JP2003311241A - Heat treatment apparatus for fly ash - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a heat treatment apparatus for fly ash capable of preventing the separation of a salt, such as ammonium chloride, in a condenser. <P>SOLUTION: The heat treatment apparatus for the fly ash is provided with a heater 1 for heating the fly ash produced from an incineration furnace and the condenser 4 for cooling the heat treating gas produced by heating the fly ash in the heater 1 and is constructed to return the heat treating gas cooled in the condenser 4 to the heater 1. A washing column 20 passing the heat treating gas is disposed between the heater 1 and the condenser 4. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to fly ash that is discharged together with combustion exhaust gas from an incinerator of an incinerator such as municipal waste and industrial waste, and is collected by a dust collector such as an electric dust collector or a bag filter. The present invention relates to a device for heat treatment.

[0002]

2. Description of the Related Art Fly ash discharged from an incinerator together with combustion exhaust gas and collected is heat-treated for the purpose of reducing dioxins in the fly ash.

This type of fly ash often contains water such as chloride of heavy metals and water of crystallization of calcium chloride, as well as ammonium chloride and ammonium sulfate. That is, ammonia gas, hydrogen chloride, sulfur oxides, etc. contained in the flue gas discharged from the incinerator react and precipitate as ammonium chloride and ammonium sulfate due to the temperature drop during the flue gas treatment process, and are collected together with the dust. It In recent flue gas treatment processes, there are many cases where a bag filter is used to collect dust, and the operating temperature thereof tends to be maintained at a relatively low temperature (150 to 180 ° C). Whether or not ammonium chloride or ammonium sulfate is contained in the fly ash depends on the combustion exhaust gas temperature when passing through the dust collector in the combustion exhaust gas treatment process. Table 1 shows an example in which the bag filter is operated at a combustion exhaust gas temperature of 180 ° C. and when an electric dust collector is operated at a combustion exhaust gas temperature of 230 ° C. It should be noted that in Table 1, ∘ indicates inclusion, and x indicates not inclusion. Further, as can be seen from the thermodynamic equilibrium calculation results, the lower the temperature, the more these ammonium salts are contained in the fly ash.

[0004]

[Table 1]

When the collected fly ash is heat-treated for the purpose of reducing dioxins, the above-mentioned ammonium salt is contained in the heat-treated gas generated by heating in a decomposed state.

For example, in the case of ammonium chloride,
Although it is contained in the heat treatment gas in a state of being decomposed into NH ₃ and HCl, it may precipitate again as ammonium chloride as the heat treatment gas is cooled, which may cause a trouble that the gas flow is obstructed. . Hereinafter, this phenomenon will be specifically described in the conventional heat treatment apparatus.

FIG. 5 shows a conventional fly ash heat treatment apparatus.

In FIG. 5, the heat treatment apparatus comprises a heater (1) for heating fly ash generated from an incinerator of an incinerator, and a heat treatment gas generated by heating fly ash in the heater (1). Dust filter for removing dust inside (2)
And an inert gas supply device (3) for blowing an inert gas such as nitrogen gas to the outlet side of the filter part (2a) of the dust filter (2), and a condenser (for cooling the heat-treated gas from which dust has been removed ( 4) and a circulation fan (5) that returns the heat treatment gas cooled in the condenser (4) to the heater (1)
And a cooler (6) for cooling the fly ash that has been subjected to the heat treatment in the heater (1). Inert gas supply system (3)
The inert gas supplied to the dust filter (2) backwashes the dust filter (2) and at the same time maintains a low oxygen atmosphere in the heater (1).

The heater (1) comprises a horizontal heating cylinder (7) whose both ends are closed, an agitator (8) arranged in the heating cylinder (7),
It consists of a heater (9) arranged on the outer circumference of the heating cylinder (7), and an inlet (10) for charging fly ash to the peripheral wall of the heating cylinder (7) and an exhaust for discharging the heat-treated fly ash. The exit (11) is formed.

The cooler (6) comprises a lateral cooling cylinder (12) closed at both ends and an agitator (13) arranged in the cooling cylinder (12).
And a water jacket placed around the cooling tube (12)
(14), the cooling cylinder (12) has a receiving wall (15) for receiving the treated fly ash discharged from the discharge port (11) of the heating cylinder (7) and a cooled fly ash on the peripheral wall of the cooling cylinder (12). Discharge outlet (1
6) is formed.

