KR101003006B1 - A combustion device and carbonization system - Google Patents

Abstract

The present invention provides dry gas and odor containing harmful gases generated in drying and carbonization plants while being able to recycle preheated air and hot air to reduce the consumption of fuel provided to generate hot air and heated steam in a combustion furnace. It is a combustion furnace and carbonization system having a dry gas removal function that collects a lamp and causes it to be burned by re-supply to a combustion furnace to discharge the air from which harmful gases have been removed.

The present invention is a combustion furnace 10 in which the outside air is sucked and heated to discharge hot air and heated steam, and a secondary drying apparatus 20 for drying the sludge by receiving heating steam through the combustion furnace 10; The carbonization furnace 30 receives the hot air generated through the combustion furnace 10, and the hot air discharged through the carbonization furnace 30 is supplied again, and the heated steam discharged through the secondary drying device is supplied. Drying gas and carbonized gas generated in the primary and secondary drying apparatuses 20 and 40 and the carbonization furnace 30 are composed of the primary drying apparatus 40 which is resupplied. After being supplied to the dry gas inlet 14 and removed by the heat of the combustion furnace 10, the purified air is discharged to the atmosphere.

Combustion furnace, carbonization furnace, organic waste, hot air

Description

A combustion device and carbonization system with dry gas removal

The present invention relates to a combustion furnace and a carbonization system having a dry gas removal function, and more specifically, to remove harmful components of dry gas by supplying the dry gas generated in the process of drying and carbonizing the sludge to the combustion furnace. The present invention relates to a combustion furnace and a carbonization system having a dry gas removal function for releasing a purified exhaust gas to the atmosphere.

In general, organic wastes such as sewage and wastewater sludge and food waste are high in water content and are easily decayed, so when they are buried in the ground, they can cause serious environmental pollution such as soil pollution and groundwater pollution by leachate, and can be incinerated. In this case, air pollution may occur.

In order to solve various problems caused by landfilling and incineration of organic wastes, various methods for drying and carbonizing organic wastes and recycling them as carbides have been proposed.

As shown in FIG. 1, an inlet 210 through which external air is introduced and a outlet 220 through which heated hot air and steam are discharged to provide hot air and heated steam for drying and carbonizing sludge as shown in FIG. 1. Hot air having an appropriate temperature (800 to 950 ° C.) by heating the external air inhaled by forming the outer cylinder 200 and the heating means 100 such as a burner on one side of the outer cylinder 200, respectively. To provide.

However, the hot air and heated steam heated in the combustion furnace are supplied to the drying apparatus and the carbonization furnace and then discharged to the outside, and the new external air is sucked in and heated to heat the fuel. In addition, dry gas and odor generated during the carbonization and drying process are discharged without purification in the air, causing a problem of polluting the air.

The present invention has been proposed in order to solve the above-mentioned conventional problems, and a carbonization system capable of recycling preheated air and hot air to reduce consumption of fuel provided to generate hot air and heated steam in a combustion furnace. To provide.

In addition, to provide a combustion furnace that collects dry gas and odors, including harmful gas generated in the drying and carbonization unit to be burned by re-supply to the combustion furnace to discharge the air from which the harmful gas is removed to the atmosphere. have.

The present invention describes the technical configuration means for implementing the above object,

External air is sucked into the outside through the air inlet and generates hot air and steam through one side heating means, and has an inner tube for discharging it to the other side of the hot air outlet and the steam outlet. A combustion furnace having an outer tube forming a space, having a dry gas inlet on one side of the outer tube, and a dry gas outlet on the other side to allow the dry gas to flow into and remove the space between the inner tube and the outer tube; Secondary drying apparatus for drying the sludge by receiving the heated steam through the combustion furnace, a carbonization furnace to receive the hot air generated through the combustion furnace, and the hot air discharged through the carbonization furnace to be supplied again, 2 This is accomplished by the configuration of a primary drying device that is resupplied with heated steam discharged through the primary drying device.

