludge. When the sewage sludge is dried, the weight of the sludge is reduced, so handling and transporting are easy, and problems such as secondary leachate can be solved. In addition, the dried sludge can be recycled into activated carbon, construction materials and the like.

Drying apparatus using hot wind may be used to dry sewage sludge. Drying apparatus using hot air has the advantage that it can easily meet the required standards according to the organic waste treatment and disposal method. In other words, the high drying temperature changes the physical properties of the organic waste, such as sterilizing the organic waste and partially removing the odor, thereby making it easier for end users to use sewage sludge.

The present invention was devised to solve the above problems, and an object of the present invention is to provide an organic waste drying apparatus using hot air having high drying efficiency and capable of discharging dried organic waste having dense and even particles.

An object of the present invention as described above, the hopper for storing the organic waste; A transfer unit installed under the hopper and supplying organic waste stored in the hopper; A rotary drying unit rotatably installed at one side of the transfer unit and discharging to the waste outlet while rotating the organic waste supplied into the transfer unit; And a hot air supply unit installed at one side of the transfer unit and configured to supply hot air to dry the organic waste into the rotary dryer unit, wherein the transfer unit connects the hopper to the rotary dryer unit; Is installed inside the connection pipe, the transfer screw for transferring the organic waste stored in the hopper to the rotary drying unit, rotatably installed above the transfer screw in the interior of the hopper, the organic waste is transferred to the transfer screw It can be achieved by providing an organic waste drying apparatus using a hot air comprising a rotating member for moving to.

At this time, the rotating member includes a pair of rotary plates facing each other to rotate, it is preferable that the pair of rotary plates to be rotated by a paddle motor.

In addition, the rotary drying unit, a rotating drum installed to be rotatable in a hollow cylindrical shape; A transfer blade spirally formed along the inner surface of the rotary drum from one end of the rotary drum to the other end so as to move the organic waste supplied by the transfer unit to the waste discharge port; And a plurality of pickup wings formed on an inner surface of the rotating drum in parallel to each other in the longitudinal direction of the rotating drum.

In addition, the organic waste drying apparatus using the hot air according to an embodiment of the present invention, is installed in the rotary drying unit to be rotated independently of the rotary drying unit, to grind the organic waste supplied from the hopper A waste stirrer including a plurality of primary stirring blades may be further included.

In addition, the organic waste drying apparatus using the hot air according to an embodiment of the present invention, is installed to rotate integrally with the rotary drying unit inside the rotary drying unit, hinders the flow of hot air moving to the other end of the rotary drying unit It may further include a hot air blocker formed to.

Organic waste drying apparatus using the hot air according to an embodiment of the present invention having the structure as described above can be continuously put into the rotary drying unit, even if the organic waste has a high viscosity, during the drying process by grinding the organic waste Since agglomeration can be prevented, even if load or property of an organic waste changes, it can fully dry.

In addition, the organic waste drying apparatus using the hot air according to an embodiment of the present invention to increase the thermal insulation efficiency by the dual structure of the rotating drum, make the hot air turbulent by the waste stirrer, and increase the contact with the crushed organic waste Since the drying efficiency can be maximized, the drying time can be reduced, and the drying temperature can be lowered. Therefore, energy consumption can be reduced.

In addition, using the organic waste drying apparatus using the hot air according to an embodiment of the present invention, it is possible to discharge the organic waste of dense and evenly dried particles as a final result, it is possible to minimize the discharge of particulate matter.

In addition, when the organic waste drying apparatus using the hot air according to an embodiment of the present invention is used, the dried organic waste may be recycled as an adsorbent or soil cover agent through a subsequent process, thereby greatly reducing the amount of waste. have. Therefore, the occurrence of secondary social problems such as environmental pollution can be reduced.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the organic waste drying apparatus using the hot air according to the present invention.

However, in the following description of the present invention, if it is determined that the detailed description of the related known functions or components may unnecessarily obscure the subject matter of the present invention, the detailed description and the detailed illustration will be omitted.

