JP2007248007A - Waste melting treatment device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a waste melting treatment device carrying out direct heating of a slope for half-molten material outflowing out of a shaft kiln type melting furnace bottom section to a heat maintaining furnace by burner flame by burning inflammable dust by a burner, and achieving compactification of a facility and improvement of long-term stability of the facility. <P>SOLUTION: The horizontal heat maintaining furnace 6 is connected in a connected state to a side face of a shaft kiln type melting furnace 1 having a plurality of tuyeres in the bottom section 5. The heat maintaining furnace 6 is provided with a half-molten material heating burner 10 burning the inflammable dust discharged from a melting furnace 1 to directly heat the half-molten material flowing out from the bottom section 5, and a slug discharge opening 8 discharging slug. A waste treatment device is provided with a slug discharge chute 14 provided around the slug discharge opening 8 facing vertically downwards, and a water granulation pit 16 carrying out water seal of the slug discharge chute 14 for carrying out water granulation of the slug discharged from the slug discharge opening 8 and falling through the slug discharge chute. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a waste melting apparatus that burns combustible dust in a heat retaining furnace connected to the bottom of a shaft furnace type melting furnace to directly heat the melt to reduce the amount of coke used.

  The shaft furnace type melting furnace can solve various problems such as the remaining years of the final disposal site because it can reduce the volume of molten waste such as general waste, industrial waste, etc. It is effective as a waste disposal device.

  In a system in which waste is processed in a shaft furnace type melting furnace, it is required to reduce the operating cost, particularly to reduce the amount of coke used as a fuel source.

  As a method of reducing the amount of coke used as a fuel source in shaft furnace type melting furnaces, combustible dust (char) discharged from the top of the furnace is blown from the tuyere and burned, and the coke function is partially substituted with the amount of heat. There exists a technique to do (patent document 1). However, in this conventional technique, due to the combustibility problem of combustible dust, there is a limit to the coke replacement ratio by combustible dust, and a sufficient coke reduction effect cannot be obtained. In addition, when combustible dust is supplied directly from the tuyere to the bottom of the furnace and burned, there is less space in front of the tuyere and combustion occurs in the packed bed, resulting in a deterioration in the combustibility of the combustible dust. As the coke replacement rate was limited.

  Therefore, in order to effectively burn the dust blown into the bottom of the furnace and suppress the consumption of coke, the present applicant provides a combustion melting furnace in the vicinity of the bottom of the shaft furnace type melting furnace and the bottom of the shaft type melting furnace. We proposed a melting technology that uses a sensible heat to connect the combustion melting furnace to the combustion melting furnace, burn the fuel in the combustion melting furnace, and supply the generated high-temperature exhaust gas to the bottom of the furnace from the communication section. 2).

FIG. 2 is a schematic view of a shaft furnace type melting furnace provided with a combustion melting furnace disclosed in the patent document. In FIG. 2, a combustion melting furnace 24 is connected to a furnace bottom portion 22 of a shaft furnace type melting furnace 21 by a communication portion 23. The waste 25 charged from the top of the furnace is blown in air from the upper tuyere 26 and oxygen-enriched air is blown in from the lower tuyere 27, and combustion of the pyrolysis residue of coke and some wastes causes It is dried, pyrolyzed, burned and melted in the furnace. The melt is discharged from a tap outlet 28 installed in the hearth of the combustion melting furnace 24. Combustible dust and air or oxygen-enriched air are blown from the tuyere 29 for injecting combustible dust provided in the combustion melting furnace 24, the combustible dust is burned in the combustion melting furnace, and the exhaust gas 30 generated by the combustion is exhausted. Is used as a melting heat source.
JP 2001-21123 A JP 2004-301494 A

  In the melting treatment technique described in Patent Document 2, since a combustion melting furnace for generating exhaust gas is separately installed via a communication part, the equipment becomes large, and the construction cost and the increase in the heat radiation amount become problems. In addition, the combustion in the combustion melting furnace is space combustion, but there is no high-temperature heat source such as coke at the bottom of the shaft furnace melting furnace, so the combustibility is poor, and part of the end fuel remains in the slag. Therefore, it is necessary to add auxiliary fuel.

