JP3516260B2 - Waste melting furnace - Google Patents

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a waste melting furnace, and more particularly to a slag discharge structure for a waste melting furnace.

[0002]

2. Description of the Related Art Generally, exhaust gas and slag are generated when a waste material (for example, incinerated ash in a refuse processing plant or dust containing valuable metal in a steel mill) is melt-processed in a waste melting furnace. Then, the exhaust gas is guided to the secondary combustion chamber,
After secondary combustion here, it is detoxified and exhausted through a heat recovery facility, an exhaust gas cooling facility, a dust removing device, and the like. On the other hand, the slag is collected as described later.

Here, a conventional waste melting furnace will be outlined with reference to FIG. The waste melting furnace shown is a melting furnace 1.
1 and a secondary combustion tower 12 connected to the melting furnace 11. The secondary combustion tower 12 has a secondary combustion chamber 12a and a slag discharge duct 12b.

In the waste melting furnace shown in the figure, the waste is first sent to the melting furnace 11, where the waste is heated in a reducing atmosphere and thermally decomposed. That is, the waste that has been charged from the inlet of the melting furnace 11 is melted while being moved in the outlet direction (rightward in the figure). At this time, slag and exhaust gas are generated in the melting furnace 11. The illustrated melting furnace 11 has an outlet 11a having the same exhaust gas outlet and slag outlet, and the exhaust gas discharged from the outlet 11a is the secondary combustion chamber 12
After secondary combustion in a, it is detoxified and discharged through, for example, a waste heat recovery facility, an exhaust gas cooling facility, a dust removing device, or the like.

On the other hand, the slag accumulated in the melting furnace 11 is sent toward the outlet, and the slag discharge duct 12 is discharged from the outlet 11a.
fall to b. A slag cooling water tank 13 is provided below the slag discharge duct 12b, and a slag transport cooling conveyor (not shown) is installed in the water tank 13, and the slag cooling water tank 13 discharges the slag cooling water tank 13 to the slag cooling water tank 13. The slag is carried out by the slag transport conveyor while being cooled here. In addition, slag discharge duct 1
The 2b and the slag cooling water tank 13 are sealed by a water seal to prevent atmospheric air from entering the secondary combustion tower 12.

[0006]

In the waste melting furnace, the exhaust gas rises up in the secondary combustion tower 12 and is guided to the secondary combustion chamber 12a. As a result, dust ( Condensates of volatile components, exhaust gas entrained waste particles, etc.) inevitably adhere. Then, in the case of the waste melting furnace as shown in FIG. 4, that is, when the slag and the exhaust gas are discharged from the melting furnace 11 from the same outlet, the secondary combustion chamber 12a is increased by the rise of the exhaust gas (due to the influence of the exhaust gas). Dust adhering to the inner surface of the slag may fall into the slag.

Heavy metals are sometimes concentrated in the adhering dust. When such adhering dust is mixed in the slag, the slag component is not stable and sometimes the slag is partially contaminated. Therefore, there is a problem in that the reuse of the slag (for example, the reuse as the construction material) is adversely affected.

An object of the present invention is to provide a waste melting furnace capable of reliably separating and collecting dust and slag attached and deposited on the inner surface of the secondary combustion chamber of the melting furnace.

[0009]

According to the present invention, a melting furnace for melting waste to discharge exhaust gas containing dust and slag from the same outlet; and a secondary combustion of the exhaust gas connected to the outlet. and a secondary combustion chamber to the outlet of the melting furnace, the in waste melting furnace which opens at the bottom of the secondary combustion chamber, outside the slag falling from the outlet is arranged in the exit of There is provided a waste melting furnace characterized by having a slag discharge duct which discharges into the interior of the secondary combustion chamber and a dust discharge duct which is arranged apart from the outlet and discharges dust falling from the inner wall of the secondary combustion chamber to the outside.