1 is a view schematically showing an organic waste drying apparatus using hot air according to an embodiment of the present invention. FIG. 2 is a perspective view illustrating a hopper and a transfer unit of the organic waste drying apparatus using the hot air of FIG. 1, and FIG. 3 is a plan view illustrating the hopper and the transfer unit of FIG. 2. 4 is a perspective view illustrating a rotary drying unit of the organic waste drying apparatus using the hot air of FIG. 1, and FIG. 5 is a cross-sectional view of the rotary drying unit of FIG. 4 taken along line 5-5. 6 is a perspective view illustrating a hot air blocker of the organic waste drying apparatus using the hot air of FIG. 1.

Referring to Figure 1, the organic waste drying apparatus 1 using the hot air according to an embodiment of the present invention is a hopper 10, transfer unit 20, rotary drying unit 30, hot air supply unit 40, waste agitator 50, a hot air blocker 60, and a controller 70 may be included.

Hopper 10 stores the organic waste (S), the lower portion of the hopper 10 is provided with a transfer unit 20 for transferring the organic waste (S) to the rotary drying unit (30). Here, the organic waste (S) stored in the hopper 10 includes sewage sludge and the like remaining after the sewage treatment in the sewage treatment plant. Sewage sludge S is usually stored in the hopper 10 after undergoing a dehydration process. Therefore, the sewage sludge S stored in the hopper 10 has a water content of about 70%. Hopper 10 may be formed in a variety of shapes, if the organic waste (S) can be stored. In this embodiment, as shown in Figure 4 is formed in a box shape of a rectangular cross-section.

The transfer unit 20 is installed below the hopper 10, and supplies the organic waste S stored in the hopper 10 to the rotary drying unit 30. The transfer unit 20 may include a connection pipe 21, a transfer screw 22, and a rotating member 23.

The connecting pipe 21 connects the hopper 10 and the rotary drying unit 30, and is installed below the hopper 10. One end of the connecting pipe 21 is connected to one side wall 37 of the rotary dryer 30 at a position higher than the rotation center of the rotary dryer 30, and the organic waste S is connected to the rotary dryer 30. An inlet port 27 to be introduced into the inside is formed. An inclined surface 24 is provided between the hopper 10 and the connection pipe 21 to collect the organic waste S stored in the hopper 10 into the connection pipe 21 by its own weight. One end of the connection pipe 21 may be installed to protrude a predetermined distance into the rotary drying unit 30 as shown in FIG. 1.

 The feed screw 22 is rotatably installed in the connection pipe 21, and transfers the organic waste S stored in the hopper 10 to the rotary drying unit 30. The feed screw 22 is rotated by the feed motor M2. Therefore, it is possible to quantitatively supply the organic waste S by adjusting the rotation speed of the feed screw 22.

The rotating member 23 is rotatably installed above the feed screw 22 near the bottom of the hopper 10 in the hopper 10. That is, the rotating member 23 is installed between the hopper 10 and the transfer screw 22 to transfer the organic waste S stored in the hopper 10 to the transfer screw 22. In general, sewage sludge, one of the organic wastes (S), has a high viscosity due to high water content even after the dehydration process. Therefore, when only the above-mentioned feed screw 22 is installed in the lower part of the hopper 10, and the sewage sludge S dehydrated is loaded in the hopper 10 and then transferred to the feed screw 22, a tunneling phenomenon occurs. The sewage sludge S cannot be continuously supplied. In order to prevent such a tunneling phenomenon, the rotating member 23 may be installed on the upper side of the conveying screw 22. Then, since the rotary member 23 moves the organic waste S such as sewage sludge to the feed screw 22, the tunneling phenomenon can be prevented from occurring. Therefore, even in the case of the organic waste S of high moisture content, the feed screw 22 can smoothly supply the organic waste S to the rotary drying unit 30.

The rotating member 23 may be formed of a pair of rotating plates 23a that rotate to face each other. As shown in FIG. 3, the pair of rotating plates 23a may be installed in parallel with each other at the bottom of the hopper 10 and may be formed as a flat plate having an area corresponding to the entire area of the bottom of the hopper 10. . In addition, the pair of rotating plates 23a can be configured to rotate by the rotating shaft 23b, the gear 23c, and the paddle motor M1. Therefore, when the pair of rotary plates 23a are rotated by the paddle motor M1, the organic waste S stored in the hopper 10 is pushed by the transfer screw 22 to be transferred. The rotary member 23 and the feed screw 22 are preferably installed as close as possible as long as the outer circumferential surface of the rotary member 23 and the outer circumferential surface of the feed screw 22 do not interfere during rotation.

