KR101960071B1 - Boiler for waste gas - Google Patents

Abstract

The present invention relates to a waste heat gas boiler for preventing dead zones in which heat exchange efficiency can be increased by continuously reducing the dead zone where waste heat gas is not flowed by continuously guiding the waste heat gas flowing in the boiler up and down.
The present invention is characterized in that it comprises a boiler body 100 through which waste heat gas is flowed at one end, an upper drum 200 provided at an upper portion of the boiler body 100 and having an internal space for filling the steam, The lower drum 300 is connected to the upper drum 200 and the lower drum 300 and is connected to the upper drum 200 and the lower drum 300 in the inner space of the boiler body 100, A heat exchange tube 400 for guiding the steam generated due to the heat exchange of the water provided in the lower drum 300 by the waste heat gas to the upper drum 200, A waste heat gas guide means 500 for uniformly guiding the waste heat gas flowing through the internal space of the boiler body 100 to the heat exchange tubes 400 to prevent a dead zone, A cleaning member 600 for spraying or spraying water, A lift unit 800 for lifting and lowering the member 600 and dust collectors 900 included in the waste heat gas flowing through the boiler body 100 and collecting the water sprayed from the cleaning member 60 do.

Description

{BOILER FOR WASTE GAS}

The present invention relates to a waste heat gas boiler for preventing dead zones in which heat exchange efficiency can be increased by continuously reducing the dead zone where waste heat gas is not flowed by continuously guiding the waste heat gas flowing in the boiler up and down.

Generally, waste heat gases generated by incineration of various refuse and waste in an incinerator contain a large amount of harmful substances, so if they are released to the atmosphere as they are, they cause severe environmental pollution and waste heat gas have.

In recent years, a waste heat gas boiler for preventing dead zones has been developed and used so as to minimize the emission of harmful substances and to recycle the waste heat gas.

As shown in FIG. 1, the waste-heat gas boiler for preventing dead zones according to the related art includes a body 11 to which waste heat gas flows into one side and is discharged to the other side, And a plurality of pipes 14 vertically installed inside the body 12 and the lower drum 13 and the body 11 and connecting the upper drum 12 and the lower drum 13 to each other.

According to this waste-heat prevention gas boiler for preventing dead zones, the waste heat gas of about 1000 ° C generated in the incineration process flows into the inside of the body 11 through one side of the body 11 and then exchanges heat with the pipe 14 Deg.] C to the other side of the body 11. In this process, the steam generated by the heat exchange between the waste heat gas and the pipe 14 is stored in the upper drum 12 and used for heating or industrial purposes.

However, since the piping 14 is formed long in the vertical direction, there is a problem that the waste heat gas at high temperature is concentrated only in the upper portion of the piping 14 in the process of perfusion.

The background art of the present invention is disclosed in Patent Registration No. 10-0650383 (registered on November 21, 2006) in the Korean Intellectual Property Office.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a waste heat gas boiler for preventing dead zones in which heat exchange efficiency can be increased by reducing the dead zone where the waste heat gas that is perfused in the boiler is continuously guided in the vertical direction, will be.

The waste-heat gas boiler for preventing dead zones according to an embodiment of the present invention includes a boiler body 100 in which waste heat gas is introduced into one end and waste heat gas introduced into the other end is discharged, And an inner space for filling water is formed in a lower portion of the boiler body 100. A lower portion of the lower drum 200 located on both sides of the upper drum 200 is connected to the upper portion of the upper drum 200, The water supplied from the lower drum 300 is heat-exchanged by the drum 300 and the waste heat gas that is connected to the upper drum 200 and the lower drum 300 so as to communicate with the inner space of the boiler body 100 A plurality of heat exchange tubes 400 for guiding the generated steam to the upper drum 200 and a heat exchanger 400 for heat exchange with the waste heat gas flowing in the inner space of the boiler body 100, Guide the tubes 400 evenly A cleaning member 600 for spraying air or spraying water to clean the heat exchange tube 400 and a cleaning member 600 for cleaning the cleaning member 600 to clean the heat exchange tube 400. [ The boiler body 100 includes an opening and closing member 700 for opening and closing an inner space of the boiler body 100 and a lower drum 300. The boiler body 100 is disposed between the lower drum 300 and the lower drum 300, And an oven 900 for collecting water sprayed from the cleaning member 60. The waste heat gas guiding means 500 is fixed to the lower drum 300 while being spaced apart from the upper drum 200, A first guide portion 510 for guiding the waste heat gas to the upper drum 200 and a second guide portion 510 fixed to the upper drum 200 in a state spaced apart from the lower drum 300 and guided by the first guide portion 510 And a second guide portion 520 for guiding the waste heat gas to the lower drum 300. The first guide portion 510 includes a lower drum 300, Multiple to be fixed to the periphery of each A second fixing groove 521 for fixing the periphery of the upper drum 200 is formed in the second guide portion 520 and the opening and closing portion 700 is formed in the boiler body 100 And an opening and closing door 720 for opening and closing the opening 710. The cleaning member 600 is mounted around the opening 710 And the cleaning member 600 and the opening and closing door 720 are screwed to the mounting hole 711. The mounting hole 711 is formed with a screw hole.