In such a heat treatment apparatus, a heater
The fly ash charged into the heating cylinder (7) of (1) is conveyed toward the discharge port (11) by the density difference flow while being stirred by the stirring device (8), and the heater (9 By being heated by (4), the fly ash is subjected to a heat treatment for thermally decomposing dioxins, for example. The fly ash that has been subjected to the heat treatment is discharged from the discharge port (11) and sent into the cooling cylinder (12) of the cooler (6) through the reception port (15). The fly ash sent into the cooling cylinder (12) is conveyed toward the discharge port (16) by the density difference flow while being stirred by the stirring device (13), and during the conveyance, inside the water jacket (14). It is cooled by the flowing cooling water, which stabilizes the fly ash and prevents the regeneration of dioxins. afterwards,
Fly ash is discharged from the discharge port (16).

The heat treatment gas generated during the heat treatment in the heater (1) is circulated between the dust filter (2), the condenser (4) and the heater (1) by the circulation fan (5). After the dust is removed by the dust filter (2), it is cooled by the condenser (4) and heated by the heating cylinder of the heater (1).
Returned to (7). Hereinafter, this heat treatment gas is referred to as “circulation gas”. In addition, inert gas supply device
When the pressure in the system rises above a predetermined pressure by blowing an inert gas from (3), a part of the heat treatment gas is discharged out of the system.

When the fly ash is heat-treated, the water contained in the fly ash is discharged into the circulating gas as water vapor. By indirectly cooling the circulating gas with the condenser (4), the water vapor is condensed and separated. . As a result, the water content in the circulating gas is stably maintained at a low level, and the cooling cylinder (12) of the cooler (6) is
The occurrence of condensation trouble inside is prevented.

Further, the heat transfer surface of the condenser (4) is wetted by the condensed water generated by cooling the circulating gas, and ammonium salts such as ammonium chloride are dissolved in the condensed water to prevent precipitation of the salt. However, when the circulating gas is sent to the condenser (4), it is not saturated with water and the heat transfer surface of the condenser (4) remains dry until the temperature of the circulating gas drops to the dew point. . Therefore, the precipitation of ammonium salts such as ammonium chloride is unavoidable until the temperature of the circulating gas drops to the dew point and the heat transfer surface of the condenser (4) gets wet, and this precipitated salt impedes the flow of the circulating gas. However, as a result, safe operation of the heat treatment apparatus may be impaired.

An object of the present invention is to solve the above problems and provide a heat treatment apparatus for fly ash capable of preventing the precipitation of salts such as ammonium chloride in a capacitor.

[0016]

Means for Solving the Problems and Effects of the Invention A heat treatment apparatus for fly ash according to the invention of claim 1 is a heater for heating fly ash generated from an incinerator, and heating fly ash in the heater. Between the heater and the condenser in a fly ash heat treatment device, which is provided with a condenser for cooling the heat treatment gas generated by the above, and the heat treatment gas cooled by the condenser is returned to the heater. In addition, a water washing tower through which the heat treatment gas is passed is provided.

According to the heat treatment apparatus of the invention of claim 1,
Since a washing tower for passing circulating gas is installed between the heater and the condenser, the circulating gas flowing into the washing tower makes efficient contact with a large amount of water, and the water-soluble chloride contained in the circulating gas. Hydrogen is dissolved and removed by water, the circulating gas is subjected to humidification cooling (adiabatic cooling), and the circulating gas flows into the condenser. Since hydrogen chloride in the circulating gas has already been removed in the water washing tower, even when the circulating gas is indirectly cooled in the condenser, the production of ammonium salts such as ammonium chloride is prevented. Even if a small amount of hydrogen chloride remains in the circulating gas, since the circulating gas is saturated with water in the washing tower, the heat transfer surface of the condenser gets wet with condensed water when it flows into the condenser. Ammonium salts such as ammonium chloride dissolve in this condensed water. Therefore, the precipitation of ammonium salt is prevented and the circulating gas flows without obstruction, and as a result, the safe operation of the heat treatment apparatus is maintained.

A heat treatment apparatus for fly ash according to a second aspect of the present invention is a heater for heating fly ash generated from an incinerator, and a condenser for cooling heat treatment gas generated by heating fly ash in the heater. In a heat treatment apparatus for fly ash, wherein the heat treatment gas cooled by the condenser is returned to the heater, an ammonia oxidation decomposition catalyst is provided between the heater and the condenser. There is something.