Rotating drying unit 30 is rotatably installed on one side of the transfer unit 20, is formed in a substantially hollow cylindrical shape. The rotary drying unit 30 is configured to transport and discharge the organic wastes S supplied therein by the transfer unit 20 to a waste discharge port 81 formed on the opposite side to the transfer unit 20. The rotary drying unit 30 includes a rotary drum 31.

The rotary drum 31 is formed in a hollow cylindrical shape, and rotates by a drum motor (M3) installed on the outside of the rotary drum (31). The controller 70 may adjust the rotation time of the drum motor M3 to adjust the time for the organic waste S transferred to the inside of the rotating drum 31 to stay in the rotating drum 31. Rotating drum 31 is formed in a double drum structure, as shown in Figures 1 and 4 in order to minimize the heat loss, it is preferable to install a heat insulating material 35 between the two drums. One side wall 37 of the rotary dryer 30, that is, the portion connected to the transfer unit 20, is fixed without being rotated like the rotary drum 31. Accordingly, one end of the rotating drum 31 may be supported by a rotation supporting member 38 such as a bearing installed on one side wall 37. The other end of the rotating drum 31 may be rotatably supported by the rotation support member 38 installed in the discharge unit 80. Therefore, even if the rotating drum 31 rotates, the discharge portion 80 does not rotate. The discharge part 80 includes a waste discharge port 81 installed in the lower portion and a gas discharge port 82 provided in the upper portion.

On the inner surface 31a of the rotary drum 31, a transfer blade 32 for transferring the organic waste S supplied through the transfer unit 20 in the longitudinal direction of the rotary drum 31 is formed. The transfer blade 32 is formed spirally along the inner surface 31a of the rotating drum 31 from one end of the rotating drum 31 to the other end. In addition, a plurality of pickup blades 33 may be formed on the inner surface 31a of the rotating drum 31 to efficiently mix the organic waste S. As shown in FIGS. 4 and 5, the plurality of pickup wings 33 are formed at regular intervals in parallel to each other in the longitudinal direction of the rotating drum 31 on the inner surface 31a of the rotating drum 31. When the rotary drum 31 rotates, the plurality of pickup blades 33 carry the organic waste S on the lower surface of the rotary drum 31 upwards. Organic waste (S) transported to the top is dropped by its own weight. That is, the organic waste S transported into the rotating drum 31 is transferred to the upper portion of the rotating drum 31 by the plurality of pickup blades 33 when the rotating drum 31 rotates, and at the same time, It is conveyed from the inlet 27 to the waste outlet 81 by the transfer blade 32.

The hot air supply unit 40 is installed at one side of the transfer unit 20, and supplies hot air to dry the organic waste S injected into the rotary drying unit 30. The hot air inlet 48 of the hot air supply unit 40 may be installed near the center of rotation of the rotary dryer 30 below the inlet 27 of the transfer unit 20 as shown in FIG. 1. The hot air inlet 48 may be provided with a hot air distribution plate 49 that can deflect the direction of the hot air. The hot air distribution plate 49 is formed of a porous plate having a plurality of holes 49a formed therein, and the plurality of holes 49a discharge hot air from the hot air inlet 48 toward the inner surface 31a of the rotating drum 31. It is formed to be. When the hot air blows toward the inner surface 31a of the rotating drum 31 as described above, the organic waste S may be minimized to be attached to the inner surface 31a of the rotating drum 31.

The hot air supply unit 40 includes a combustion chamber 41 that generates hot air at a high temperature, and a hot air line 47 that connects the combustion chamber 41 and the rotary drying unit 30 to each other. Combustion chamber 41 may include a chimney (42) insulated with a heat insulating material and a gas burner (43) installed at the bottom of the chimney (42). The gas burner 43 is connected to a fuel gas cylinder 44 and a blower 45 that pressurizes the gas and blows hot air into the hot air inlet 48. LPG may be used as the fuel gas. Between the gas burner 43, the fuel gas cylinder 44, and the blower 45, flowmeters F1 and F2 and valves V1 and V2 are installed to control the amount of fuel gas and the pressure of the blower. do. In addition, inside the chimney 42 and the hot air line 47 of the combustion chamber 41, temperature sensors T1 and T2 for measuring the temperature of the hot air may be installed. Thermocouples may be used as the temperature sensors T1 and T2.

