KR100894899B1 - Ultra-high-temperature heat using dryness system - Google Patents

Abstract

An ultra-high temperature dry system is provided to dry and transfer waste quickly by forming a first drying part having smaller diameter than the diameter of the second drying part. An ultra-high temperature dry system comprises: an RPF(Refuse Plastic Fuel) burner(10) producing hot air having high temperature and high speed; a waste feed part(20) transferring waste; a first drying part(30) drying the waste, emitted from the waste feed part, with the hot air generated in the RPF burner; a second drying part(40) secondly drying the waste passed through the first drying part; a discharging part(A) discharging the waste passed through the second drying part; and a disc(50) transferring the waste to the second drying part which is in outside when the waste is transferred by the hot air having high temperature and high speed produced in the RPF burner in the end of the first drying part.

Description

ULTRA-HIGH-TEMPERATURE HEAT USING DRYNESS SYSTEM

The present invention relates to an ultra-high temperature drying system for drying wastes by using high temperature hot air, and more particularly, in the form of a spray-like spray when supplying wastes, thereby increasing the spacing between waste particles and increasing drying efficiency. Fast primary drying is performed by the high temperature / high speed hot air generated by the RPF (Refuse Plastic Fuel) burner, and at the same time, the hot air can be used to quickly transfer the waste during primary drying. The secondary drying unit takes the form of a double pipe and takes up the space of the subsidiary facility, so that the space can be utilized, and the primary drying unit has a smaller diameter than the secondary drying unit, so that it can be quickly dried and transported. In addition, it is caused by hot air transferred from the first drying unit together with the waste and heat emitted from the outside of the first drying unit. It relates to an ultra-high temperature drying system that can increase the efficiency of removing odors and gases by burning the odor and gas generated during the first and second drying of the waste by the secondary drying effect and the secondary combustion unit. .

In general, the waste treatment system 200a includes a burner 210a and primary and secondary drying units 220a and 230a as shown in FIG. 1, and injects waste from the primary drying unit 220a. It is configured to handle.

At this time, the pipe line L is provided so that the smell and the gas which generate | occur | produce in the primary dryer 220a can be burned again.

However, the waste treatment system 200a as described above has a problem in that waste is transported in a direction opposite to the hot air generated by the burner 210a, thereby reducing thermal efficiency.

In order to solve this problem, as shown in FIG. 2, the primary drying unit 220b is configured to be adjacent to the burner 210b, and the secondary drying unit 230b receiving the waste is transferred from the primary drying unit 220b. In addition, the waste treatment system 200b configured to be able to increase the thermal efficiency by injecting waste into the primary drying unit 220a.

However, in the conventional waste treatment system 200b as described above, since the waste is dried using the hot air generated by the burner 210b while the first and second dryers 220b and 230b are connected in series, drying efficiency is increased. There was a significant decrease and there was a problem in that a lot of fuel costs occur when the temperature of the burner (210b) to form a high temperature to overcome this.

In addition, the method of transferring waste from the primary dryer 220b is configured to be made slowly through the rotation. At this time, since the primary dryer 220b is large, the amount of waste that can be dried is not only small but also incompletely waste. Since it is dried, there was a problem that it is difficult to achieve the purpose of drying the waste.

At this time, since the primary dryer 220b dries the waste with a limited hot air in a state where the size of the primary dryer 220b is large so as to dry a large amount of waste, it is difficult to achieve the purpose of drying the waste.

In addition, even when connected in parallel or in series in the installation of the primary and secondary dryers, as the size of the auxiliary facilities is expanded, the problem of difficult space utilization was exposed.

The ultra-high temperature drying system of the present invention for solving the above problems forms an RPF burner for forming hot / high speed hot air, and a waste supply part for transporting waste, in order to process waste using high temperature heat. A secondary drying unit configured to dry the waste sprayed from the waste supply unit by being moved by the hot / high speed hot air generated in the RPF burner, and to dry the waste that has passed through the primary drying unit again; In the ultra-high temperature drying system having a discharge port for discharging the waste passed through the secondary drying unit, at the end of the primary drying unit, when the waste is transported by hot / high speed hot air generated by the RPF burner It characterized in that the disk is formed to be transferred to the secondary drying unit.

The waste supply unit of the ultra-high temperature drying system of the present invention is connected to the primary drying unit, characterized in that the pump is formed to form a pressure for supplying the waste to the primary drying unit.

The primary drying unit of the ultra-high temperature drying system of the present invention is characterized in that it is made in the form of a double pipe inside the secondary drying unit.

At the end of the primary drying unit of the ultra-high temperature drying system of the present invention, when the waste is transported by the high temperature / high speed hot air generated by the RPF burner, a disk is formed so as to be transported to the secondary drying unit outside. .

