KR100976971B1 - Heat recovery steam generator - Google Patents

Abstract

PURPOSE: A heat exchanger for recovering waste heat occurred in a waste incinerator is provided to filter heavy dust by changing the flow rate of waste heat gas in a gravity space. CONSTITUTION: A heat exchanger for recovering waste heat occurred in a waste incinerator comprises a waste incinerator, a heat exchange passage(120), a reaction tower, and a bag filter. Waste heat gas occurred in the waste incinerator is passed through the heat exchange passage and is heat-exchanged to obtain vapor. The reaction tower neutralizes the waste heat gas by spraying water or chemicals on the waste heat gas. The bag filter collects dust in the waste heat gas passing through the reaction tower and discharges the dust to air. One or more gravity spaces(125) are formed because a heat pipe is not installed in the heat exchange passage.

Description

Heat exchanger that recovers waste heat of waste heat gas from waste incinerator {Heat Recovery Steam Generator}

The present invention relates to a waste heat boiler, and more particularly, a heat exchanger for recovering waste heat of waste heat gas generated from a waste incinerator which can improve heat efficiency by improving a heat exchange furnace used in a waste heat boiler and facilitate maintenance. It's about the furnace.

In general, the high temperature waste heat gas generated during incineration, such as incinerators, contains a large amount of dust, and if it is released to the atmosphere as it is, it causes serious problems in environmental pollution as well as recycling of waste heat.

For this reason, a number of waste heat boilers have been disclosed that utilize waste heat of waste heat gas and at the same time reduce and release harmful conditions to the human body.

Figure 1 shows an example of a waste heat boiler according to the prior art, the incinerator 10 is provided, the heat exchange furnace 20 is connected to the outlet of the incinerator 10.

The heat exchange path 20 is a passage through which waste heat gas of the incinerator 10 is discharged, and a steam drum 23 and a drum 22 are installed above and below the heat exchange path 20, and the heat exchange path 20 of the heat exchange path 20 is disposed. The inside has a structure in which a plurality of heat transfer tubes 21 are installed in a direction perpendicular to the discharge direction of the waste heat gas.

The waste heat boiler lowers the temperature of the waste heat gas through heat exchange with the heat transfer tube 21 while guiding and discharging the waste heat gas having a high temperature of about 1,000 ° C. generated during the incineration of the incinerator 10 through the heat exchange furnace 20. It is to be discharged to avoid the regeneration temperature range, such as dioxin.

In this process, the steam generated by heat exchange with the heat exchanger tube 21 is stored as a steam drum 23 to be used for heating or industrial purposes according to each use.

However, in the waste heat boiler as described above, since the hot waste heat gas is directly injected into the heat exchange furnace 20, and the heat transfer tube 21 is formed in a direction perpendicular to the discharge direction of the waste heat gas, the dust in the waste heat gas is melted by the high temperature. The outer surface of the heat exchanger tube 21 was fused and solidified.

As the dust is fused and solidified on the outer surface of the heat transfer pipe 21, the efficiency of the heat transfer pipe is rapidly lowered due to deterioration in function due to heat exchange with the waste heat gas, and the dust that is solidified by being fused to the heat transfer tube is frequently cleaned. Uncomfortable and the temperature of the exhaust gas is increased as time goes by, as well as had a problem that contains a large amount of dust.

In order to clean the dust solidified in the heat pipe 21 of the waste heat boiler, a hole 25 is formed in the outer wall of the heat exchange path 20 so as to be opened and closed, and a high pressure air nozzle or water jet is formed through the hole 25. I've been brushing my back.

However, even if a vacuum cleaner such as an air nozzle or a water jet is used, it is cleaned through a narrow hole 25, so that the inside of the cleaning state cannot be seen, and only the heat pipe 21 near the hole 25 is partially cleaned. There was a problem.

On the other hand, the incinerator 10 is used because the incineration temperature is too high to stack the refractory brick 11 in all directions as shown in FIG.

At this time, in the incinerator 10, the fine ash (12) generated in the combustion process is attached to the refractory brick (11), these fine ash flows down from the top of the refractory brick (11) layer, and flowed down from the bottom Molten combustion products 12 are stacked.

Thus, the combustion products 12 stacked below are solidified while being cooled when the incinerator is not used, and the stack of fine ashes is gradually increased according to the continuous use of the incinerator 10.

It would not matter if the fine ash piled up and solidified as described above can be shaken off after it is cooled, but once the solidified molten combustion products are hardened like stones, they do not break well and do not melt in the fire.