  In addition to the high temperature of the combustion melting furnace, there is a problem that the refractory life is shortened because slag always flows. In addition, as a result of refractory erosion caused by the slag flow at the slag discharge part, slag dripping adheres to the chute wall surface and grows, and finally the chute becomes blocked.

  Accordingly, the present invention directly heats the slope of the semi-molten material introduced from the bottom of the shaft furnace type melting furnace into the heat-retaining furnace with a burner flame of a burner that uses combustible dust as fuel, and combustible dust combustion. To provide a waste melting treatment equipment that can achieve a long-term stability improvement by eliminating the combustion melting furnace and reducing the size of the equipment, and cooling the heat-retaining furnace and improving the slag discharge fireproof structure. Is.

  In the waste treatment apparatus of the present invention, a horizontal heat-retaining furnace is connected in communication with a side surface of a shaft furnace-type melting furnace having a plurality of tuyere at the furnace bottom, and the heat-retaining furnace includes a shaft furnace-type melting furnace. A semi-molten heating burner that directly heats the semi-melt flowing from the furnace bottom by burning the combustible dust discharged from the furnace and a slag discharge port for discharging the slag, and surrounding the slag discharge port vertically The slag discharge chute provided downward and the slag discharge chute are sealed with water, and a granulation pit is provided for granulating the slag discharged from the slag discharge port and falling in the slag discharge chute .

  In the conventional technology in which a separate combustion melting furnace is provided in the shaft furnace type melting furnace, combustible dust is burned in the combustion melting furnace, and then the high-temperature exhaust gas is introduced into the bottom of the furnace for sensible heat utilization. However, in the present invention, a semi-molten heating burner is installed in the heat-retaining furnace, and the semi-melt is directly heated by the burner flame. Can be reduced, and the semi-melt can be efficiently heated. Moreover, the heating efficiency of the semi-molten by the semi-molten heating burner is improved by the luminous flame radiation effect at the time of combustible dust combustion.

  Also, when combustible dust is blown from the burner for heating the semi-melt, combustibility of the combustible dust becomes a problem, but the area around the burner for heating the semi-melt is a space, and the space is a high-temperature shaft furnace. Since it is close to the bottom of the furnace of the type melting furnace, the temperature is almost the same as that of the bottom of the furnace, close to 1600 ° C. As a result, it was possible to reduce the amount of added auxiliary fuel, and there was no remaining unburned fuel in the slag.

  In addition, by directly heating the slope of the melt introduced from the shaft furnace type melting furnace to the heat insulation furnace with a burner flame, the combustion heat of the burner can be efficiently used as a melting heat source, so the coke ratio can be reduced. Also grows.

  FIG. 1A is a schematic view of a waste melting apparatus of the present invention, FIG. 1B is a sectional view of a slag flow path, and FIG. 1C is a plan view.

  A shaft furnace type melting furnace (hereinafter referred to as “melting furnace”) 1 is provided with a plurality of upper tuyere 3 for blowing air to burn the pyrolysis residue of the waste 2, and coke and pyrolysis residue are placed below it. A plurality of lower tuyere 4 for supplying oxygen or oxygen-enriched air for combustion is arranged. A heat-retaining furnace 6 is connected to the furnace bottom 5 of the melting furnace 1 in horizontal communication with the side surface.

  The furnace bottom 7 of the melting furnace 1 is inclined downward in the direction of the heat insulation furnace. The inclination angle is a gentle inclination of about 15 °. Due to this inclination, the semi-molten product can be smoothly discharged to the heat insulating furnace 6. Further, the lower tuyere 4 is also arranged so as to be located downward along a spiral trajectory toward the heat-retaining furnace in accordance with the inclination angle of the furnace bottom 7. With this arrangement, the semi-molten product can be smoothly discharged to the heat insulating furnace 6.

  A slag tap 8 for discharging slag is provided at the end opposite to the melting furnace 1 on the hearth of the heat insulating furnace 6, and the ceiling is introduced into the heat insulating furnace 6 from the side surface of the bottom 5 of the melting furnace 1. A melt heating burner 10 for directly heating the semi-melt 9 is provided.

