KR101110699B1 - Rotary kiln - Google Patents

Abstract

The present invention relates to a rotary kiln suitable for use in an apparatus for incineration and melting of waste such as industrial waste or general waste, and an air inlet hole 120a is formed in the outer cylinder 120 constituting the rotary kiln 100. The inner cylinder 110 constituting the rotary kiln 100 has an air supply line 111 that induces and discharges the air introduced through the air inlet hole 120a of the outer cylinder 120 to the inner hole 100a of the rotary kiln 100. , 111 ', 112, 113 are provided, the rotary kiln 100 is to directly supply the air to promote combustion to the waste inside the rotary kiln 100, and to the rotary kiln inner hole (100a) Since the discharge line 113 for ejecting air is continuously moved along the circumferential direction, the external air is ejected to the rotary kiln inner hole 100a, so that the external air is evenly ejected to the rotary kiln inner hole 100a, Kite of the Kiln (100) Small function is greatly improved.

Rotary kiln, rotary kiln, combustion, incineration, melting

Description

Rotary kiln with excellent combustion function {Rotary kiln}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rotary kiln with excellent combustion function, and more particularly to a rotary kiln suitable for use in an apparatus for incineration and melting of waste such as industrial waste or general waste.

As is well known, a rotary kiln made of a refractory cylinder is installed to rotate at a gentle speed at a slightly inclined state, and generally blows flame into the rotary kiln, and feeds the raw material toward the entrance of the relatively high rotary kiln. As the raw material injected into the inlet of the rotary kiln is agitated and burned and dissolved in the rotary kiln, it is naturally moved to the exit of the rotary kiln, which is located relatively low, and discharged to the outside of the rotary kiln.

On the other hand, the fuel injected into the rotary kiln is forced to blow the air to the inside of the rotary kiln to better burn, so that the combustion of the fuel is promoted.

However, the conventional rotary kiln has a simple cylindrical structure, in order to force air into the rotary kiln, the air must be blown toward the inlet of the rotary kiln. When the air is blown into the inlet of the rotary kiln, the rotary kiln Since the air blown inside is not supplied to the inside of the rotary kiln where the fuel is located and most of the air is moved along the inside of the rotary kiln and discharged to the outside, fuel injected into the rotary kiln is satisfactorily burned and dissolved. It didn't work.

Therefore, researches on how to make the fuel injected into the rotary kiln burn better are being studied in various fields, some of which are already being performed in related fields.

However, these conventional methods use the conventional rotary kiln of a simple cylindrical structure as it is, but change the rotary kiln peripheral device into a complicated structure or add separate devices. Due to the extremely complicated structure, the maintenance and maintenance of the waste incineration and melting apparatus is disadvantageous, and the cost of equipment investment of the waste incineration and melting apparatus is greatly increased.

In addition, the improved conventional waste incineration and dissolution apparatus is not as satisfactory as the combustion function, and it is not activated to burn waste, which is an environmental pollutant, and recycle it as a heat source.

Accordingly, the present invention has been invented to solve the above-mentioned conventional problems, and an object thereof is to provide a rotary kiln having an excellent combustion function for effectively burning the waste fuel introduced therein.

The present invention for achieving the above object, the first distribution line is provided in the circumferential direction on the outer circumferential direction, the secondary distribution line provided in the longitudinal direction while communicating with the primary distribution line, the secondary distribution line, secondary distribution An inner passage of a refractory material having a discharge line communicating with the line and opening toward the inner hole; It has a structure characterized in that it comprises an outer cylinder surrounding the outer surface of the inner cylinder having an air inlet hole communicated with the primary distribution line of the inner cylinder.

According to the present invention, the outer cylinder constituting the rotary kiln is formed with an air inlet hole, the inner cylinder constituting the rotary kiln is provided with an air supply line for inducing and discharging air introduced through the air inlet hole of the outer cylinder to the inner hole of the rotary kiln. Thus, since the rotary kiln directly supplies the air for promoting combustion to the waste inside the rotary kiln itself, there is an effect that the combustion function of the rotary kiln is greatly improved.

In addition, since the rotary kiln rotates continuously, the discharge line for ejecting air into the rotary kiln inner hole continuously moves along the circumferential direction and ejects the outside air into the rotary kiln inner hole, so that the outside air is evenly distributed into the rotary kiln inner hole. There is an effect that the combustion function of the rotary kiln is further improved.

Therefore, if the rotary kiln according to the present invention is applied to a waste incineration-dissolving device, the structure of the waste incineration-dissolving device is greatly simplified, and the maintenance and maintenance of the waste incineration-dissolving device is advantageous, and the waste incineration-dissolving device of A significant reduction in facility investment costs can be expected.