The present invention has been made in order to solve the above problems, forming a gravity space in which the heat exchanger tube does not exist inside the heat exchanger, relatively heavy dust falls down, when the interior of the heat exchanger to clean the door It is to provide a heat exchanger that recovers the waste heat generated from the waste incinerator, which can be opened and moved into the gravity space and cleaned efficiently.

The present invention to solve the above problems,

Incinerators for incineration of waste;

A heat exchanger that obtains steam by passing heat through the heat transfer pipe while the waste heat gas generated in the incinerator passes;

A reaction tower for neutralizing by spraying water or chemicals on the waste heat gas passing through the heat exchanger; And

And a bag filter having a large-capacity blower fan installed to collect the dust in the waste heat gas that has passed through the reaction tower and then discharge the atmosphere.

Since no heat pipe is installed in the heat exchange furnace, a gravity space having a size enough to accommodate one person is formed in at least one section, and the heat of waste heat gas generated in a waste incinerator is characterized in that an opening door is formed on the outer wall of the gravity space. It provides a heat exchanger to recover the.

As described above, the heat exchange furnace according to the present invention has an advantage in that relatively heavy dusts are primarily filtered by changing the flow rate of waste heat gas in the gravity space of the heat exchange furnace.

And since this gravity space can be used as a cleaning space, there is an advantage in the life of the boiler and thermal efficiency.

1 is a schematic view showing a waste heat boiler according to the prior art,
2 is a view showing the incinerator of FIG.
3 is a schematic view showing a gas flow according to the present invention,
4 is a perspective view showing the inner wall of the incinerator according to the present invention;
5 is a view showing a heat exchange furnace according to the present invention,
6 is a view showing a reaction tower according to the present invention,
FIG. 7 is a perspective view showing the homogeneous plate shown in FIG. 6, and
FIG. 8 is a view of the outlet of FIG. 6 as viewed from below. FIG.

Hereinafter, a heat exchanger for recovering waste heat of waste heat gas generated in a waste incinerator according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

Referring to FIG. 3, the waste heat boiler 100 according to the present invention includes an incinerator 110, a heat exchange furnace 120, a reaction tower 130, and a bag filter 140.

The incinerator 110, the heat exchanger 120, the reaction tower 130 and the bag filter 140 are all connected, waste heat gas burned in the incinerator 110 by installing a powerful blower fan in the bag filter 140 Inhale and discharge to outside.

Here, the role of the incinerator 110 and the heat exchanger 120 is as described in the prior art, the reaction tower 130 serves to neutralize the waste heat gas passing through the heat exchanger 120 with moisture or chemicals. The bag filter 140 collects the remaining dust remaining in the waste heat gas while sucking the waste heat gas by the powerful blowing fan.

That is, the waste heat gas generated in the incinerator 110 is not discharged to the atmosphere by convection but is forcedly blown out of the bag filter 140 and discharged to the atmosphere.

Incinerator 110 according to the present invention is configured to prevent the solidification of the combustion as shown in FIG. In the incinerator 110, an inner wall is stacked with the refractory brick 111, and a cooling metal block 112 is installed at the lowermost layer of the inner wall. In addition, a circulation passage 113 is formed in the metal block 112 to circulate the cooling water, and the cooling water is supplied to the inlet 114 and the outlet 115 of the circulation passage 113.

The fine ash melted by the metal block 112 formed as described above flows down the outer wall and accumulates in the lowermost layer, but is cooled by the metal block 112 installed in the lowermost layer of the inner wall, thereby preventing combustion products from sticking to the incinerator 110. ) It easily falls after use.

Next, the heat exchange furnace 120 according to the present invention is provided with a gravity type dust removing means as shown in Figure 5, conventionally removed or collected dust in the process after the heat exchange furnace, in the present invention in the heat exchange furnace 120 Gravity removal primarily removes relatively heavy dust.

The heat exchange path 120 is disposed in the heat transfer pipe 121 is heat exchange is made as the waste heat gas passes through the inside as in the prior art, the steam drum 123 and the water drum (123) and the top and bottom of the heat transfer pipe 121, respectively ( 122) is arranged. More preferably, the water in the water tube 122 is raised in the heat transfer tube 121, and when the heat transfer tube 121 is heated by the waste heat gas, the water in the inside of the water boils to make steam to collect steam in the steam drum 123. . In addition, the water drum 122 is continuously supplied with water shortages appearing while steam is generated.