  The semi-molten heating burner 10 uses the combustible dust discharged from the melting furnace 1 as fuel. The semi-molten heating burner 10 is positioned so that the semi-melt 9 can be directly heated by the flame of the semi-melt heating burner 10 in order to facilitate the discharge of the semi-melt 9 from the bottom 5 of the melting furnace 1. Deploy. The semi-melt heating burner 10 is installed so that the distance from the slope formed by the semi-melt 9 introduced into the heat-retaining furnace 6 is 100 to 800 mm. The semi-melt heating burner 10 is preferably installed at a distance of 800 mm or less from the slope of the semi-melt 9 for effective direct heating, but if the distance from the slope is too close, combustible dust Before the completion of combustion, it hits the semi-melted slope, and unburned combustible dust is mixed in the discharged slag, so the distance is set to 100 mm or more.

  As the semi-molten heating burner 10, a triple tube burner is adopted to further reduce coke, and the triple tube burner is supplied with combustible dust, fuel such as LPG, and oxygen for fuel combustion for combustion. . This semi-melt heating burner 10 can improve the combustibility of combustible dust and improve the coke reduction rate.

The superficial velocity at the shaft of the melting furnace 1 is basically 0.7 m / sec in the existing technology. By increasing the superficial velocity by increasing the superficial velocity to 1.0 to 2.0 m / sec, combustible dust is obtained. It is possible to further reduce the coke by increasing the amount of generated and blowing the increased amount into the burner 10 for heating the semi-melt. In addition, since the heat-retaining furnace 6 can be used as a fuel without any problem if it has a certain degree of combustibility because of space combustion in the high-temperature part, it assists various combustible materials such as powdered biomass such as dry sludge and waste plastics. It can be used as a fuel, and the cost and CO ₂ can be reduced.

  The slag flow path in the hearth of the heat insulation furnace 6 flows slag of 1500 ° C. or more, and the atmosphere of the whole heat insulation furnace becomes a high temperature of 1500 to 1600 ° C. In order to prevent this, a water-cooled refractory structure is provided in which the water-cooled wall 11 is provided by a jacket or a water-cooled snake pipe over the entire circumference of the heat-retaining furnace 6. The slag flow path can protect the wall surface by self-coating with slag, and the other surfaces can be cooled by water cooling walls. By reducing the thickness of the refractory layer 12 to 50 mm or less by the water-cooled refractory structure, the refractory thickness is reduced, and the surrounding metal surrounding it can be made compact. As a result, the entire heat-retaining furnace is compact. Can be

  Further, a groove 13 is formed as a slag flow path in the hearth of the heat insulating furnace 6, and the slag flow is concentrated by the groove 13, so that a slag discharge chute provided from the heat insulating furnace 6 below the slag discharge port 8. By suppressing the temperature drop of the slag in the 14 low temperature region (1200 to 1400 ° C.), good slag discharge can be continued. The slag discharge port extends to the center of the slag discharge chute so that the slag drops from the center of the slag discharge chute. In addition, by using a water-cooled refractory structure to prevent the shape of the discharge portion of the slag discharge port 8 from changing, the slag dripping location can be kept constant and blockage caused by wall surface adhesion on the slag discharge chute 14 can be prevented. .

  The slag discharge port 8 has a structure in which the flowing slag travels along the vertical wall surface 15 and drops onto the granulated pit 16. In order to prevent the vertical wall surface 15 from spreading on the vertical wall surface 15 when the slag flowing through the heat insulating furnace 6 drops along the vertical wall surface 15, it is desirable to form a groove in advance.

  Since the growth of icicles due to slag or refractory metal is considered at the lower end of the vertical wall 15, the burner 17 for preventing growth is directed upward from the bottom, and the flame is cut at the lower end of the slag discharge port which is the growth point of the icicles. It may be arranged on the slag discharge chute 14 so that it can be aimed. Further, a thrust mechanism may be provided.

  Moreover, since the vertical wall surface 15 may be eroded by the slag flow, the water cooling pipe 18 prevents the erosion as the water cooling structure and maintains the original shape.