On the other hand, in the present invention, the combustion furnace, it may be carried out by having a spiral guide plate on the outer peripheral surface of the inner tube, the carbonization furnace is a carbonization tube provided with a sludge inlet and a carbide discharge port, and the rotary shaft inside the carbonization tube And a sludge conveying / stirring means including a screw blade and a hot air inlet and a hot air outlet, which surround the outer side of the carbonization tube and are spaced apart from the carbonization tube to form an inner space, and the hot air is introduced to one side and discharged to the other side. It may be implemented as an outer cylinder.

By using a carbonization system including a combustion furnace having a dry gas removal function of the present invention as described above, the consumption of fuel consumed to heat the air by recycling the preheated air and hot air to supply to the drying furnace and carbonization furnace It also has the advantage of effectively reducing the gas, and also by collecting the harmful gas and carbon dioxide and odor generated from the carbonization furnace and drying equipment to the combustion furnace to be combusted, through which the harmful gas is removed to the air This has the advantage of preventing air pollution.

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

2 is a configuration diagram showing an example of a combustion furnace and carbonization system having a dry gas removal function of the present invention, Figure 3 is a combustion furnace of a combustion furnace and carbonization system having a dry gas removal function of the present invention 4 is a side cross-sectional view showing an example of a secondary drying apparatus of the combustion furnace and carbonization system having a dry gas removal function of the present invention, Figure 5 is a dry gas removal function of the present invention Side cross-sectional view showing an example of the primary drying apparatus of the combustion furnace and carbonization system provided, Figure 6 is a side cross-sectional view showing an example of the carbonization furnace of the combustion furnace and carbonization system with a dry gas removal function of the present invention. Indicated.

Referring to these drawings,

As shown in FIG. 2, the secondary drying apparatus 20 for drying the sludge by receiving heating steam through the combustion furnace 10 and the carbonization furnace 30 receiving the hot air generated through the combustion furnace 10 are provided. It is provided with each, and is supplied with the hot air discharged to pass through the carbonization furnace 30, and is provided with a primary drying device 40 for resupplying the heated steam discharged through the secondary drying device (20).

As shown in Figure 3, the combustion furnace 10 is provided with a heating device (B) for providing hot air on one side to heat the outside air introduced through the outside air inlet 11 to generate hot air and steam. Has an inner tube 10A to be discharged to the hot air outlet 12 and the steam outlet 13 located on the opposite side, the outer tube 10B is provided to form a suitable space on the outer peripheral surface of the inner tube (10A) It is provided with a distillation gas inlet 14 on one side and a distillation gas outlet 15 on the other side so that the distillation gas flowing into the space between the inner tube 10A and the outer tube 10B is heated by high heat.

A spiral guide plate 16 may be provided between the inner tube 10A and the outer tube of the combustion furnace 10 so that the dry gas is guided in a spiral direction and exhausted.

As shown in FIG. 4, the secondary drying apparatus 20 includes a screw shaft 22 having a plurality of stirring blades 21 at an inner lower side thereof, causing the primary dried sludge to float upward at a predetermined height, and heating steam. The heated steam may be supplied to the floated sludge side through the supply pipe 23 to dry the sludge.

The primary drying apparatus 40, as shown in Figure 5, the inner side of the conveying screw 41 provided in the main body 40A of a predetermined size in the longitudinal direction is heated steam is introduced and discharged, the main body ( 40A) the outer circumferential surface may be provided with a jacket portion 40B surrounding a predetermined portion to allow hot air to flow into and out of the jacket portion 40B.

The carbonization furnace 30 has a carbonization pipe 30A provided with a sludge inlet 31 and a carbide outlet 32 as shown in FIG. 6, and a rotation shaft 33A and a screw inside the carbonization pipe 30A. Sludge conveyance / stirring means 33 including the wing 33B, and surrounds the outer side of the carbonization pipe (30A) and spaced apart from the carbonization pipe (30A) to form an inner space, hot air is introduced to one side The outer cylinder 30B having the hot air inlet 34 and the hot air outlet 35 discharged to the other side, and the dry gas generated inside the carbonization pipe 30A are collected to one side of the outer cylinder 30B to burn the furnace ( 10) may be implemented as a dry gas collector (39) for supplying, the outer cylinder (30B) is provided with an external air inlet 36 and the preheated air outlet 37, the external air inlet (36) And a spiral shield pipe 38 for connecting the preheated air outlet 37 to each other.