The waste stirrer 50 may be further installed inside the rotary dryer 30. The waste stirrer 50 grinds the organic waste S introduced into the rotary drying unit 30 and generates swirl flow so that the hot air and the organic waste S are mixed well. As shown in FIG. 1, the waste stirrer 50 is installed to rotate independently of the rotary drying unit 30 in the longitudinal direction of the rotary drying unit 30 inside the rotary drying unit 30. That is, the waste stirrer 50 may be installed to rotate by the stirring motor M4 provided outside the exhaust unit 80. The waste agitator 50 may be installed to rotate at the same rotation center as the rotation center of the rotary dryer 30, but is preferably installed to be eccentric with the rotation center of the rotary dryer 30.

The waste stirrer 50 may include a rotating shaft 51 connected to the stirring motor M4 and a plurality of rotating bodies 52, 53, and 54 spaced apart along the rotating shaft 51. The plurality of rotors 52, 53, and 54 are formed to perform various functions. For example, the plurality of rotating bodies 52, 53, 54 are introduced into the rotary drying unit 30 through the inlet 27 from the hopper 10 so as to crush the falling organic waste S. It may include a plurality of primary stirring blades 52 are installed near the inlet 27. In addition, the plurality of rotors 52, 53, and 54 may be installed on the rotation shaft 51 to one side of the primary stirring blade 52, and may include a plurality of secondary stirring blades 53 for generating swirl flow. have. The plurality of secondary agitating blades 53 allow the rotary shaft 51 to rotate to generate swirl flow so that hot air forms turbulence, thereby effectively drying organic waste that is difficult to dry. In addition, the plurality of rotating bodies 52, 53, and 54 may include a plurality of rotating blades 54 installed on the rotating shaft 51 toward the discharge part 80 toward one side of the secondary stirring blade 53. The plurality of rotary blades 54 prevents the low-speed hot air flowing toward the gas discharge port 82 toward the gas discharge port 82 as the rotary shaft 51 rotates. Therefore, the fine dust of the dried organic waste does not easily go out toward the gas outlet 82, so that the time for which the hot air stays in the rotary drying unit 30 is increased, thereby increasing the drying efficiency.

In addition, the inside of the rotary drying unit 30 may be further provided with a hot air obstruction unit 60 formed to interfere with the flow of hot air moving toward the discharge portion 82 of the rotary drying unit 30. The hot air blocker 60 is installed to be fixed to the other end of the rotary drying unit 30, that is, the other end of the rotary drum 30, inside the rotary drying unit 30. Therefore, when the rotary drying unit 30 rotates, the hot air blocker 60 rotates integrally with the rotary drying unit 30.

As shown in FIGS. 1 and 6, the hot air blocker 60 is installed coaxially with the rotating drum 31, and has a cylindrical core 61 having a diameter smaller than that of the rotating drum 31, and a cylindrical core. A plurality of vanes 62 provided on the outer circumferential surface of 61 and a base 63 for fixing the cylindrical core 61 to the other end of the rotary drum 31 are included.

The cylindrical core 61 is formed in a hollow cylindrical shape, and rotates integrally with the rotating drum 31 to block the flow of hot air in the rotating drum 31 in the horizontal and vertical directions to block the discharge of particulate matter. .

The plurality of vanes 62 are arranged side by side in the longitudinal direction of the cylindrical core 61 in two or more rows on the outer circumferential surface of the cylindrical core 61. In the case of this embodiment, the plurality of vanes 62 are provided on the outer circumferential surface of the cylindrical core 61 in five rows. In addition, one end of each vane 62 is bent at a predetermined angle. Therefore, when the cylindrical core 61 is rotated, the plurality of vanes 62 serves to make the particles evenly in contact with the organic waste floating or falling inside the rotary drying unit 30.

On the other hand, the other end of the rotary drying unit 30 is provided with a discharge unit 80 for discharging the dried organic waste and the dry gas discharged from the rotary drying unit 30. A waste outlet 81 through which the dried organic waste is discharged is provided under the discharge portion 80. In addition, the discharge portion 80 is provided above the waste discharge port 81 is provided with a gas discharge port 82 for discharging the dry gas generated in the process of drying the organic waste with hot air. The gas outlet 82 may be provided with a temperature sensor T4 capable of measuring the temperature of the discharged dry gas. In addition, one side of the discharge unit 80 may be provided with a temperature sensor (T3) that can measure the temperature of the inside of the rotary drying unit (30).

