KR101792580B1 - Trash boiler system capable of improving gas flow rate - Google Patents

Abstract

The combustion gas flow improvement type incinerator boiler system according to the present invention comprises:
A first combustion chamber;
A second combustion chamber communicating with the first combustion chamber;
A third combustion chamber communicating with the second combustion chamber;
A boiler communicating with the third combustion chamber and comprising a body, an upper drum, a lower drum, and a superheater; And
And a combustion gas flow improving unit, which is provided at a portion where the third combustion chamber communicates with the boiler, and which includes a passage expanding portion and a dust removing portion.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a combustion gas flow improvement type incinerator boiler system,

The present invention relates to a combustion gas flow improvement type incinerator boiler system.

The incinerator boiler system is a system that uses the heat generated by incineration of waste for heating or power generation.

The incinerator boiler system consists of a combustion chamber and a boiler.

The combustion chamber is composed of a first combustion chamber, a second combustion chamber, and a third combustion chamber.

The first combustion chamber, the second combustion chamber, and the third combustion chamber are made by welding water pipes welded to each other. The body of the boiler is made by welding water pipes to each other.

The combustion gas generated as the waste is incinerated in the first combustion chamber passes through the second combustion chamber, the third combustion chamber, and the boiler and is discharged to the atmosphere.

While the combustion gas passes through the interior of the second combustion chamber, the third combustion chamber, and the boiler, the heat contained in the combustion gas is transferred to the water flowing through the water pipe. The heat is supplied to the heating or power generation facilities.

The combustion gas rises from the first combustion chamber to the second combustion chamber, enters the third combustion chamber, and then falls to the bottom of the third combustion chamber. Then, at the portion where the third combustion chamber and the boiler communicate with each other, they are sharply bent to the right and enter the inside of the boiler. Such a sudden change in the combustion gas prevents the combustion gas from flowing smoothly into the boiler.

If the combustion gas can not flow smoothly into the boiler, the efficiency of the incineration boiler system is lowered as a whole.

Korea registered patent (10-1470569)

It is an object of the present invention to provide a combustion gas flow improvement type incinerator boiler system in which the flow of combustion gas entering the interior of the boiler in the third combustion chamber is improved.

In order to achieve the above object, a combustion gas flow improvement type incinerator boiler system includes:

A first combustion chamber;

A second combustion chamber communicating with the first combustion chamber;

A third combustion chamber communicating with the second combustion chamber;

A boiler communicating with the third combustion chamber and comprising a body, an upper drum, a lower drum, and a superheater; And

And a combustion gas flow improving unit, which is provided at a portion where the third combustion chamber communicates with the boiler, and which includes a passage expanding portion and a dust removing portion.

The present invention is provided with a combustion gas flow improving unit composed of a passage expanding portion and a dust removing portion provided at a portion where the third combustion chamber communicates with the boiler.

The passage extensions allow the combustion gas to fall vertically in the third combustion chamber and then gently turn into the interior of the boiler. Thus, in order to enter the interior of the boiler in the third combustion chamber, the combustion gas does not need to be rapidly changed in direction. Therefore, the combustion gas can flow smoothly into the interior of the boiler.

The dust removing section removes the dust adhering to the passage expanding portion and sticking out when the combustion gas passes the passage expanding portion. In addition, the dust removing part sweeps air swirlingly to remove dust adhered firmly to the passage expanding part. Therefore, the combustion gas can flow smoothly through the portion where the third combustion chamber communicates with the boiler, without being disturbed by the dust, and can flow smoothly into the boiler.

Due to the combustion gas flow improvement unit described above, the combustion gas can smoothly flow from the third combustion chamber into the interior of the boiler, thereby improving the efficiency of the incineration boiler system as a whole.