Combustion furnace and carbonization system having a dry gas removal function of the present invention configured as described above, by using the heating device (B) of the combustion furnace 10 provided on one side to generate hot air and heating steam, and the drying device and Feeding the carbonization furnace to dry and carbonize food waste and organic waste.

To describe this in more detail, the combustion furnace 10 sucks the outside air into the external air suction port 11 communicating with the inner tube 10A side as shown in FIG. 3, and sucks it through the heating device B provided at one side. The heated air is heated to discharge hot air and heated steam to the other hot air outlet 12 and the steam outlet 13, respectively. At this time, the hot air and heated steam are circulated by mixing various dry gas and odor generated from drying and carbonizing sludge such as food waste and organic waste. Into the space between the inner tube 10A and the outer tube 10B of 10) to remove the gas and odor due to the heat.

As described above, the combustion furnace 10 of the present invention includes a function of removing dry gas and odor generated during drying and carbonization, and the dry gas injection port 14 of the outer tube 10B of the combustion furnace 10 is removed. When a predetermined amount of dry gas is input into the gas, the gas and odor are burned and removed by the temperature of the inner tube 10A heated to a constant temperature by the heating device B. At this time, the dry gas flows rapidly in a spiral along the spiral guide plate 16 formed on the outer circumferential surface of the inner tube 10A.

Therefore, in general, the dry gas supplied to the inner tube 10A is lower than the temperature at which the inner tube 10A is heated to take heat from the outer circumferential surface of the inner tube 10A to cool the inner tube 10A.

As a result, the dry gas supplied into the combustion furnace 10 cools the inner tube 10A, and at the same time, the gas is burned due to heat to remove the gas and odor, and then, the air is purged into the atmosphere.

On the other hand, in carrying out the combustion furnace 10 of the present invention, the external air supplied to the inner inner tube (10A) is preheated in the carbonization furnace 30 and then supplied to warm the air at room temperature with hot air at a constant temperature It is more preferable that the fuel consumption is lower than that of the fuel cell and the heating time is short.

As such, the heated steam and hot air generated through the combustion furnace 10 are supplied to the secondary drying apparatus 20 and the carbonization furnace 30, respectively, and used to dry or carbonize the sludge.

When the secondary drying apparatus 20 is described in more detail, as shown in FIG. 4, when the first dried sludge is introduced into the sludge inlet 25, the screw shaft 22 provided at the lower side rotates and the screw shaft 22 is rotated. A plurality of stirring blades 21 provided on the outer circumferential surface is rotated to raise the sludge to a predetermined height. At this time, the sludge is floated upward and is conveyed a predetermined width in all directions.

When the sludge is raised to a certain height in this way, the heated steam is introduced through the one side heating steam supply pipe 23 and the sludge is dried by passing between the sludge. Here, the heated steam supplied through the heated steam supply pipe 23 is discharged to the other heating steam discharge pipe 24, and the heated steam discharge pipe 24 is connected to the heated steam inlet 46 of the primary drying device 40. Reused.

On the other hand, in carrying out the secondary drying apparatus 20 of the present invention, as a means for reducing the temperature deviation of the upper and lower sides of the secondary drying apparatus 20, the upper side is warmed by the heating steam, to the combustion furnace 10 The hot air pipe 12 'for supplying the discharged hot air to the carbonization furnace 30 is provided to abut the bottom surface of the secondary drying apparatus 20, and the secondary air is heated by the temperature of the hot air pipe 12' heated by the hot air. More preferably, the bottom surface of the drying apparatus 20 is heated to reduce the temperature deviation on the upper and lower sides.

The sludge dried through the secondary drying apparatus 20 is discharged through the sludge outlet 26 and supplied to the carbonization furnace 30, and the used heated steam is supplied to the primary drying apparatus 40 and reused.