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

1 to 5 are diagrams showing an example of a rotary kiln according to the present invention.

1 to 5, the rotary kiln according to the present embodiment, the inner cylinder 110 of the refractory material, the outer cylinder 120 surrounding the outer surface of the inner cylinder 110, and the air provided on the outer surface of the outer cylinder 120 It consists of a flow guide member (130; 130 ').

The inner cylinder 110 is provided in the circumferential direction in the circumferential direction and is provided in the longitudinal direction while communicating with the primary distribution lines 111 and 111 'and the primary distribution lines 111 and 111'. And a discharge line 113 communicating with the primary distribution line 112 and the secondary distribution line 112 and opening toward the inner hole 100a. In the present exemplary embodiment, the primary distribution lines 111 and 111 'are formed by fixing a cylindrical metal frame having a “C” cross section to the inner surface of the outer cylinder 120, but the primary distribution lines 111 and 111'. The cross-sectional shape of ') is not limited to this embodiment and may be variously modified as necessary, and if necessary, the primary distribution lines 111 and 111 may be formed in an arc shape. In this embodiment, the secondary distribution line 112 is formed by fixing a circular metal tube in communication with the side of the primary distribution line (111; 111 '), but also the cross-sectional shape of the secondary distribution line 112 is also specified The present invention is not limited to the form and may be variously modified as necessary. In this embodiment, the discharge line 113 is fixed to communicate with the circumferential surface of the secondary distribution line 112, the circular metal tube, the outlet is formed to face the central axis of the inner cylinder 110, discharge line 113 Although the air discharged through) is discharged toward the center of the inner hole 100a of the rotary kiln 110, the cross-sectional shape of the discharge line 113 is also not limited to a specific shape and may be variously modified as necessary. If necessary, it is also possible to appropriately change the discharge angle of the air discharged through the discharge line 113 by adjusting the angle of the discharge line 113. In the present embodiment, the air supply lines 111, 111 ', 112, and 113 are formed by using a metal frame and a pipe, and a part or part of these air supply lines 111, 111', 112, and 113 are made of fireproof materials. While encapsulating the whole, the inner cylinder 110 of the refractory material with the air supply lines 111, 111 ', 112, 113 was formed, but the air supply lines 111, 111', 112, 113 according to the present invention are limited thereto. It can be formed in a variety of forms without. On the other hand, in the case of forming the discharge line 113 through the metal tube, when the air outlet of the discharge line 113 is exposed to the inner hole (100a) of the rotary kiln 100, the discharge line 113 by the high temperature Since there is a risk of melting, the air outlet of the discharge line 113 is preferably formed of a refractory material. In the present embodiment, the air outlet of the discharge line 113 to protrude toward the inner hole (100a) to form a nozzle-shaped projection (113a), in this way to form a projection nozzle 113a, at a high temperature By the combustion by the waste inside the rotary kiln 100 can be effectively suppressed to flow back to the discharge line (113).

The outer cylinder 120 forms a structure having an air inlet hole 120a communicating with the primary distribution line 111 of the inner cylinder 110. The size and position of the air inlet hole 120a may be appropriately selected as necessary, but the position of the air inlet hole 120a is preferably formed in the middle portion between the secondary distribution lines 112, so that the air inlet hole ( It is preferable to allow the air introduced from the outside through 120a) to flow into the secondary distribution line 112 evenly through the primary distribution lines 111 and 111 '. As the outer cylinder 120, a circular metal tube is generally applied.

The air flow guide member (130; 130 ') is provided to protrude in the circumferential form on the outer surface of the outer cylinder 120, a pair of air guide plate (G1) for guiding air supplied from the outside to the air inlet hole (120a) G2; G3, G4). In the present embodiment, the pair of air guide plates (G1, G2; G3, G4) is made of a heat-resistant silicone material having heat resistance and elasticity, but a pair of air guide plates (G1, G2; G3, G4) is not limited thereto, and various materials may be applied as necessary.

On the other hand, reference numeral "141" is a fixing member for fixing the air guide plate (G1 ~ G4), and reference numeral "142" is a fastening member for fastening the fixing member 141 to the outer cylinder 120, and not described Reference numeral 120b denotes a fastening hole which is screwed with the fastening member. Here, the structure for fastening the air guide plate (G1 ~ G4) to the outer cylinder 120 is not limited to this embodiment, it can be appropriately modified according to the shape and shape of the air guide plate (G1 ~ G4) of course to be.