According to the heat treatment apparatus of the invention of claim 2,
Since the ammonia oxidation decomposition catalyst is provided between the heater and the condenser, the ammonia contained in the circulating gas is decomposed as follows.

(A) 2NH ₃ → N ₂ + 3H ₂ (b) 2NH ₃ + O ₂ → 2NO + H ₂ O (c) 4NO + 4NH ₃ + O ₂ → 4N ₂ + 6H ₂ O ,
Since it then flows into the condenser, even when the circulating gas is indirectly cooled in the condenser, the production of ammonium salts such as ammonium chloride is prevented.

A heat treatment apparatus for fly ash according to a third aspect of the present invention is a heater for heating fly ash generated from an incinerator, and a condenser for cooling heat treatment gas generated by heating fly ash in the heater. In the fly ash heat treatment apparatus, wherein the heat treatment gas cooled by the condenser is returned to the heater, the ammonia oxidation decomposition catalyst and the heat treatment gas are provided between the heater and the condenser. A water washing tower is installed so that the latter comes to the downstream side.

According to the invention of claim 3, the following operational effects are exhibited. That is, since a washing tower for passing the ammonia oxidation decomposition catalyst and the heat treatment gas is provided between the heater and the condenser so that the latter is on the downstream side, a large amount of circulating gas flows into the washing tower. Water is efficiently contacted, water-soluble hydrogen chloride contained in the circulating gas is dissolved and removed by water, and the circulating gas is humidified and cooled (adiabatic cooling). Therefore, if the ammonia in the circulating gas is not completely decomposed by the ammonia oxidation decomposition catalyst,
Even if a small amount of ammonia remains in the circulating gas, when the circulating gas is indirectly cooled in the condenser, generation of ammonium salt such as ammonium chloride is prevented. Further, if the ammonia in the circulating gas is not completely decomposed by the ammonia oxidation decomposition catalyst, a small amount of ammonia remains in the circulating gas, and a small amount of hydrogen chloride remains in the circulating gas passing through the water washing tower. However, since the circulating gas is saturated with water in the washing tower, the heat transfer surface of the condenser gets wet with condensed water when it enters the condenser, and ammonium salts such as ammonium chloride dissolve in this condensed water. To do. Therefore, the precipitation of ammonium salt is prevented and the circulating gas flows without obstruction, and as a result, the safe operation of the heat treatment apparatus is maintained. When the pH of the washing water in the washing tower shifts to the strongly acidic side due to the decomposition of ammonia, it is desirable to control the pH of the washing water.

A heat treatment apparatus for fly ash according to a fourth aspect of the present invention is the same as that of the second or third aspect, wherein a catalyst tower is provided between the heater and the condenser for passing the heat treatment gas.
An ammonia oxidation decomposition catalyst is arranged in the catalyst tower.

A heat treatment apparatus for fly ash according to a fifth aspect of the present invention is the heat treatment apparatus according to the second or third aspect, wherein a dust filter for removing dust in the heat treatment gas is provided between the heater and the condenser. An ammonia oxidation decomposition catalyst is provided at the outlet of the heat treatment gas in the dust filter.

A heat treatment apparatus for fly ash according to a sixth aspect of the invention is the heat treatment apparatus according to the second or third aspect, wherein a dust filter for removing dust in the heat treatment gas is provided between the heater and the condenser. The filter part of the dust filter carries the ammonia oxidation decomposition catalyst.

[0026]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. In the following description, the same components as those shown in FIG. 5 will be assigned the same reference numerals and overlapping explanations will be omitted.

Embodiment 1 The present invention is shown in FIG. In FIG. 1, a washing tower (20) is provided between the dust filter (2) and the condenser (4). In the water washing tower (20), the circulating gas flows into the tower (20) from the lower end, flows upward, and flows from the upper end to the tower (2).
0) It flows out to the outside, and water is further ejected from the upper end toward the circulating gas.

In the heat treatment apparatus having such a structure,
The fly ash is treated in the same manner as in the heat treatment apparatus shown in FIG.

The circulating gas generated during the heat treatment in the heater (1) is supplied to the dust filter (2), the washing tower (20), the condenser (4) and the heater (1) by the circulation fan (5). It is circulated between the dust filters (2) to remove dust, and then the water washing tower (20) dissolves and removes hydrogen chloride and is saturated with water, and further cooled by the condenser (4) and heated. It is returned to the heating cylinder (7) of the vessel (1).