The waste-heat gas boiler for preventing dead zones according to another embodiment of the present invention includes a boiler body 100 in which waste heat gas is introduced into one end and waste heat gas introduced into the other end is discharged, And an inner space for filling water is formed in a lower portion of the boiler body 100. A lower portion of the lower drum 200 located on both sides of the upper drum 200 is connected to the upper portion of the upper drum 200, The water supplied from the lower drum 300 is heat-exchanged by the drum 300 and the waste heat gas that is connected to the upper drum 200 and the lower drum 300 so as to communicate with the inner space of the boiler body 100 A plurality of heat exchange tubes 400 for guiding the generated steam to the upper drum 200 and a heat exchanger 400 for heat exchange with the waste heat gas flowing in the inner space of the boiler body 100, Guide the tubes 400 evenly A cleaning member 600 for spraying air or spraying water to clean the heat exchange tube 400, a lifting and lowering member 600 for lifting and lowering the cleaning member 600, And the water sprayed from the cleaning member 60 and the water sprayed from the cleaning member 60 are disposed between the lower drum 300 and the boiler body 100, And the waste heat gas guiding means 500 is fixed to the lower drum 300 while being separated from the upper drum 200 to guide the waste heat gas introduced into the upper drum 200 The first guide portion 510 is fixed to the upper drum 200 while being separated from the lower drum 300 so that the waste heat gas guided by the first guide portion 510 is guided to the lower drum 300 And a second guiding part 520 for guiding the lower drum 300. The first guiding part 510 includes a second guiding part 520, A second fixing groove 521 for fixing the periphery of the upper drum 200 is formed in the second guide portion 520 and the cleaning member 600 is fixed to the upper surface of the upper drum 200, A fixed body 610 which is erected in the inner space of the fixed body 610 and receives fluid from the outside and a rec gear 621 is formed along the longitudinal direction and inserted into the fixed body 610 and slid into the fixed body 610, And the lift unit 800 is rotatably installed inside the boiler body 100 in a state of being engaged with the return gear 621 of the lift tube 620 A pinion 810 provided on the outer side of the boiler body 100 in a state of being axially coupled to the pinion 810 so as to be rotatable about the axis of the pinion 810, And a motor 820 for forward rotation or reverse rotation.

The present invention has an advantage in that heat exchange efficiency can be increased by continuously guiding the waste heat gas passed through the boiler through the waste heat gas guiding means in the vertical direction to reduce the dead zone where the waste heat gas does not flow.

Also, during operation of the boiler, the heat exchanger can be cleaned from time to time to enable continuous operation of the boiler.

In addition, since the first guide portion and the second guide portion included in the waste heat gas guiding means are formed in the form of plate members, the fixing grooves are formed in each of them, so that they can be fixed in a state of being tightly adhered to the outer circumferential surfaces of the cylindrical upper drum and the lower drum.

Further, since the cleaning member for cleaning the heat exchange tube is constituted by a nozzle for spraying air or water, it is possible to clean the heat exchange tube at a long distance.

Further, since the mounting hole is formed around the opening hole that opens the inner space of the boiler body, air or water can be sprayed while the nozzle, which is the cleaning member, is mounted.

In addition, since the nozzle, which is the cleaning member, lifts and lowers the air or water, the heat exchange tube can be cleaned as a whole.