6 to 10, the use of the rotary kiln 100 according to the present invention will be described as follows.

First, according to FIG. 6, the waste incineration dissolving device supports a rotary kiln 100 and rotates the rotary kiln 200 clockwise or counterclockwise about an axis of the rotary kiln 100. 200); A rotary kiln 100 according to the present invention mounted on and fixed to the rotary kiln drive unit 200 in an inclined state such that an inlet (left in FIG. 6) is disposed higher than an outlet (right in FIG. 6); A refractory sealing structure 300 for sealing an inlet opened to the outside of the rotary kiln 100; The secondary combustion furnace 400 separates and discharges the combustion gas and the slag while sealing the outlet opened to the outside of the rotary kiln 100 by having a combustion gas outlet 400a at the upper portion and a slag outlet 400b at the lower portion. )Wow ; A waste input device 500 installed in the sealed structure 300 to supply waste into the rotary kiln 200; A combustion burner (600) installed in the closed structure (300) to ignite the waste introduced into the rotary kiln (200); An air supply device 700 for supplying combustion promoting air to the rotary kiln 100; A slug feeder 800 for transferring the slugs discharged to the outside through the slug discharge ports 400b of the secondary combustion furnace 400; It is discharged to the outside through the slug discharge port 400b of the secondary combustion furnace 400, and consists of a cooling water tank 900 for cooling the slugs conveyed by the slug feeder (800). FIG. 7 is an enlarged view of the periphery of the inlet-side air flow guide member 130 of the rotary kiln 100, and accordingly, the first hermetic holding member having a plurality of ribs B1a and a through hole h1 ( B1) is installed in the sealed structure 300, and the air guide plates G1 and G2 constituting the inlet-side airflow guide member 130 between the ribs B1a of the first hermetic holding member B1 are spaced a predetermined distance. It is fitted together. FIG. 8 is an enlarged view of the periphery of the outlet side air flow guide member 130 of the rotary kiln 100. As a result, a second hermetic holding member having a plurality of ribs B2a and through holes h2 may be provided. B2) is installed in the secondary combustion furnace 400, and the air guide plates G3 and G4 constituting the outlet-side air flow guide member 130 between the ribs B2a of the second hermetic holding member B2. It is fitted at a predetermined interval. Here, reference numeral 410 denotes an air nozzle for supplying air supplied from the air supply device 700 into the secondary combustion furnace 400.

When the waste incineration-dissolving device is operated, the rotary kiln 100 is rotated by the rotary kiln driving device 200, and in the state in which air is supplied from the air supply device 700 to the rotary kiln 100, waste is stored. The waste injector 500 is introduced into the rotary kiln 100. The combustion burner 600 is temporarily operated so that the waste introduced into the rotary kiln 100 is ignited, and when the waste introduced into the rotary kiln 100 is ignited, the combustion heat of the waste even if the operation of the combustion burner 600 is stopped. This ensures that the combustion of the waste continues. The waste introduced into the rotary kiln 100 is agitated by the rotary kiln 100 to be burned and melted and naturally discharged to the secondary combustion furnace 400. The combustion gas from the rotary kiln 100 is secondary combustion furnace. After being led to the upper portion of the 400 and re-burned in the secondary combustion furnace 400, it is discharged to the outside through the combustion gas outlet 400a, and the slag (combustion waste) from the rotary kiln 100 is secondary combustion. The free fall to the lower portion of the furnace 400 is rapidly cooled through the cooling water tank 900 is transferred to the next step through the slug feeder (800).

On the other hand, the air supplied from the air supply device 700, as shown in Figure 9, the space between the through-hole h1 of the first hermetic holding member (B1) → a pair of air guide plates (G1, G2) → the air inlet hole 120a (see FIG. 4 or FIG. 6) of the outer cylinder 120 → the primary distribution line 111 → the secondary distribution line 112 → the nozzle 113a after being sequentially moved to the discharge line 113 Blows into the inner hole (100a) through. At the same time, as shown in FIG. 10, the through-hole h2 of the second hermetic holding member B2 → the space between the pair of air guide plates G3 and G4 → the air inlet hole of the outer cylinder 120. (120a; see FIG. 4 or 6) → the first distribution line (111 ') → the second distribution line (112) → after moving in sequence to the discharge line 113, the inner hole (100a) through the nozzle (113a) Is blown out. At this time, the air guide plate (G1, G2, G3, G4), as shown in Figs. 9 and 10, bent outward by the air supply pressure ribs (B1a, B2a) of the airtight holding members (B1, B2) ), The airtight leakage between the sealed structure 300 and the rotary kiln 100, the secondary combustion furnace 400 and the rotary kiln 100 is closely maintained, effectively leaking the supply air to the outside. Is prevented.