1 is a view illustrating a combustion gas flow improvement type incineration boiler system according to an embodiment of the present invention.
Fig. 2 is an excerpt of the flue gas flow improving unit shown in Fig. 1. Fig.
3 is a side cross-sectional view of the dust removing unit shown in Fig.
4 is a side cross-sectional view of the nozzle stand shown in Fig.

Hereinafter, a combustion gas flow improvement type incinerator boiler system according to an embodiment of the present invention will be described.

1, a combustion gas flow improvement type incineration boiler system 10 according to an embodiment of the present invention comprises a combustion chamber 100, a boiler 200, and a combustion gas flow improvement unit 300 . The arrows shown in Fig. 1 represent the flow of combustion gas.

The combustion chamber 100 and the boiler 200 communicate with each other.

The combustion chamber 100 includes a first combustion chamber 110, a second combustion chamber 120, and a third combustion chamber 130. The first combustion chamber 110, the second combustion chamber 120, and the third combustion chamber 130 communicate with each other.

The first combustion chamber 110 is composed of water tubes 111 and diaphragms 112. Water flows into the water tube 111. The water tube 111 lowers the temperature of the inner wall of the first combustion chamber 110. The diaphragm 112 is disposed between the water tubes 111 and welded to the water tubes 111. Since the diaphragm 112 is disposed between the water tubes 111, there is no gap between the water tubes 111 in which dust can be caught.

The waste is introduced into the first combustion chamber 110 through the inlet 11. The introduced waste is placed on the grate 19 installed at the bottom of the first combustion chamber 110. The grate (19) consists of plates arranged in the form of stairs. The waste placed on the grate 19 is pushed to the right by the RAM PUSHER 12. Below the right end of the grate 19, a refill can 13 is installed.

A first burner 15 is installed below the first combustion chamber 110. The first burner 15 primarily combusts the waste introduced into the first combustion chamber 110. A second burner 16 is installed above the first combustion chamber 110. The second burner 16 secondarily burns the primarily burned waste. The ash remaining in the waste falls off to the refueling station (13).

The combustion gas generated when the waste is incinerated in the first combustion chamber 110 passes through the second combustion chamber 120, the third combustion chamber 130, and the boiler 200 and is discharged to the atmosphere. The heat contained in the combustion gas is transferred to the water flowing through the water tubes 111, 121, 131 and 211. The heated water is supplied to heating or power generation facilities.

The second combustion chamber 120 is located above the first combustion chamber 110. The second combustion chamber 120 is made by welding the water tubes 121 to each other.

The third combustion chamber 130 is located on the right side of the second combustion chamber 120. The second combustion chamber 120 and the third combustion chamber 130 are partitioned into a first partition W1. The top of the first partition W1 is pierced so that the combustion gas can move from the second combustion chamber 120 to the third combustion chamber 130. [ The third combustion chamber 130 is made by welding the water tubes 131 to each other. A first hopper 17 is disposed below the third combustion chamber 130 to collect ashes contained in the combustion gas.

The boiler 200 includes a body 210, an upper drum 220, a lower drum 230, and a superheater 240.

The body 210 is made by welding the water pipes 211. The interior of the body 210 is partitioned into a first boiler room S1 and a second boiler room S2 by a second partition W2. The bottom of the second partition W2 is pierced so that the combustion gas can move from the first boiler room S1 to the second boiler room S2. Below the second boiler room S1, there is installed a second hopper 18 in which ash contained in the combustion gas is collected. A chimney 14 for discharging the combustion gas into the atmosphere is installed above the second hopper 18.

The upper drum 220 is spherical and is installed on the upper part of the body 210. The upper drum 220 is in communication with the water tubes 111, 121, 131 and 211. Water and steam flowing in the water tubes 111, 121, 131 and 211 collect in the upper drum 220 and exist in the upper drum 220 in the state of saturated water and saturated steam.