1 is a view showing a waste-heat gas boiler for preventing dead zones according to the prior art.
2 is a view showing a configuration of a waste heat gas boiler for preventing dead zones according to an embodiment of the present invention.
3 is a view showing an arrangement state of an upper drum and a lower drum according to the present invention.
Fig. 4 shows a main part of the present invention. Fig.
5 is a view showing an opening and closing member applied to the present invention.
6 (a), 6 (b) and 6 (c) sequentially show the process of fixing the cleaning member to the opening and closing member of the present invention.
7 is a plan view of Fig.
8 is a plan view showing the state where the lens control lever of the present invention rotates the lens rod.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 2 to 8, the present invention includes a boiler body 100 in which waste heat gas is introduced into one end and waste heat gas introduced into the other end is discharged, and an upper portion of the boiler body 100, A lower drum 300 provided at a lower portion of the boiler body 100 and having an inner space filled with water and an upper drum 200 and a lower drum 300. [ 300 for guiding the steam generated as a result of the heat exchange of the water provided in the lower drum 300 by the waste heat gas flowing through the inner space of the boiler body 100 to the upper drum 200 The waste heat gas that is guided to the heat exchange tubes 400 uniformly in the inner space of the boiler body 100 while being provided between the heat exchange tubes 400 and the heat exchange tubes 400, And gas guiding means (500).

Since the inner space of the boiler body 100 is opened at both ends, the waste heat gas flows into the one end, is perfused, and then is discharged to the other end. At this time, the waste heat gas flowing from the boiler body 100 flows into the heat exchange pipe 400 while being perfused, so that heat exchange may occur.

An oven 900 for collecting dust falling from the waste heat gas flowing in the boiler body 100 is positioned between the lower drums 300 at a lower portion of the boiler body 100.

In addition, in the inner space of the boiler body 100, it is preferable that the waste heat gas is set to flow at an appropriate flow rate of 4 m / s or less. Accordingly, the differential pressure increase and the fusion of the dust are reduced by the fast flow rate, the efficiency of the heat exchange is increased, and dust contained in the waste heat gas is dropped by the proper flow rate and can be collected in the pellet 900.

The upper drum 200 stores steam generated in the heat exchange tube 400 where heat exchange is performed by the waste heat gas. The stored steam is used for heating or industrial use.

The lower drum 300 is filled with water for generating steam in the inner space, and is provided in a direction parallel to the upper drum 200. The lower drum 300 is composed of a plurality of lower drums 300 and is positioned on both sides of the lower drum 200.

Here, the water for generating steam may be supplied through the upper drum 200 or the lower drum 300 and filled therein. And, the water can be filled automatically by the pump and a constant water level can be maintained.

One end of the heat exchange tubes 400 is connected to the upper drum 200 and the other end thereof is connected to the lower drums 300. Therefore, steam is generated in the heat exchange tube 400, which is heat-exchanged by the waste heat gas, and is supplied to the upper drum 200.

The heat exchange tubes 400 are installed at regular intervals along the longitudinal direction of the drums 200 and 300. That is, the waste heat gas can be moved between the heat exchange tubes 400.

The waste heat gas guide means 500 includes a first guide portion 510 fixed to the lower drum 300 while being spaced apart from the upper drum 200 and guiding the waste heat gas introduced into the upper drum 200, And a second guide unit 520 which is fixed to the upper drum 200 while being separated from the drum 300 and guides the waste heat gas guided by the first guide unit 510 to the lower drum 300 .

The first guide part 510 is formed with a first fixing groove 511 for fixing the periphery of the lower drum 300. Therefore, when the outer side of the lower drum 300 is inserted into the first fixing groove 511 of the first guide part 510, the first guide part 510 is fixed to the lower drum 300 by bolting or welding . That is, the first guide portion 510 is in a standing state in the lower drum 300.

The second guide portion 520 is formed with a second fixing groove 521 for fixing the periphery of the upper drum 200. The second guide portion 520 is fixed to the upper drum 200 by the bolting or welding in a state where the outer side of the upper drum 200 is inserted into the second fixing groove 521 of the second guide portion 520 . That is, the second guide portion 520 is suspended from the upper drum 200.

The first guide portion 510 and the second guide portion 520 are disposed in a plurality of the heat exchange tubes 400 arranged at alternate intervals and spaced apart at regular intervals.