The circulating gas flowing into the water washing tower (20) efficiently contacts with a large amount of water, the water-soluble hydrogen chloride contained in the circulating gas is dissolved and removed by the water, and the circulating gas is subjected to humidification cooling. (Adiabatic cooling) and this circulating gas
It flows into (4). And since hydrogen chloride in the circulating gas has already been removed in the water washing tower (20), the condenser
Even when the circulating gas is indirectly cooled in (4), the formation of ammonium salts such as ammonium chloride is prevented. Even if a small amount of hydrogen chloride remains in the circulating gas, the circulating gas is saturated with water in the washing tower (20). The heat transfer surface is wetted by the condensed water, and an ammonium salt such as ammonium chloride is dissolved in the condensed water. Therefore, precipitation of ammonium chloride or the like in the condenser (4) is prevented, and the circulating gas flows in the condenser (4) without being obstructed. As a result, the safe operation of the heat treatment device is maintained.

When the fly ash is heat-treated, the water contained in the fly ash is discharged into the circulating gas as water vapor. By indirectly cooling the circulating gas with the condenser (4), the water vapor is condensed and separated. . As a result, the water content in the circulating gas is stably maintained at a low level, and the cooling cylinder (12) of the cooler (6) is
The occurrence of condensation trouble inside is prevented.

The water ejected from the water washing tower (20) is stored in the drain tank (21) and then sent to the water washing tower (20) by the pump (22) for reuse. Also capacitors (4)
The condensed water generated in 1 is also stored in the drain tank (21) and then sent to the water washing tower (20) by the pump (22) for reuse. When the pH of the water in the water washing tower (20) becomes low, the pH is adjusted with an alkali.

Table 2 shows the results of measuring the temperature and the water content of the circulating gas at the positions A, B and C in FIG.

[0034]

[Table 2]

Embodiment 2 This embodiment is shown in FIG. In FIG.
A catalyst tower (25) for passing a circulating gas is provided between the dust filter (2) and the condenser (4). An ammonia oxidation decomposition catalyst layer (26) made of, for example, a platinum-silica-alumina-based catalyst is arranged in the middle of the height in the catalyst tower (25). The circulating gas that has passed through the dust filter (2) is
It flows into the tower (25) from the lower end of (25), passes through the ammonia oxidation decomposition catalyst layer (26), then flows out of the tower (25) from the upper end, and further flows into the condenser (4). It has become.

In the heat treatment apparatus having such a structure,
The fly ash is treated in the same manner as in the heat treatment apparatus shown in FIG.

The circulating gas generated during the heat treatment in the heater (1) is supplied to the dust filter (2), the catalyst tower (25), the condenser (4) and the heater (1) by the circulation fan (5). After being circulated between them, the dust is removed in the dust filter (2), the ammonia is decomposed and removed in the catalyst tower (25), and further cooled by the condenser (4) to be heated by the heater (1).
It is returned to the heating cylinder (7).

When the circulating gas flowing into the catalyst tower (25) passes through the ammonia oxidation decomposition catalyst layer (26), ammonia is decomposed and removed by the above reactions (a) to (c). Then, the circulating gas from which ammonia has been removed is then condensed into the condenser (4).
Therefore, even when the circulating gas in the condenser (4) is indirectly cooled, the production of ammonium salts such as ammonium chloride is prevented.

When the fly ash is heat-treated, the water contained in the fly ash is discharged as water vapor into the circulating gas. By indirectly cooling the circulating gas with the condenser (4), the water vapor is condensed and separated. . As a result, the water content in the circulating gas is stably maintained at a low level, and the cooling cylinder (12) of the cooler (6) is
The occurrence of condensation trouble inside is prevented.

Embodiment 3 This embodiment is shown in FIG. In FIG.
At the heat treatment gas outlet portion (2a) on the downstream side of the filter portion (2a) in the dust filter (2), an ammonia oxidation decomposition catalyst layer made of, for example, a platinum-silica-alumina catalyst is formed.
(30) is provided. Therefore, the circulating gas from which dust has been removed by the filter part (2a) passes through the ammonia oxidation decomposition catalyst layer (30), then flows out of the dust filter (2) and flows into the condenser (4). .

In the heat treatment apparatus having such a structure,
The fly ash is treated in the same manner as in the heat treatment apparatus shown in FIG.