The lower drum 230 is spherical and is installed at the bottom of the body 210. The lower drum 230 receives water from the outside and supplies the water to the water pipes 111, 121, 131, 211. The water flowing in the water tubes 111, 121, 131 and 211 passes through the first combustion chamber 110, the second combustion chamber 120, the third combustion chamber 130, the first boiler chamber 210 and the second boiler chamber 220 And receives heat from the combustion gas.

The superheater 240 is located in the third combustion chamber 130. The superheater 240 is supplied with saturated steam from the upper drum 220. The superheater 240 supplies superheated steam to a heating or power generating facility.

1, the combustion gas flow improving unit 300 is installed at a portion where the third combustion chamber 130 and the boiler 200 communicate with each other. The combustion gas flow improving unit 300 includes a passage expanding portion 310 and a dust removing portion 320.

As shown in FIG. 2, the passage expanding part 310 includes bent pipes 311 spaced apart at regular intervals and linear pipes 312 spaced apart from each other by a predetermined distance. The bold straight arrows shown in Fig. 2 indicate the flow direction of the combustion gas, the bidirectional straight arrows indicate the forward and backward directions of the nozzle stand, and the curved arrows indicate the rotational direction of the nozzle stand.

The extension space C1 is formed by being surrounded by the bent piping 311 and the straight piping 312. [

A first passage P1 through which the combustion gas descending vertically in the third combustion chamber 130 can enter into the expansion space C1 is formed between the bent pipes 311. [

The bent pipe 311 includes a first part 311a positioned on the upper side and inclined downward to the left side, a second part 311b connected vertically to the end of the first part 311a, And a third part 311c horizontally extended to the left. The passage expanding portion 310 is located in the third combustion chamber 130 due to the first part 311a and the second part 311b.

A second passage P2 through which the combustion gas can flow into the boiler 200 is formed in the expansion space C1 between the straight pipings 312. [

3, the dust removing unit 320 includes a nozzle base 321 located in the expansion space C1 and a nozzle base 322 located outside the expansion space C1 and rotating the nozzle base 321, And a driving unit 322 for driving the motor. The bidirectional straight arrows shown in Fig. 3 indicate forward and backward directions of the nozzle stand, and the curved arrows indicate the rotational direction of the nozzle stand.

As shown in Fig. 4, an air space C2 is formed inside the nozzle stand 321. As shown in Fig.

A spray hole 321a is formed at the left end of the nozzle stand 321.

A tube hole 321b to which one end of the tube T is connected is formed at the right end of the nozzle base 321. [

The tube T rotates along the nozzle base 321 when the nozzle base 321 rotates. The tube T is twisted to have a sufficient length to rotate.

The other end of the tube T is connected to an air pump (not shown).

The air pump supplies air into the inside of the tube (T).

The tube T supplies air to the air space C2.

A helical thread 321b is formed on the outer circumferential surface of the nozzle base 321.

The helical thread 321b is positioned between the spray hole 321a and the tube hole 321b.

3, the driving unit 322 includes a case 322a, a ball bearing 322b, a coupling 322c, a motor 322d, a guide block 322e, and a guide rail 322f.

A nozzle bank 322aa through which the nozzle stand 321 passes is provided at the center of the left side of the case 322a.

On the right side surface of the case 322a, a tube passage hole 322ab through which the tube T passes is provided.

The ball bearing 322b is fixed to the left inner surface of the case 322a.

The nozzle base 321 passing through the nozzle bore and hole 322aa passes through the center of the ball bearing 322b.

The helical thread 321b is engaged with the ball 322bb constituting the ball bearing 322b.

The right end of the nozzle stand 321 is connected to the shaft of the motor 322d by a coupling 322c.

A motor 322d is mounted on the guide block 322e.

The guide block 322e is coupled to the guide rail 322f so as to be able to move back and forth.

The guide rail 322f is fixed to the inner bottom surface of the case 322a.

Hereinafter, the operation and effect of the combustion gas flow improving unit will be described.

Referring to FIGS. 1 to 4, the combustion gas is lowered in the third combustion chamber 130.