In this state, the waste heat gas flowing into the boiler body 100 is guided upward by the first guide portion 510 to be contacted with the heat exchange tubes 400 located in front of the first guide portion 510 do. The raised waste heat gas is guided downward by the second guide portion 520 and is contacted with the heat exchange tubes 400 located in front of the second guide portion 520.

Therefore, the waste heat gas is repeatedly lifted and lowered by the first guide portion 510 and the second guide portion 520, so that the waste heat gas can be evenly contacted to the heat exchange tubes 400 as a whole. Since the waste heat gas is moved upward and downward to prevent the occurrence of a dead zone, the efficiency of heat exchange can be increased. In addition, during the movement of the waste heat gas, the dust contained in the waste heat gas may collide with the first guide part 510 and the second guide part 520 and may fall down and be collected in the opener 900.

Thus, the steam generated in the heat exchange tube 400, which is heat-exchanged by the waste heat gas generated by incineration of waste or waste in the incinerator, can be used for heating or industry.

The present invention further includes a cleaning member 600 for cleaning the heat exchange tube 400 and an opening and closing member 700 for opening and closing the inner space of the boiler body 100 for cleaning the cleaning member 600 .

The cleaning member 600 may be composed of an air nozzle for spraying air supplied from the outside or a water jet for spraying water supplied from the outside.

The cleaning member 600 is fixed in a state of passing through the boiler body 100 and can blow air or water. Accordingly, when air or water is injected at a predetermined period in the cleaning member 600 fixed to the boiler body 100, the heat exchange tube 400 can be cleaned at regular intervals.

The opening and closing member 700 includes an opening hole 710 formed in the boiler body 100 to open the interior space to the outside and an opening and closing door 720 for opening and closing the opening hole 710.

The opening hole 710 may be formed to a minimum size such that the cleaning member 600 can be penetrated. That is, the heat exchanging tube 400 can be cleaned by blowing air or water through the opening hole 710 in a state where the cleaning member 600 is penetrated.

The opening / closing door 720 may be formed in a plate shape to cover and close the opening hole 710, and may be fixed by bolting. Of course, the opening / closing door 720 may be rotatably or slidably installed in the boiler body 100 to open / close the opening hole 710.

The opening and closing part 700 is formed in a plurality of units and is vertically spaced from the boiler body 100. The opening and closing part 700 of the upper part may be formed to be smaller than the opening and closing part 700 of the lower part. The upper opening / closing part 700 may be formed to pass through the cleaning member 600, and the lower opening / closing part 700 may be formed to have a size that can be accessed by an operator. Accordingly, in the state where air or water is sprayed from the cleaning member 600 passing through the upper opening hole 710 and the lower opening hole 710 is opened, when the user uses the cleaning member 600, Air or water can be injected into the internal space of the body 100.

A mounting hole 711 for mounting the cleaning member 600 may be formed around the opening hole 710 formed in the upper portion of the boiler body 100. The mounting hole 711 may be a screw tap.

Accordingly, since the bolt is screwed to the mounting hole 711, the opening / closing door 720 can be fixed to the opening hole 710, and the cleaning member 600 can be fixed to the opening hole 710. That is, there is a convenient advantage that the user does not need to grasp the cleaning member 600 because the cleaning member 600 sprays water or air while being fixed to the opening hole 710 by bolting.

Accordingly, the operator can open the opening / closing door 720 even when the boiler is in operation, insert the cleaning member 600 into the opening hole 710, and blow the air or water to clean the heat exchange tube 400 . At this time, the dust to be cleaned in the heat exchange tube 400 can be dropped and collected in the pail 900.

In the meantime, the present invention includes a cleaning member 600 for cleaning the heat exchange tube 400 and a lifting unit 800 for lifting and lowering the cleaning member 600.

The cleaning member 600 includes a fixed tube 610 fixed to the boiler body 100 through which the fluid is supplied from the outside and is fixed to the fixed tube 610 so as to be able to ascend and descend, And a lifting body 620 for lifting.

Therefore, since the fluid is sprayed in a state in which the lifting tube 620 is lifted and lowered from the fixed tube 610, it can be cleaned from the upper part to the lower part of the heat exchange tube 400.

Further, a recoil gear 621 is formed on the lifting body 620 along the longitudinal direction.