The circulating gas generated during the heat treatment in the heater (1) is circulated between the dust filter (2), the condenser (4) and the heater (1) by the circulation fan (5), After the dust is removed by the dust filter (2), ammonia is decomposed and removed at the outlet portion (2b) of the dust filter (2), and further cooled by the condenser (4) to cool the heating cylinder (7) of the heater (1). ) Is returned in.

When the circulating gas that has passed through the filter part (2a) of the dust filter (2) passes through the ammonia oxidation decomposition catalyst layer (30), ammonia is decomposed and removed by the reactions (a) to (c). The circulating gas from which ammonia has been removed then flows into the condenser (4), so
Even when the circulating gas is indirectly cooled in (4), the formation of ammonium salts such as ammonium chloride is prevented.

When the fly ash is heat-treated, the water contained in the fly ash is discharged as water vapor into the circulating gas, but this water vapor is condensed and separated by indirectly cooling the circulating gas with the condenser (4). . As a result, the water content in the circulating gas is stably maintained at a low level, and the cooling cylinder (12) of the cooler (6) is
The occurrence of condensation trouble inside is prevented.

Table 3 shows the decomposition performance of ammonia in the devices of Embodiments 2 and 3 together with the decomposition treatment conditions.

[0046]

[Table 3]

In Table 3, AV means the unit geometric surface area of the catalyst and the amount of processing gas per unit time.

Embodiment 4 This embodiment is shown in FIG. In FIG.
The filter part (2a) of the dust filter (2) carries an ammonia oxidation decomposition catalyst (31) made of, for example, a platinum-silica-alumina catalyst.

In the heat treatment apparatus having such a structure,
The fly ash is treated in the same manner as in the heat treatment apparatus shown in FIG.

The circulating gas generated during the heat treatment in the heater (1) is circulated between the dust filter (2), the condenser (4) and the heater (1) by the circulation fan (5), At the same time as dust is removed in the dust filter (2), ammonia is decomposed and removed by the ammonia oxidation decomposition catalyst (31), and further cooled by the condenser (4) to be placed in the heating cylinder (7) of the heater (1). Will be returned.

When the circulating gas passes through the filter part (2a) of the dust filter (2), the dust in the circulating gas is removed and the ammonia in the circulating gas is decomposed by the reactions (a) to (c). To be removed. Then, the circulation gas from which the ammonia has been removed flows into the condenser (4) thereafter, so that even when the circulation gas is indirectly cooled in the condenser (4), the production of ammonium salts such as ammonium chloride is prevented.

When the fly ash is heat-treated, the water contained in the fly ash is discharged into the circulating gas as water vapor, but this water vapor is condensed and separated by indirectly cooling the circulating gas with the condenser (4). . As a result, the water content in the circulating gas is stably maintained at a low level, and the cooling cylinder (12) of the cooler (6) is
The occurrence of condensation trouble inside is prevented.

Table 4 shows the decomposition performance of ammonia in the apparatus of Embodiment 4 together with the decomposition treatment conditions.

[0054]

[Table 4]

In the second embodiment described above, the catalyst tower (25)
And a condenser (4), and in the third and fourth embodiments, a washing tower (20) similar to that of the first embodiment may be provided between the dust filter (2) and the condenser (4). .

In this case, the circulating gas from which ammonia has been decomposed and removed flows into the water washing tower (20) from the lower end. Water washing tower
The circulating gas flowing into the (20) efficiently contacts with a large amount of water ejected from the upper end of the tower (20), and water-soluble hydrogen chloride contained in the circulating gas is dissolved and removed by water, The circulating gas is humidified and cooled (adiabatic cooling), and the circulating gas flows into the condenser (4). Since the hydrogen chloride in the circulating gas has already been removed in the water washing tower (20), the ammonia in the circulating gas is not completely decomposed by the ammonia oxidation decomposition catalyst, and a trace amount of ammonia remains in the circulating gas. Even if the circulating gas is indirectly cooled in the condenser (4), generation of ammonium salt such as ammonium chloride is prevented. Further, if the ammonia in the circulating gas is not completely decomposed by the ammonia oxidation decomposition catalyst, a small amount of ammonia remains in the circulating gas, and a small amount of chloride is contained in the circulating gas passing through the water washing tower (20). Even if hydrogen remains, since the circulating gas is saturated with water in the water washing tower (20), the heat transfer surface of the condenser (4) gets wet with condensed water when it flows into the condenser (4). Ammonium salts such as ammonium chloride dissolve in this condensed water. Therefore, the precipitation of ammonium salt is prevented and the circulating gas flows without obstruction, and as a result, the safe operation of the heat treatment apparatus is maintained.