  Below the slag discharge port 8, a space where slag drops from the vertical wall surface 15 to the granulated pit 16 is surrounded by a slag discharge chute 14, and the slag discharge chute 14 is sealed with the granulated pit 16. The water seal height of the slag discharge chute 14 and the granulated pit 16 is 500 mm or more. By setting the water seal height to 500 mm or more, it is possible to prevent gas leakage outside even when the pressure difference in the furnace fluctuates. Further, in the slag discharge chute 14, there is a possibility that the dripping slag adheres to the wall surface, grows and becomes clogged. Therefore, the wall surface of the slag discharge chute 14 has a wet wall structure that allows water to flow along the wall surface. Slag adhesion to the wall surface of the slag can be prevented.

(A) is the schematic of the waste melting apparatus of this invention, (b) is sectional drawing of a slag flow path, (c) is a top view. It is the schematic of the waste melting furnace provided with the conventional combustion melting furnace.

Explanation of symbols

1: Melting furnace 2: Waste 3: Upper tuyere 4: Lower tuyere 5: Furnace bottom 6: Thermal furnace 7: Furnace bottom 8: Slag discharge 9: Semi-melt 10: Semi-melt heating burner 11 : Water-cooled wall 12: Refractory layer 13: Groove 14: Slag discharge chute 15: Vertical wall surface 16: Granulated pit 17: Burner 18: Water-cooled pipe 21: Shaft furnace type melting furnace 22: Furnace bottom part 23: Communication part 24: Combustion melting Furnace 25: Waste 26: Upper tuyere 27: Lower tuyere 28: Outlet 29: Tuyere for blowing combustible dust

Claims (12)

A horizontal heat-retaining furnace is connected and connected to the side surface of the shaft furnace type melting furnace having a plurality of tuyere at the bottom of the furnace,
The heat-retaining furnace is provided with a semi-melt heating burner that directly heats the semi-melt flowing out from the furnace bottom, and a slag discharge port that discharges slag,
A slag discharge chute that surrounds the slag discharge port and is provided vertically downward;
A waste treatment apparatus comprising a water granulation pit for water granulating a slag discharge chute and water slag discharged from a slag discharge port and falling inside the slag discharge chute.   The waste treatment apparatus according to claim 1, wherein the semi-molten heating burner collects combustible dust scattered from a shaft furnace type melting furnace and uses it as fuel.   The semi-molten heating burner is installed on the upper surface of the heat insulating furnace so that the tip thereof is at a distance of 100 to 800 mm from the slope of the semi-melt flowing into the heat insulating furnace. Waste treatment equipment.   The plurality of tuyere of the shaft furnace type gasification melting furnace are arranged to be inclined downward along a spiral trajectory in the direction of the heat-retaining furnace. Waste melting treatment equipment.   The waste melting apparatus according to any one of claims 1 to 4, wherein the bottom of the shaft furnace type melting furnace is inclined downward toward the heat-retaining furnace.   The waste heat treatment apparatus according to any one of claims 1 to 5, wherein the heat-retaining furnace has an all-around water-cooled refractory structure.   The waste melting apparatus according to any one of claims 1 to 6, wherein a groove through which a melt flows is provided in the bottom floor of the heat insulation furnace.   The waste melting apparatus according to any one of claims 1 to 7, wherein the slag discharge port is extended to the center of the slag discharge chute so that the slag is dropped from the center of the slag discharge chute.   The waste melting apparatus according to any one of claims 1 to 8, wherein the slag discharge port has a water cooling structure.   The slag discharge chute is provided with a heating burner for preventing icicle growth from the slag discharge port, the wall surface has a wet wall structure, and the water seal height of the granulated pit is 500 mm or more. Item 10. The waste melting apparatus according to any one of Items 1 to 9.   The waste according to any one of claims 1 to 10, wherein finer combustible waste or an intermediate treatment product thereof, and powdery biomass such as waste plastic and dry sludge are supplied to the melt heating burner. Material melting processing equipment.   The shaft diameter of the shaft furnace type melting furnace is such that the cylinder speed of the gas passing through the shaft is 1.0 to 2.0 [m / s]. The waste melting treatment apparatus described.

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