A gas discharge means for discharging the exhaust gas into the secondary combustion chamber and causing the swirling motion in the secondary combustion chamber may be provided at the outlet of the melting furnace.

[0011]

DETAILED DESCRIPTION OF THE INVENTION The present invention will be described below with reference to the drawings.

An example of the waste melting furnace according to the present invention will be described with reference to FIG. The illustrated waste melting furnace includes a melting furnace 21 and a secondary combustion tower 22 connected to the melting furnace 21, and a secondary combustion chamber 22a is formed in the secondary combustion tower 22 and a slag discharge duct 22b is formed. And a dust discharge duct 22c is formed.

In the illustrated melting furnace 11, the exhaust gas discharge port and the slag discharge port are formed as the same outlet 11a, and the slag discharge duct 22b is positioned on the outlet side of the melting furnace 21. On the other hand, the dust discharge duct 22c is connected to the melting furnace 21.
Of the secondary combustion chamber 22a, and its inlet is located immediately below the secondary combustion chamber 22a.

A slag cooling water tank 23 equipped with a slag carry-out conveyor (not shown) below the slag discharge duct 22b.
Is installed, and the slag discharge duct 22b and the slag cooling water tank 23 are sealed with a water seal in order to prevent atmospheric air from entering the secondary combustion tower 22. Further, a dust cooling water tank 24 equipped with a dust discharging conveyor (not shown) is arranged below the dust discharging duct 22c, and the dust discharging duct 22c and the dust cooling water tank 24 are provided in the secondary combustion tower 22. It is sealed with a water seal to prevent air from entering.

In the illustrated waste melting furnace, the waste is first sent to the melting furnace 21, where the waste is heated in a reducing atmosphere and pyrolyzed. That is, the waste that has been introduced from the inlet of the melting furnace 21 is melted while being moved in the outlet direction (rightward in the figure). At this time, slag and exhaust gas are generated from the melting furnace 21.

Exhaust gas discharged from the outlet 21a of the melting furnace 21 rises in the secondary combustion tower 22 and rises in the secondary combustion chamber 22a.
After being secondarily burned in the secondary combustion chamber 22a, it is detoxified and discharged through, for example, a heat recovery facility, an exhaust gas cooling facility, a dust collector, and the like. At this time, the dust in the exhaust gas settles down by gravity and falls into the dust discharge duct 22c, or collides with the inner wall of the secondary combustion chamber 22a, and the secondary combustion chamber 22
Dust inevitably accumulates (attaches) on the inner surface of a.

On the other hand, the slag melted in the melting furnace 21 is sent toward the outlet and reaches the outlet 21a. As aforementioned,
Since the slag discharge duct 22b is positioned near the outlet 21a, the slag drops from the outlet 11a directly to the slag discharge duct 22b. Then, the slag discharged from the slag discharge duct 22b is cooled in the slag cooling water tank 23, and is discharged to the outside by a slag unloading conveyor (not shown) provided in the slag cooling water tank 23.

By the way, in the waste melting furnace shown in the figure, as described above, the dust discharge duct 22c is positioned away from the outlet of the melting furnace 21, that is, the slag drop axis and the dust drop axis are arranged. Since they are arranged in a staggered manner, even if dust adhered / accumulated on the inner surface of the secondary combustion chamber 22a falls, this dust will be directly absorbed by the dust discharge duct 22.
It falls to c. The slag discharged from the dust discharge duct 22c is discharged to the outside separately from the slag by a dust conveyor (not shown).

As described above, in the illustrated example, since the slag discharge duct 22b and the dust discharge duct 22c are provided and the drop axis of the slag and the drop axis of the dust are displaced from each other, dust is mixed in the slag. Therefore, it is possible to prevent the dust adhering to and accumulating in the secondary combustion chamber from being mixed into the slag.

Next, another example of the waste melting furnace according to the present invention will be described with reference to FIGS. 2 and 3.