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Inside the secondary drying unit of the ultra-high temperature drying system of the present invention is characterized in that the stirring blade for stirring the waste is provided.

The secondary drying unit of the ultra-high temperature drying system of the present invention includes a cooling air generating device for generating cooling air, and a cooling air passage configured to cool the outside of the secondary drying unit by receiving air from the cooling air generating device. It further comprises a cooling unit configured in the form.

In order to combust harmful substances such as odors and gases generated in the secondary drying unit of the ultra-high temperature drying system of the present invention to form a harmful substance moving passage connected to the secondary drying unit, and to form a hot air duct connected to the RPF burner Further, characterized in that it further comprises an auxiliary combustion section consisting of an exhaust port for burning through the hot air and exhaust and harmful substances moved through the harmful substance pipe.

An outer side of the secondary drying unit of the ultra-high temperature drying system of the present invention is characterized by further forming an angle adjusting unit capable of adjusting the angle by the circular angle adjusting shaft made of a pair of two outside the secondary drying unit.

The discharge port of the ultra-high temperature drying system of the present invention is characterized in that it further forms a transfer pipe for transporting the remaining waste after combustion to the RPF burner to recycle the remaining fuel after combustion discharged to the exhaust.

In the ultra-high temperature drying system of the present invention, the primary drying is performed by the high temperature / high speed hot air generated by the RPF burner, and at the same time, the waste can be quickly transferred during the primary drying using the hot air.

In addition, since the primary and secondary drying units take the form of double pipes, they occupy less space and can utilize the space, and the primary drying units are made of smaller diameters than the secondary drying units. Not only is it possible to transfer quickly, but there is an effect of increasing the drying efficiency in the secondary drying unit by the hot air transferred together with the waste in the primary drying unit and the heat emitted from the outside of the primary drying unit.

In addition, the secondary combustion unit may burn the odor and gas generated during the second drying of the waste, thereby increasing the efficiency of removing the odor and the gas.

In addition, it is a useful invention that can reduce the fuel cost by recycling the spent solid waste fuel made of the first and second drying.

Is a useful invention.

Hereinafter, the configuration of the present invention with reference to the accompanying drawings in more detail.

As shown in FIG. 3, the RPF burner 10 generates hot / high speed hot air, a waste supply unit 20 for supplying waste, and primary and secondary drying units 30 and 40 for drying waste. ) And an outlet A for discharging waste.

The RPF burner 10 is configured to form hot air at high temperature / high speed by using RPF (solid fuel: Refuse Plastic Fuel) as a normal burner.

Here, the waste supply unit 20 is formed of a conventional pump that can form a pressure to transfer the waste, the primary drying unit (to dry the waste to the primary drying unit 30) It is configured to be connected to 30 and configured to be sprayed by blowing the waste with the hot air generated by the RPF burner 10 instantaneously.

On the other hand, the primary drying unit 30 is configured so that the waste is first dried after being transferred by the hot air generated in the RPF burner 10, the waste dried in the primary drying unit 30 is 2 The secondary drying unit 40 is configured to be dried by car.

The first and second drying units 30 and 40 are configured in the form of a double pipe so as not to occupy much of the space of the auxiliary facilities, and the first drying unit 30 is formed of a smaller diameter than the secondary drying unit 40. The waste is transported by the hot / high speed hot air generated by the RPF burner 10, and the waste may be dried by the hot air.

Here, the hot air of the RPF burner 10 is configured to be introduced only to the primary drying unit 30 to increase the drying efficiency in the primary drying unit 30.

In addition, the disk 50 is further provided at the end of the primary drying unit 30 so that the waste dried in the primary drying unit 30 can be transferred to the secondary drying unit 40.

Since the disk 50 is transferred from the primary drying unit 30 by hot / high speed hot air, the disk 50 is configured in a plate shape so that the waste to be transported at high speed is no longer advanced. Waste to be transported at a high speed in the) hit the disk 50 is configured to be naturally transported to the secondary drying unit (40).

On the other hand, the secondary drying unit 40 is configured to dry the waste secondary by using the heat generated from the primary drying unit 30 in a state that does not supply a separate hot air.

That is, the hot air generated at the high temperature / high speed of the RPF burner 10 hits the disk 50 together with the waste in the primary drying unit 30 and the heat source generated outside the primary drying unit 30. All are configured to be available.

In addition, the secondary drying unit 40 is provided with a stirring blade 41 is configured to evenly dry the entire waste during drying of the waste transferred from the primary drying unit 30.

In addition, the secondary drying unit 40 may further configure the cooling unit 60 to the outside in consideration of the safety of the user.