The combustion gas enters the expansion space C1 through the first passage P1 while gently descending downward to the left side on the inclination of the first part 311a.

The combustion gas stays in the expansion space C1 for a while and gently changes its direction toward the second passage P2. The combustion gas, which temporarily stands in the extended space (C1) and is changed in direction, smoothly flows into the boiler (200) through the second passage (P2). The dust contained in the combustion gas falls into the first hopper 17.

The dust removing unit 320 removes the dust adhering to the bent pipes 311 and the straight pipe 312. The dust removing unit 320 may operate when the combustion gas flows, or may operate when the boiler operation is stopped and the combustion gas is not flowing.

The motor 322d rotates the nozzle base 321 clockwise or counterclockwise and simultaneously advances and retreats.

The motor 322d rotates the coupling 322c clockwise. The nozzle stand 321 rotates clockwise. Helical thread 321b turns clockwise around ball 322b. The nozzle base 321 advances. The motor 322d provided on the guide block 322e advances on the guide rail 322f.

The motor 322d rotates the coupling 322c counterclockwise. The nozzle stand 321 rotates counterclockwise. The helical thread 321b turns counterclockwise around the ball 322b. The nozzle stand 321 is moved backward. The motor 322d mounted on the guide block 322e is moved back on the guide rail 322f.

The air pump supplies air to the inside of the tube T while the nozzle stand 321 rotates clockwise or counterclockwise and advances and retreats. The tube T supplies air to the air space C2 of the nozzle stand 321. [ The air supplied to the air space C2 is injected through the injection hole 321a.

When the air is sprayed through the spray hole 321a, the nozzle stand 321 rotates clockwise or counterclockwise while moving forward and backward, so that the air is spouted into the expansion space C1.

The injected air removes the dust adhering to the bending pipes 311 and the straight pipe 312. The dust separated from the bent pipes 311 and the straight pipe 312 falls into the first hopper 17.

The combustion gas flows smoothly into the interior of the boiler 200 through the portion where the third combustion chamber and the boiler communicate without being disturbed by the dust.

10: Combustion gas flow improvement type incinerator boiler system
110: first combustion chamber 120: second combustion chamber 130: third combustion chamber
200: boiler 300: combustion gas flow improvement unit
310: passage extension part 311: bending pipe
312: Straight piping 320: Dust removal
321: nozzle stand 322:

Claims (5)

A first combustion chamber;
A second combustion chamber communicating with the first combustion chamber;
A third combustion chamber communicating with the second combustion chamber;
A boiler communicating with the third combustion chamber and comprising a body, an upper drum, a lower drum, and a superheater;
The combustion gas passing through the first combustion chamber and the second combustion chamber is vertically lowered in the third combustion chamber and is then installed at a portion where the third combustion chamber communicates with the boiler so as to smoothly change direction and enter the inside of the boiler A passage extension; And
And dust removing means for removing dust adhered to the passage expanding portion when the combustion gas passes through the passage expanding portion,
The passage expanding portion is composed of bent pipes spaced apart at regular intervals and linear pipes spaced apart from each other by a predetermined distance,
A first passage is formed between the bending pipes so as to allow the combustion gas descending vertically in the third combustion chamber to enter the expansion space, A second passage is formed between the straight pipings to allow the combustion gas to flow into the boiler from the expansion space,
The bent pipe includes a first part positioned on the upper side and inclined downward to the left side, a second part connected to the end of the first part and vertically lowered, and a second part connected to the end of the second part, It consists of three parts,
The passage expanding portion is positioned in the third combustion chamber by the first part and the second part so that the combustion gas descending vertically in the third combustion chamber gently falls down to the left side down the slope of the first part Is able to enter the expansion space through the first passage and then stay in the expansion space for a while to gently turn toward the second passage and into the boiler through the second passage Gas flow improvement type incinerator boiler system. delete delete delete delete

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