At this time, the heat exchange path 120 according to the present invention is to remove the relatively heavy dust from the waste heat gas passing through the different arrangement of the heat transfer tube 121. The heat pipe 121 is arranged at least one section or several sections to form a gravity space 125 in which the heat pipe 121 is not installed. Gravity space 125 is large enough to accommodate one person. In addition, the gravity space 125 should be formed to penetrate in the width direction of the heat exchange path 120.

As such, when the gravity space 125 is formed, relatively heavy dusts fall freely while the moving speed of the waste heat gas passing through the gravity space 125 decreases. That is, the waste heat gas passes through the heat pipes 121 arranged in a densely and suddenly stays in a large large space, and the speed decreases, thereby causing heavy dusts to fall.

Here, since the waste heat gas passing through the heat exchange path 120 is a forced air blowing method instead of a natural convection method, the same heat as the previous heat exchanger tube 121 is obtained.

And a lower portion (under the drum 122) of the heat exchange path 120 is provided with a support 127 to receive the freely fallen dust.

On the other hand, the opening and closing door 126 to the gravity space 125 is formed on the wall surface of the gravity space 125, the opening and closing door 126 is a worker to enter into the gravity space 125 to clean the heat exchange path 120. It is arranged to help.

Next, the reaction tower 130 is to neutralize the waste heat gas passing through the heat exchange path 120, as shown in Figure 6, having a cylindrical shape in the upper portion is formed in a conical shape, the upper and lower portion in the upper center portion Inlet hole 131 is formed to pass through.

The reaction tower 130 is a waste heat gas is introduced into the inlet hole 131, the spray nozzle 132 for spraying water or chemicals to neutralize the introduced waste heat gas is installed inside the conical inclined surface (130a) do.

With only the configuration as described above, there is a problem that the incoming waste heat gas is vertically lowered to supply sufficient moisture.

Therefore, the present invention added a configuration to spread the waste heat gas flowing into a wider space.

In other words, the inlet hole 131 is installed under the inlet plate 134, and the inlet plate 134 serves to make the waste heat gas flowing in vertically or radially spread.

Such an equilibrium plate 134 has a hatshade shape as shown in FIG. 7, and a vertical hole 135 is formed in the center to vertically drop waste heat gas.

A plurality of perforations 137 are formed on the inclined surface 136 of the uniform plate 134 to spread at a larger angle than the vertical drop of the waste heat gas by the vertical holes 135.

The waste heat gas which is not introduced into the vertical hole 135 or the other hole 137 impinges on the inclined surface 136 of the evenly distributed plate 134 and spreads toward the wall of the reaction tower 130.

Therefore, the waste heat gas is spread in all directions, so that the water ejected from the injection nozzle is evenly applied to the waste heat gas.

For reference, the uniform plate 134 is suspended in the air by a plurality of vertical rods 138 extending from the upper oblique surface (130a) of the reaction tower 130 (see Figure 6).

On the other hand, the outlet 133 is formed in the lower portion of the reaction tower 130 is not formed as one, as shown in Figure 6 and Figure 8 are formed at equal intervals on the side of the reaction tower 130. At this time, each outlet 133 is extended while drawing an arc of a predetermined length to the outside.

Therefore, the waste heat gas discharged through the plurality of outlets 133 is returned from the lower portion of the reaction tower 130 by a sufficient number of outlets and then transferred to the next bag filter 140.

At this time, each of the outlets 133 are combined together again, it is preferable to be connected to the bag filter 140.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined by the appended claims. .

100: waste heat boiler 110: incinerator
111: refractory brick 112: metal block
120: heat exchange furnace 121: heat pipe
125: gravity space 126: opening and closing door
130: reaction tower 131: inlet hole
132: injection nozzle 133: outlet
134: uniform plate 135: vertical hole
136: perforation 140: bag filter

Claims (1)

Incinerator 110 for incineration of waste;
A heat exchange path 120 through which heat is generated by the heat transfer pipe 121 while the waste heat gas generated in the incinerator 110 passes, thereby obtaining steam;
Reaction tower 130 for neutralizing by spraying water or medicine to the waste heat gas passing through the heat exchange path 120; And
And a bag filter 140 installed with a large-capacity blower fan to collect dust in the waste heat gas that has passed through the reaction tower 130 and then discharge the air.
In the heat exchange path 120, the heat transfer pipe 121 is not installed, and a gravity space 125 having a size that can accommodate about one person is formed in at least one section, and the opening and closing door ( 126) is a heat exchange furnace for recovering the waste heat of the waste heat gas generated in the waste incinerator.

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