2 and 3, the same components as those in FIG. 1 are designated by the same reference numerals and the description thereof will be omitted. A gas suction unit 25 is attached to the outlet 21 a of the melting furnace 21. Specifically, the gas suction portion 25 is attached so as to close a part (upper side) of the outlet 21a,
The gas suction unit 25 has, for example, a fan (not shown).
Is attached. Further, the secondary combustion chamber 22a has a cyclone structure, and the exhaust gas sucked by the gas suction portion 25 is discharged to the secondary combustion tower 22 using the gas suction portion 25 as a gas outlet, which is indicated by a solid arrow in FIG. Thus, it rises while swirling in the secondary combustion chamber 22a. By swirling (cyclone motion) the exhaust gas in this way, the dust in the exhaust gas is forcibly separated,
As shown in FIG. 2, the adherence near the inlet of the secondary combustion chamber 22a
accumulate.

As described with reference to FIG. 1, in the illustrated example as well, the slag discharge duct 22b has the outlet 21a of the melting furnace 21.
The dust discharge duct 22c is disposed in the vicinity and the melting furnace 21
Since it is positioned away from the outlet 21a of the slag, that is, the drop axis of the slag and the drop axis of the dust are arranged so as to be displaced, dust is not mixed in the slag.
It is possible to prevent the dust adhering to and depositing on the inner surface of the secondary combustion chamber from mixing with the slag.

Moreover, in the example shown in FIGS. 2 and 3, since the exhaust gas is raised while swirling (cyclone motion) in the secondary combustion chamber 22a, the dust in the exhaust gas is forcibly separated, and as a result, The proportion of dust in the exhaust gas reaching the waste heat recovery equipment, exhaust gas cooling equipment, etc. can be extremely reduced.

[0024]

As described above, in the present invention, the slag discharge duct is arranged near the outlet of the melting furnace, and the dust discharge duct is arranged away from the outlet of the melting furnace, that is, the slag drops. Since the shaft and the drop axis of the dust are arranged so as to be offset from each other, the dust does not mix into the slag, and it is possible to prevent the dust deposited and deposited near the inlet of the secondary combustion chamber from mixing into the slag. This has the effect of expanding the range of slag reuse.

[Brief description of drawings]

FIG. 1 is a diagram showing an example of a waste melting furnace according to the present invention.

FIG. 2 is a diagram showing another example of the waste melting furnace according to the present invention.

FIG. 3 is a view of FIG. 2 seen from above.

FIG. 4 is a diagram showing a conventional waste melting furnace.

[Explanation of symbols]

21 melting furnace 22 Secondary combustion tower 22a Secondary combustion chamber 22b Slag discharge duct 22c dust discharge duct 23 Slag cooling water tank 24 Dust cooling water tank 25 Gas suction part

─────────────────────────────────────────────────── ─── Continuation of the front page (56) Reference JP-A-9-145032 (JP, A) JP-A-11-19618 (JP, A) JP-A-2-178508 (JP, A) JP-A-8- 285245 (JP, A) JP-A-8-5038 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) F23G 5/00-5/28 F23G 5/44-5/48 F23G 7/00 F23G 7/00-7/12 F27B 5/00-7/42 F27B 9/00-9/40

Claims (2)

(57) [Claims] 1. A melting furnace that melt-processes waste to discharge dust-containing exhaust gas and slag from the same outlet, and a secondary combustion chamber that is connected to the outlet to perform secondary combustion of the exhaust gas , The outlet of the melting furnace is of the secondary combustion chamber.
In the waste melting furnace which is open at the bottom, falling slag falling from the outlet disposed on the exit of the slag discharge duct for discharging to the outside, is disposed away from the outlet from the inner wall of the secondary combustion chamber And a dust discharge duct for discharging the generated dust to the outside. 2. The waste melting furnace according to claim 1, wherein a gas discharging means for discharging the exhaust gas into the secondary combustion chamber and causing a swirling motion in the secondary combustion chamber is provided at an outlet of the melting furnace. A waste melting furnace characterized by being provided.