The control unit 70 includes a paddle motor M1 for rotating the rotary member 23 of the transfer unit 20, a transfer motor M2 for rotating the feed screw 22, and a drum motor M3 for rotating the rotating drum 31. And the rotational speed of the stirring motor M4 for rotating the waste agitator 50 can be used to dry the organic waste under appropriate conditions. In addition, the controller 70 may include a display unit which displays the temperature measured by the various temperature sensors T1, T2, T3, and T4 and the flow rate measured by the flow meters F1 and F2.

Hereinafter, the operation of the organic waste drying apparatus 1 using the hot air according to an embodiment of the present invention having the above structure will be described in detail with reference to FIG. 1.

First, the organic waste S to be dried is stored in the hopper 10.

Thereafter, when the feed motor M2 of the feeder 20 is rotated through the control unit 70, the feed screw 22 is rotated so that the organic waste S stored in the hopper 10 is transferred through the inlet 27. It is injected into one side of the rotary drying unit (30). At this time, the control unit 70 rotates the pair of rotary plates 23a provided on the upper side of the conveying screw 22 together with the conveying screw 22 to push the organic waste S toward the conveying screw 22. Therefore, even when the viscosity of the organic waste S is high, tunneling does not occur and can be continuously supplied to the rotary drying unit 30.

Since the inlet 27 connected to the transfer unit 20 is installed above the rotation center of the rotary dryer 30 on one side of the rotary dryer 30, the organic waste S added to one side of the rotary dryer 30. Falls to the bottom of the rotary drying unit (30). At this time, a hot air inlet 48 is provided directly under the inlet 27 so that hot air generated by the hot air supply unit 40 is injected into the rotary drying unit 30. The injected hot air comes into contact with the organic waste S injected from the inlet 27 to dry the organic waste S. On the other hand, the waste stirrer 50 is rotated below the inlet 27 of the organic waste S in the rotary drying unit 30. Therefore, since the organic waste S falling from the inlet 27 is finely crushed by the primary stirring blade 52 of the waste stirrer 50, the organic waste S is uniformly contacted with the hot air injected into the hot air inlet 48.

When the organic waste S falls to the lower portion of the rotary drying unit 30, the dropped organic waste is transferred toward the waste discharge port 81 by the transfer blade 32. At the same time, the organic waste in the lower portion is again conveyed upward of the waste stirrer 50 by a plurality of pickup blades 33 of the rotary drying unit (30). Then, the organic waste S transported upward of the waste stirrer 50 is crushed again by the primary stirring blade 52 of the waste stirrer 50 while falling by its own weight. As described above, since the organic waste S is moved toward the waste outlet 81, the stirring process is repeated by the waste agitator 50, so that the organic waste S is in contact with the hot air, thereby increasing the drying effect.

In addition, the hot air injected into the rotary drying unit 30 through the hot air inlet 48 forms turbulent flow by the plurality of rotors 52, 53, and 54 installed in the waste stirrer 50, thereby causing organic waste (S). Contact with them increases. In particular, the secondary stirring blades 53 of the plurality of rotating bodies 52, 53, and 54 generate swirl flow to promote the turbulence of hot air. In addition, the rotor blade 54 of the plurality of rotors 52, 53, 54 is a gas discharge port in which the dry gas generated by the organic waste S in contact with the hot wind and the particles generated by the dry pulverization of the organic waste S are dried. By preventing the discharge toward the 82 side, the drying gas is allowed to stay in the rotary drying unit 30 for a long time, thereby increasing the drying efficiency.

On the other hand, the hot air obstruction unit 60 installed near the discharge unit 80 at the other end of the rotary drying unit 30 is to prevent the dry gas flow in the rotary drying unit 30 in the horizontal and vertical directions, thereby causing particulate organic matter. Block the discharge of waste (S). In addition, the plurality of vanes 62 of the hot air blocker 60 collide with the dried organic waste S to even out the size of the dried organic waste S. FIG.