The primary drying device 40 will be described in more detail. As shown in FIG. 5, the heated steam discharged to the heating steam discharge pipe 24 of the secondary drying device 20 is introduced into the heating steam inlet 46 and stirred / It is supplied to the feed screw 41, the stirring / feed screw 41 is punched in the inner side is formed with a heating steam outlet 47 on the other end.

The heated steam supplied in this way warms the stirring / feeding screw 41 while flowing along the stirring / feeding screw 41, and when the sludge is not dried through the sludge inlet 42, the stirring / transfer is carried out. It dries while hitting the screw 41. At this time, the hot air is supplied to the carbonization furnace 30 to increase the drying efficiency of the sludge, and is supplied to the hot air inlet 44 of the jacket portion 40B surrounding the outer circumferential surface of the main body 40A by supplying hot air discharged after use. The outer peripheral surface is warmed, and as a result, the center side stirring / feeding screw 41 and the jacket portion 40B of the main body 40A are warmed, and the sludge is evenly dried.

The hot air and heated steam used here and discharged to the hot air outlet 45 and the heated steam outlet 47 are mixed with odors and harmful gases generated during the drying process of the sludge, and the dry gas input port 14 of the combustion furnace 10 is used. ) Is supplied and removed.

Meanwhile, the carbonization furnace 30 to which hot air is first supplied is supplied to the internal carbonization pipe 30A by receiving the sludge dried through the secondary drying apparatus 20 through the sludge inlet 31, and transferring / stirring means 33. Is fed / stirred and carbonized by the screw blade 33B. At this time, the outer cylinder 30B surrounding the outer circumferential surface of the carbonization pipe 30A is supplied with high temperature hot air through the hot air inlet 34 to heat the inner carbonization pipe 30A.

In addition, the outer cylinder 30B may be implemented by further including air preheating means that sucks the outside air through the external air inlet 36 and is heated by hot air and discharged to the other preheating air outlet 37. This prevents the hot air and the outside air from being mixed with each other by connecting the external air inlet 36 and the preheated air outlet 37 through the spiral shield pipe 38, and shields the hot air by heating the side of the shield pipe 38. The air passing through the inside of the pipe 38 is preheated. At this time, due to the temperature difference between the air flowing through the shielding pipe 38 and the hot air, not only the internal carbonization pipe 30A is heated by the hot air, but also the cooling of the external air causes the carbonization pipe 30A to be excessively heated. prevent.

As such, the sludge introduced into the carbonization pipe 30A is carbonized while being transferred to the other end through the transfer / stirring means 33, and the sludge is carbonized and discharged through the carbide outlet 32, and interlocked with a crushing device and a storage device. Is processed using.

On the other hand, harmful gas and odor generated in the process of carbonization of the sludge is collected through the dry gas collector (39), is supplied to the dry gas input port 14 of the combustion furnace 10 through the dry gas transfer pipe (39A) After the gas and odor are removed, the air is discharged into the atmosphere, and the air preheated through the preheating air outlet 37 is supplied to the external air inlet 11 of the combustion furnace 10 so that the combustion furnace 10 generates hot air. Reduce fuel consumption.

1 is a side cross-sectional view showing an example of a conventional combustion furnace.

Figure 2 is a block diagram showing an example of a combustion furnace and carbonization system with a dry gas removal function of the present invention.

3 is a side cross-sectional view showing an example of a combustion furnace and a carbonization system having a dry gas removal function of the present invention.

Figure 4 is a side cross-sectional view showing an example of the secondary drying apparatus of the combustion furnace and carbonization system with a dry gas removal function of the present invention.

Figure 5 is a side cross-sectional view showing an example of the primary drying device of the combustion furnace and carbonization system with a dry gas removal function of the present invention.

Figure 6 is a side cross-sectional view showing an example of a carbonization furnace of the combustion furnace and carbonization system with a dry gas removal function of the present invention.