The cooling unit 60 is provided with a cooling air passage 62 in the form of a double pipe on the outside of the cooling air generating device 61 and the secondary drying unit 40 to cool the outside of the secondary drying unit 40. It is configured to achieve the effect.

On the other hand, in the present invention, the secondary combustion unit 70 may be further configured to burn odors such as odors and harmful gases such as VOS generated when the wastes are dried in the primary and secondary drying units 30 and 40. .

The auxiliary combustion unit 70 is for burning harmful substances such as odors and gases generated when the secondary drying unit 40 is dried, and is connected to the secondary drying unit 40 and the secondary drying unit 40. ) Is connected to a hot air pipe (72) connected to the RPF burner (10) in order to receive a hot / high speed hot air from the RPF burner (10) and a harmful material moving pipe (71) capable of moving a hazardous material from the RPF burner (10). The exhaust port 73 is formed, and the exhaust port 73 is configured to be discharged to the outside after burning harmful substances.

Then, as shown in FIG. 4, the angle adjusting unit 80 is configured to the outside of the secondary drying unit 40 so that waste can be transferred from the secondary drying unit 40 to the outlet A. FIG.

The angle adjusting unit 80 is typically composed of a circular angle adjusting shaft 81 of a pair of two forms that can adjust the angle, the secondary drying unit as the angle adjusting shaft 81 is moved 40 is configured to adjust the angle while tilting.

In addition, in the present invention, so that the RPF burner 10 can be driven using the waste discharged through the first and second drying units 30 and 40 to the outlet A, the outlet A and the RPF burner ( 10) may further comprise a transfer pipe (90) for connecting.

Here, in the case of waste discharged through the outlet A, since the moisture content is very small while passing through the first and second dryers 30 and 40, it is possible to use as a fuel of the RPF burner 10 as described above. At this time, although not shown in the drawing, it is natural that a separate motor may be further mounted to transfer the fuel of the outlet A to the RPF burner 10.

Looking at the preferred embodiment of the ultra-high temperature drying system of the present invention having the configuration as described above are as follows.

First, when the RPF burner 10 of the ultra-high temperature drying system 100 of the present invention is filled with RPF fuel and applied with normal power, the RPF burner 10 operates to form hot / high speed hot air. At the same time, the waste supply unit 20, which is made of a conventional pump, transfers waste to the primary drying unit 30.

Here, the waste may be composed of various wastes, such as a form containing water, or a form containing no water, a form containing only water.

In addition, in the RPF burner 10, the hot air is formed at a high temperature by using the RPF fuel. At this time, the flame is moved to the primary drying unit 30 at a high speed by a general motor (not shown). .

On the other hand, the waste transported to the primary drying unit 30 is instantaneously dried by hot / high speed hot air, and passes through the primary drying unit 30 at a high speed.

This is because the primary drying unit 30 has a diameter smaller than that of the secondary drying unit 40, and uses a high temperature / high speed hot air formed in the RPF burner 10, and at the same time, the drying speed is fast. The feed rate will also be faster.

In addition, since the hot air generated by the RPF burner 10 is introduced only to the primary drying unit 30, the drying and transport of the waste is possible without the temperature and speed of the hot air being reduced.

On the other hand, the waste dried in the primary drying unit 30 as described above is the secondary drying unit 40 formed in the form of a double pipe to the outside of the primary drying unit 30 by the disk 50 in a state where the drying is almost complete. Is moved to).

The disk 50 is formed because hot wind including waste introduced into the primary drying unit 30 is transferred at a high speed. The hot air and waste are dispersed in the secondary drying unit 40 by the disk 50. It falls and is conveyed.

In addition, the waste transported to the secondary drying unit 40 is the secondary drying unit by the hot air transferred with the waste in the primary drying unit 30 and the high temperature heat emitted from the outside of the primary drying unit 30 As the 40 is rotated, drying is performed secondarily.

At this time, the waste is transported in the rotational direction when the secondary drying unit 40 is rotated by the stirring blade 41 formed in the secondary drying unit 40 so as to drop when reaching a certain height. It acts to evenly dry the wastes evenly.

Since the secondary drying unit 40 has already been conveyed in the state where the waste is almost completely dried by the hot air in the primary drying unit 30, the secondary drying unit 40 passes through the primary drying unit 30 as described above. The secondary air can be sufficiently dried only by hot air and heat emitted from the outside of the primary drying unit 30.

On the other hand, by using the angle adjusting unit 80 formed on the outside of the secondary drying unit 40, the secondary drying unit 40 is operated to be inclined at a predetermined angle while the secondary drying of the waste is made (A) To move smoothly).