According to the present invention, an air inlet hole 120a is formed in the outer cylinder 120 constituting the rotary kiln 100, and an air inlet hole of the outer cylinder 120 is formed in the inner cylinder 110 constituting the rotary kiln 100. Air supply lines 111, 111 ′, 112, and 113 are provided to guide and discharge the air introduced through the 120a to the inner hole 100a of the rotary kiln 100, so that the rotary kiln 100 is the rotary kiln 100. Since it directly supplies the air for promoting the combustion directly to the waste inside), the combustion function of the rotary kiln 100 is greatly improved.

In addition, since the rotary kiln 100 is continuously rotated, the discharge line 113 for ejecting air to the rotary kiln inner hole (100a) is continuously moved along the circumferential direction to the outside air to the rotary kiln inner hole ( Since 100a is blown out, the outside air is evenly blown into the rotary kiln inner hole 100a, so that the combustion function of the rotary kiln 100 is further improved.

Therefore, when the rotary kiln 100 according to the present invention is applied to a waste incineration-dissolving device, the structure of the waste incineration-dissolving device is greatly simplified, and the waste incineration-dissolving device is advantageously repaired and maintained. It is expected that the cost of equipment investment for melting apparatus will be greatly reduced.

11 and 12 are views for explaining a modified example of the rotary kiln according to the present invention, and show an example in which the airflow guide members 130 and 130 'are made of hard metal.

According to FIG. 11, the third hermetic holding member B3 having a plurality of ribs B3a and the through hole h3 is provided in the closed structure 300, and the rib B3a of the third hermetic holding member B3. Air guide plates G1 and G2 constituting the inlet-side airflow guide member 130 are inserted at predetermined intervals.

12, the fourth hermetic holding member B4 having a plurality of ribs B4a and the through hole h4 is provided in the secondary combustion furnace 400, and the ribs of the fourth hermetic holding member B4 ( Between the B4a), the air guide plates G3 and G4 constituting the outlet side air flow guide member 130 are fitted at a predetermined interval.

In the present embodiment, the air guide plate (G1 ~ G4) is a hard metal material is fixed to the outer cylinder 120, so that the air from the air supply device 700 through-hole h1 of the first hermetic holding member (B1) ), A portion of the inlet air leaks to the outside through a gap between the third and fourth hermetic holding members B3 and B4 and the air guide plates G1 to G4 by the supply pressure.

Therefore, as shown in Figs. 11 and 12, the plurality of air leak prevention plates (S1 ~ S4) is reinforced on the outer surface of the outer cylinder 120, and the ribs of the third to fourth hermetic holding members (B3, B4) ( It is preferable that the air leakage preventing plates S1 to S4 are sandwiched at predetermined intervals between the B3a and B4a to suppress leakage of the supply air to the outside.

On the other hand, the outlet of the discharge line 113 may be made to match the inner surface of the inner cylinder 110, as shown in Figure 11 and 12, in this case, the dissolved waste inside the rotary kiln 100 discharge line ( 113) has the disadvantage of increasing the risk of backflow.

The present invention is not limited to the embodiment as described above, and may be modified in various ways without departing from the scope of the following claims.

For example, in the present embodiment, the inlet side air flow guide member 130 and the primary distribution line 111 of the rotary kiln 100, the outlet side air flow guide member 130 'and the primary distribution line 111 The air supply from the air supply device 700 is simultaneously made through '), but if necessary, the air supply from the air supply device 700 may be made only through the inlet or outlet side. The air flow guide member and the primary distribution line may be formed at more than one location so that the air supply from the air supply device 700 may be simultaneously performed at three or more locations, and the installation position of the air flow guide member and the primary distribution line may be provided. Of course, may be appropriately selected as needed.

In addition, in the present embodiment, the air from the air supply device 700 is guided to the air inlet hole (120a) of the outer cylinder 120 through the air flow guide member (130, 130 '), but such air flow Induction members (130, 130 ') can be selected whether or not applied depending on the coupling method with the airtight holding members (B1 ~ B4). In other words, the air flow guide members 130 and 130 'may not be applied depending on the air supply method to the primary distribution lines 111 and 111', and the air flow guide members 130 and 130 'may be applied if necessary. ) May be modified differently.

In addition, although the rotary kiln 100 according to the present invention was developed for use in waste incineration and dissolution apparatus, the rotary kiln 100 according to the present invention is not limited to a specific use, but is wider in various fields. Of course, it can be applied and used in a wide range of applications.