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

10: combustion furnace 10A: inner tube

10B: External clearance 11: External air intake

12: hot air outlet 12 ': hot air pipe

13: steam outlet 14: dry gas inlet

15: dry gas outlet 16: spiral guide plate

20: secondary drying apparatus 21: stirring blade

22: screw shaft 23: heating steam supply pipe

24: heated steam discharge pipe 25: sludge inlet

26: sludge outlet 30: carbonization furnace

30A: carbonized pipe 30B: outer cylinder

31: sludge inlet 32: carbide outlet

33: feed / stirrer 33A: axis of rotation

33B: Screw vane 34: Hot air inlet

35: hot air outlet 36: outside air inlet

37: preheated air outlet 38: shielded tube

39: dry gas collector 39A: dry gas transfer pipe

40: primary drying apparatus 40A: main body

40B: Jacket 41: Stirring / Feed Screw

42: sludge inlet 43: sludge outlet

44: hot air inlet 45: hot air outlet

46: heated steam inlet 47: heated steam outlet

B: heating device

Claims (6)

delete Hot air and through the heating device (B) the outer tube 10B having a dry gas inlet 14 on one side and a dry gas discharge port 15 on the other side, and external air sucked into the outer tube 10B A combustion furnace 10 each having an inner tube 10A for generating steam and discharging the hot air discharge port 12 and the steam discharge port 13; A secondary drying apparatus 20 for drying the sludge by receiving heating steam through the combustion furnace 10; A carbonization furnace 30 receiving hot air generated through the combustion furnace 10; Drying gas removal function, characterized in that consisting of the primary drying device 40 receives the hot air discharged through the carbonization furnace (30) and the supply of heated steam discharged through the secondary drying device. As a combustion furnace and carbonization system, The combustion furnace 10 is provided with a spiral guide plate 16 on the outer circumferential surface of the inner tube 10A, and the helical induction gas supplied through the dry gas inlet 14 is formed on the outer circumferential surface of the inner tube 10A. A combustion furnace and carbonization system having a dry gas removal function, which is guided by a plate (16) to increase the residence time of the dry gas, thereby increasing the effect of removing the dry gas. 3. The method of claim 2, The secondary drying apparatus 20 is provided with a screw shaft 22 having a plurality of stirring blades 21 on the lower side of the inside, to raise the first dried sludge to a predetermined height upwards, the heating steam supply pipe 23 Drying gas removal function characterized in that the heated steam is supplied to the floated sludge side through the dried sludge, and the remaining heated steam is discharged through the heated steam discharge pipe 24 to be supplied to the primary drying device 40. Combustion furnace and carbonization system having a. 3. The method of claim 2, The primary drying device 40 is provided with a stirring / feeding screw 41 inside the main body 40A of a predetermined size, and the inside of the stirring / feeding screw 41 is bored in the longitudinal direction so that heated steam flows in / The combustion furnace and carbonization furnace having a dry gas removal function, characterized in that it is provided with a jacket portion (40B) surrounding a certain portion of the outer peripheral surface of the main body (40A) so that hot air flows into / out of the jacket portion (40B). system. 3. The method of claim 2, The carbonization furnace 30 includes: a carbonization pipe 30A having a sludge inlet 31 and a carbide outlet 32; Sludge conveyance / stirring means (33) comprising a rotary shaft (33A) and a screw blade (33B) inside the carbonization pipe (30A); An outer cylinder having a hot air inlet 34 and a hot air outlet 35 that surrounds the outer side of the carbonization pipe 30A and is spaced apart from the carbonization pipe 30A by a predetermined distance to form an inner space, and the hot air flows into one side and is discharged to the other side. Sieve 30B; Combustion with a dry gas removal function, characterized in that it consists of a dry gas collector (39) for collecting the dry gas generated inside the carbonization pipe (30A) to one side of the outer cylinder (30B) to supply to the combustion furnace (10). Furnace and carbonization system. The method of claim 5, The outer cylinder 30B includes an external air inlet 36 and a preheated air outlet 37, and further includes a spiral shield pipe 38 connecting the external air inlet 36 and the preheated air outlet 37. Combustion furnace and carbonization system having a dry gas removal function, characterized in that.

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