The angle adjusting unit 80 is a device capable of adjusting the normal angle, as shown in FIG. 4, when the angle adjusting shaft 81 is retracted by the angle adjusting shaft 81 formed of two sets, secondary drying. The portion 40 is disposed at a position higher than the outlet A, so that the waste is secondaryly dried, so that the transfer can be performed smoothly.

Here, the angle adjusting unit 80 to adjust the angle in consideration of the input amount of the waste and the moving speed drying rate.

In addition, in the present invention, the cooling unit 60 formed in the form of a double pipe to the outside of the secondary drying unit 40 acts to reduce the heat released to the outside of the secondary drying unit 40 during waste drying.

The cooling unit 60 is an air cooling method for supplying and cooling air to generate cooling air through the cooling air generating device 61, and then to the cooling air passage 62 formed outside the secondary drying unit 40. By injecting cooling air into the furnace.

On the other hand, harmful substances such as odors and gases generated when the wastes are dried in the secondary drying unit 40 are moved to the auxiliary combustion unit 70 and burned and then discharged to the outside.

The auxiliary combustion unit 70 is one side is connected to the harmful substance moving pipe 71 that can move the harmful substances generated in the secondary drying unit 40, the other side is the high temperature / generated in the RPF burner 10 In the exhaust port (73) connected to the hot air duct (72) connected to the RPF burner (10) to receive a part of the high-speed hot air, it functions to burn out harmful substances and to discharge them to the outside. Will be able to achieve.

1 is a block diagram showing a conventional waste drying system

Figure 2 is a block diagram showing a drying system of another conventional embodiment

Figure 3 is a cross-sectional view showing an ultra high temperature drying system according to the present invention.

Figure 4 is a side view shown in part A according to the present invention.

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

10: RPF burner 20: waste supply

30: primary drying unit 40: secondary drying unit

41: stirring blade 50: disk

60: cooling unit 61: cooling air generating device

62: cooling air passage 70: auxiliary combustion section

71: Hazardous substance transfer pipe 72: Hot air pipe

73: exhaust port 80: angle adjustment unit

81: angle adjusting shaft A: outlet

100: Ultra high temperature drying system

Claims (11)

In order to process waste using high temperature heat, RPF burner 10 for forming hot / high speed hot air and waste supply unit 20 for conveying waste are formed, and the waste sprayed from the waste supply unit 20 is formed. The primary drying unit 30 is formed to be dried while moving by the high temperature / high speed hot air generated in the RPF burner 10, and the waste passing through the primary drying unit 30 is dried again. In the ultra-high temperature drying system having a secondary drying unit 40, and an outlet A for discharging the waste passed through the secondary drying unit 40, At the end of the primary drying unit 30, when the waste is transported by the hot / high speed hot air generated by the RPF burner 10, the disk 50 can be transported to the secondary drying unit 40 on the outside. Ultra-high temperature drying system characterized by the formation of). The ultra-high temperature drying system of claim 1, wherein the waste supply unit 20 is formed of a pump connected to the primary drying unit 30 to form a pressure for supplying waste to the primary drying unit 30. . The ultra-high temperature drying system according to claim 1, wherein the primary drying unit (30) is formed in the form of a double pipe inside the secondary drying unit (40). delete delete The ultra-high temperature drying system according to claim 1, wherein a stirring vane (41) capable of stirring the waste is provided inside the secondary drying unit (40). The method of claim 1, wherein the secondary drying unit 40 is supplied with air from the cooling air generating device 61 for generating cooling air, and the cooling air generating device 61 of the secondary drying unit 40 Ultra-high temperature drying system, characterized in that the cooling air passage 62 configured to cool the outside further comprises a cooling unit 60 configured in the form of a double pipe. According to claim 1, To form a harmful substance moving pipe 71 connected to the secondary drying unit 40 to burn harmful substances such as odors and gases generated in the secondary drying unit 40, the RPF It forms a hot air pipe passage 72 connected to the burner 10, and further formed an auxiliary combustion unit 70 consisting of an exhaust port 73 for discharging the harmful substances moved through the harmful substance pipe through the exhaust and hot air. Ultra-high temperature drying system characterized by The ultra-high temperature drying system according to claim 1, further comprising an angle adjusting unit (80) formed outside the secondary drying unit (40). 10. The ultra-high temperature drying system according to claim 9, wherein the angle adjusting part (80) is angled by a circular angle adjusting shaft (81) formed of two pairs outside the secondary drying part (40). . According to claim 1, The discharge port (A) is further formed with a transfer pipe 90 for transporting the remaining waste after combustion to the RPF burner 10 to recycle the remaining fuel after combustion discharged to the discharge (A) as fuel. Ultra-high temperature drying system characterized by.

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