Although not shown in FIGS. 2 to 4, the water ejected from the water washing tower (20) is discharged from the drain tank (2).
After being stored in 1), it is sent to the water washing tower 20 by the pump 22 and reused. Also, the condensed water generated in the condenser (4) is also stored in the drain tank (21), and then the pump (22)
Is sent to the water washing tower (20) for reuse.

[Brief description of drawings]

FIG. 1 is a diagram schematically showing a configuration of a fly ash heat treatment apparatus according to a first embodiment of the present invention.

FIG. 2 is a diagram schematically showing a configuration of a heat treatment apparatus for fly ash according to a second embodiment of the present invention.

FIG. 3 is a diagram schematically showing a configuration of a fly ash heat treatment apparatus according to a third embodiment of the present invention.

FIG. 4 is a diagram schematically showing a configuration of a fly ash heat treatment apparatus according to a fourth embodiment of the present invention.

FIG. 5 is a diagram schematically showing a configuration of a conventional fly ash heat treatment apparatus.

[Explanation of symbols]

(1): Heater (2): Dust filter (2a): Filter section (2b): Exit section (4): Capacitor (20): Washing tower (25): Catalyst tower (26): Ammonia oxidation decomposition catalyst layer (30): Ammonia oxidation decomposition catalyst layer (31): Ammonia oxidation decomposition catalyst

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Haruo Sakaguchi             1-89 Minami Kohoku 1-89, Suminoe-ku, Osaka             Standing Shipbuilding Co., Ltd. (72) Inventor Yasuo Sato             1-89 Minami Kohoku 1-89, Suminoe-ku, Osaka             Standing Shipbuilding Co., Ltd. (72) Inventor Shinya Tamai             1-89 Minami Kohoku 1-89, Suminoe-ku, Osaka             Standing Shipbuilding Co., Ltd. (72) Inventor Shimonosono Encouragement             1-89 Minami Kohoku 1-89, Suminoe-ku, Osaka             Standing Shipbuilding Co., Ltd. F-term (reference) 3K061 NA01 NA13                 4D002 AA13 AA19 AC10 BA02 BA05                       BA13 BA14 CA07 DA35 DA70                       EA02 HA06                 4D004 AA37 AB07 AC05 CA22 CA24                       CA32 CB28 CB31 CB32 CB43

Claims (6)

[Claims] 1. A heating device for heating fly ash generated from an incinerator, and a condenser for cooling heat treatment gas generated by heating fly ash in the heating device,
In a fly ash heat treatment device in which heat treated gas cooled by a condenser is returned to the heater, a washing tower for passing the heat treated gas is provided between the heater and the condenser. Characterized fly ash heat treatment device. 2. A heating device for heating fly ash generated from an incinerator, and a condenser for cooling heat treatment gas generated by heating fly ash in the heating device,
In a fly ash heat treatment device in which heat treatment gas cooled by a condenser is returned to the heater, a fly ash heat treatment in which an ammonia oxidation decomposition catalyst is provided between the heater and the condenser. apparatus. 3. A heating device for heating fly ash generated from an incinerator, and a condenser for cooling heat treatment gas generated by heating fly ash in the heating device,
In a fly ash heat treatment device in which a heat treatment gas cooled by a condenser is returned to a heater, a washing tower for passing an ammonia oxidation decomposition catalyst and the heat treatment gas between the heater and the condenser, Fly ash heat treatment device installed so that the latter is on the downstream side. 4. The fly ash heat treatment according to claim 2, wherein a catalyst tower for passing a heat treatment gas is provided between the heater and the condenser, and an ammonia oxidation decomposition catalyst is arranged in the catalyst tower. apparatus. 5. A dust filter for removing dust in the heat treatment gas is provided between the heater and the condenser,
The ammonia oxidation decomposition catalyst is provided at the outlet of the heat treatment gas in the dust filter.
Heat treatment device for fly ash described. 6. A dust filter for removing dust in the heat treatment gas is provided between the heater and the condenser,
The heat treatment apparatus for fly ash according to claim 2 or 3, wherein the filter part of the dust filter carries an ammonia oxidation decomposition catalyst.