As described above, the organic waste drying apparatus 1 using the hot air according to an embodiment of the present invention may be continuously introduced into the rotary drying unit 30 even when the organic waste S has a high viscosity due to a high water content. During the drying process, the organic waste S is pulverized so as not to be agglomerated so that the organic waste S can be sufficiently dried even if the load or properties of the organic waste S change. In addition, the rotary drum 31 has a double structure to increase the thermal insulation efficiency, make the hot air turbulent by the waste agitator 50, and increase the contact with the pulverized organic waste (S) to maximize the drying efficiency. It can reduce the drying time and lower the drying temperature. Therefore, energy consumption can be reduced.

In addition, the organic waste drying apparatus 1 using the hot air according to an embodiment of the present invention, since the organic waste is dried through the above process, it is possible to discharge the organic waste of dense and evenly dried particles as a final result. It is possible to minimize the emission of particulate matter.

In addition, the organic waste dried by the organic waste drying apparatus 1 using the hot air according to an embodiment of the present invention can be recycled as an adsorbent or a soil cover agent through a subsequent process, thereby dramatically reducing the amount of waste. Can be. Therefore, the occurrence of secondary social problems such as environmental pollution can be reduced.

1 is a view schematically showing an organic waste drying apparatus using hot air according to an embodiment of the present invention;

2 is a perspective view illustrating a hopper and a transfer unit of the organic waste drying apparatus using the hot air of FIG. 1;

3 is a plan view showing the hopper and the transfer portion of FIG.

Figure 4 is a perspective view showing a rotary drying unit of the organic waste drying apparatus using the hot air of Figure 1;

FIG. 5 is a cross-sectional view of the rotary dryer of FIG. 4 taken along line 3-3; FIG.

6 is a perspective view illustrating a hot air blocker of the organic waste drying apparatus using the hot air of FIG. 1.

* Description of the symbols for the main parts of the drawings *

One; Organic waste drying apparatus 10; Hopper

20; Transfer section 21; Connecting pipe

22; Feed screw 23; Rotating member

30; Rotary dryer 31; Rotating drum

32; Feed vane 33; Pickup wings

35; Insulation member 40; Hot air supply

41; Combustion chamber 42; Chimney

43; Gas burner 44; Fuel gas cylinder

45; Blower 47; Hot air line

48; Hot air inlet 49; Hot air distribution plate

50; Waste stirrer 51; Axis of rotation

52; Primary stirring blade 53; 2nd stirring wing

54; Rotary wing 60; Hot air jammer

61; Circular core 62; Bain

70; A controller 80; Discharge

81; Waste outlet 82; Gas outlet

M1, M2, M3, M4; Motors T1, T2, T3, T4; temperature Senser

F1, F2; Flow meters V1 and V2; valve

Claims (5)

A hopper for storing organic waste; A transfer unit installed under the hopper and supplying organic waste stored in the hopper; A rotary drying unit rotatably installed at one side of the transfer unit and discharging to the waste outlet while rotating the organic waste supplied into the transfer unit; And It is installed on one side of the transfer unit, the hot air supply for supplying hot air for drying the organic waste into the rotary drying unit; includes; The transfer unit and the connecting pipe for connecting the hopper and the rotary drying unit, A feed screw installed in the connection pipe and transferring organic waste stored in the hopper to the rotary drying unit; And a rotating member rotatably installed above the conveying screw in the hopper and moving the organic waste to the conveying screw. The method of claim 1, The rotating member includes a pair of rotating plate to rotate facing each other, The pair of rotating plates is rotated by a paddle motor, organic waste drying apparatus using hot air. The method of claim 1, The rotary drying unit, A rotating drum installed to be rotatable in a hollow cylindrical shape; A transfer blade spirally formed along the inner surface of the rotary drum from one end of the rotary drum to the other end so as to move the organic waste supplied by the transfer unit to the waste discharge port; And And a plurality of pickup wings formed on an inner surface of the rotating drum in parallel to each other in the longitudinal direction of the rotating drum. The method of claim 1, A waste stirrer installed inside the rotary drying unit so as to rotate independently from the rotary drying unit, the waste stirrer including a plurality of primary stirring blades for pulverizing the organic wastes supplied from the hopper; Organic waste drying apparatus using hot air. The method of claim 1, The organic waste using the hot air further comprises a; hot air obstruction unit is installed to rotate integrally with the rotary drying unit inside the rotary drying unit, the hot air obstructor formed to block the flow of hot air moving to the other end of the rotary drying unit. Drying equipment.

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