On the other hand, the inlet portion of the rotary kiln 100 is dried and ignited waste, the full-scale combustion and melting of the waste is made in the middle of the rotary kiln 100, waste at the outlet of the rotary kiln 100 Since incineration and combustion gas are generated, allowing more air to be supplied to the middle portion of the rotary kiln 100 may increase the combustion efficiency of the rotary kiln 100. Therefore, when the discharge line 113 of the same diameter is arranged at equal intervals along the longitudinal direction of the secondary distribution line 112 as in this embodiment, the discharge line (located in the middle of the rotary kiln 100) The supply pressure of the 113 is maintained relatively higher than the discharge line 113 of the other position, or the supply pressure is discharged while the discharge line 113 is arranged at equal intervals along the longitudinal direction of the secondary distribution line 112 When evenly applied to the lines 113, the diameter of the discharge line 113 located in the middle portion of the rotary kiln 100 is relatively larger than the discharge line 113 of the other position, or discharge line of the same diameter When the 113 is disposed along the longitudinal direction of the secondary distribution line 112 and the supply pressure is evenly applied to the discharge lines 113, between the discharge lines 113 located in the middle of the rotary kiln 100. To the outlet line 113 at another position. It is preferable that it be relatively compact, rotary kiln so that more air in the middle of the supply 100.

1 is a front sectional view of a rotary kiln according to the present invention;

2 is a cross-sectional view taken along the line A-A of FIG.

3 is a cross-sectional view taken along the line B-B of FIG.

4 is a cross-sectional view taken along the line C-C of FIG.

5 is a perspective view of a partial cutaway of the rotary kiln according to the present invention;

Figure 6 is a view for explaining the use of the rotary kiln according to the present invention, a view showing a waste incineration-dissolving device equipped with a rotary kiln according to the present invention,

7 is an enlarged view of part X shown in FIG. 6;

8 is an enlarged view of a portion Y shown in FIG. 6;

9 and 10 are views for explaining an air supply state into the rotary kiln using the rotary kiln according to the present invention;

11 and 12 are views for explaining a modified example of the rotary kiln according to the present invention. FIG. 11 is a diagram corresponding to FIG. 9, and FIG. 12 is a diagram corresponding to FIG. 10.

-Explanation of terms for the main parts of the accompanying drawings-

100; Rotary kiln, 100a; Interior hall,

110; Inner cylinder, 111, 111 '; Primary distribution line,

112; Secondary distribution line, 113; Discharge line,

113a; Nozzle, 120; Outerwear,

120a; Air inlet hole, 120b; Fastening hole

130, 130 '; Air flow guide member, 141; Fixed member,

142; Fastening member, 200; Rotary kiln drive,

300; Closed structure, 400; Secondary combustion furnace,

400a; Combustion gas outlet, 400b; Slag outlet,

410; Air nozzle, 500; Waste feeder,

600; Combustion burners 700; Air Supply,

800; Slag feeder, 900; Cooling water tank.

B1 to B4; Hermetic holding member, B1a to B4a; live,

G1 to G4; Air guide plates, h1 to h4; Through Hole,

S1 to S4; Air leak prevention plate.

Claims (6)

A secondary distribution line 112 provided in the circumferential direction in the circumferential direction and being provided in the longitudinal direction while communicating with the primary distribution line 111; 111 ′, the primary distribution line 111; An inner cylinder 110 of refractory material having a discharge line 113 communicating with the secondary distribution line 112 and opening toward the inner hole 100a; An outer cylinder 120 having an air inlet hole 120a communicating with the primary distribution line 111 of the inner cylinder 110 and surrounding the outer surface of the inner cylinder 110; The outer surface of the outer cylinder 120 along the air inlet hole (120a) is provided to protrude in a circumferential shape, guides the air supplied from the outside to the air inlet hole (120a), a pair of air guide plate made of a heat-resistant elastic material An air flow guide member (130; 130 ') consisting of (G1, G2; G3, G4); Excellent rotary kiln, characterized in that it comprises a rotary kiln. The rotary kiln having excellent combustion function according to claim 1, wherein the primary distribution line (111) is provided in a circumferential form on the outer circumferential surface of the inner cylinder (110). The rotary kiln according to claim 1, wherein the discharge line (113) is formed toward the central axis of the inner cylinder (110). The rotary kiln according to claim 1, wherein the air outlet of the discharge line (113) protrudes toward the inner hole (100a) to form a projection nozzle (113a). delete delete

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