The elevating portion 800 is rotatably provided on the inner side of the boiler body 100 in a state of being engaged with the recoil gear 621 of the elevating tube 620. The elevating portion 800 is forwardly or reversely rotated by a rotational force transmitted from the outside, A motor 820 provided on the outer side of the boiler body 100 in a state of being axially coupled to the pinion 810 to forwardly or reversely rotate the pinion 810, .

The pinion 810 is located inside the boiler body 100 and the motor 820 is provided outside the boiler body 100 so that the motor 820 can be prevented from being damaged by the high temperature of the waste heat gas.

Therefore, as the motor 820 rotates the pinion 810, the lifting and lowering body 620 can be automatically lifted and lowered. That is, since the elevating tube 620 is lifted and lowered, water or air is sprayed, the heat exchanging tube 400 can be cleaned evenly as a whole.

As described above, according to the present invention, it is possible to increase the efficiency of heat exchange by reducing the dead zone where waste heat gas is not flowed by continuously guiding the waste heat gas flowing in the boiler in the vertical direction, It can be widely used because it can be applied continuously to the waste gas boiler for preventing dead zone.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is to be understood, therefore, that the embodiments described above are to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, All changes or modifications that come within the scope of the equivalent concept are to be construed as being included within the scope of the present invention.

100: boiler body 200: upper drum
300: lower drum 400: heat exchanger tube
500: waste heat gas guide means 510: first guide portion
511: first fixing groove 520: second guide portion
521: second fixing groove 600: cleaning member
610: Fixed tube 620: Lift tube
621: Recoil gear 700: Opening and closing member
710: Opening hole 711: Mounting hole
720: opening / closing door 800:
810: Pinion 820: Motor
900:

Claims (2)

delete A boiler body 100 through which the waste heat gas flows into the one end and the waste heat gas introduced into the other end is discharged,
An upper drum 200 provided at an upper portion of the boiler body 100 and having an inner space for filling the steam,
A lower drum 300 provided at a lower portion of the boiler body 100 and formed with an inner space for filling water and positioned at both sides of the lower portion of the upper drum 200,
The upper drum 200 and the lower drum 300 are communicatively connected to each other to generate steam generated due to heat exchange of water provided in the lower drum 300 by the waste heat gas flowing in the inner space of the boiler body 100, A plurality of heat exchange tubes (400) guiding to the drum (200)
A waste heat gas guiding means 500 for uniformly guiding the waste heat gas flowing through the internal space of the boiler body 100 to the heat exchange tubes 400 while being interposed between the heat exchange tubes 400 to prevent a dead zone, ,
A cleaning member 600 for spraying air or spraying water to clean the heat exchange tube 400,
A lifting unit 800 for lifting and lowering the cleaning member 600,
And is disposed between the lower drums 300 at a lower portion of the boiler body 100 to collect dust that is contained in the waste heat gas flowing through the boiler body 100 and falls down and water discharged from the cleaning member 60 900,
The waste heat gas guide means 500
A first guide part 510 fixed to the lower drum 300 while being separated from the upper drum 200 and guiding the waste heat gas flowing into the upper drum 200,
And a second guide part 520 fixed to the upper drum 200 while being separated from the lower drum 300 and guiding the waste heat gas guided by the first guide part 510 to the lower drum 300 and,
The first guide portion 510 is formed with a plurality of first fixing grooves 511 to be fixed around the respective lower drums 300,
The second guide portion 520 is formed with a second fixing groove 521 for fixing the periphery of the upper drum 200,
The cleaning member 600
A fixed tubular body 610 standing up in the inner space of the boiler body 100 and receiving fluid from the outside,
And a lifting tube 620 formed with a rack gear 621 along the longitudinal direction and injecting a fluid supplied from the fixed tube body 610 while being inserted into the fixed tube body 610 and slid,
The elevating portion 800
A pinion 810 which is rotatably provided inside the boiler body 100 in a state of being meshed with the recoil gear 621 of the elevating tube 620 and is rotated forward or reverse by a rotational force to lift the elevating tube 620 )and,
And a motor 820 provided on the outer side of the boiler body 100 in a state of being axially coupled to the pinion 810 so as to rotate forward or reverse the pinion 810 while being prevented from being damaged by the high temperature of the waste heat gas The waste heat boiler for preventing dead zone.

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