JPH0970518A - Flue gas treating device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a compact flue gas treating device. SOLUTION: In the flue gas treating device for exhausting a desulfrized waste gas from an absorption tower 7 to a stack, etc., with a fan installed on the ground, a lowering duct 16 introducing the waste gas discharged from an upper part of the absorption tower main body 8 to the fan 35 installed on the ground is formed, and a gas heater 15 for rehashing which rehears the deslufurized waste gas discharged from the adsorption tower 7 by using a sensible heat recovered from the waste gas at an upper stream side of the absorption tower 7 is provided inside the lowering duct 16.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flue gas treatment device, and more particularly to a flue gas treatment device with an improved exhaust gas passage downstream of an absorption tower.

[0002]

2. Description of the Related Art A boiler in a power generation facility or the like is provided with a flue gas treatment facility for treating exhaust gas generated from the boiler. In general, this type of flue gas treatment equipment is adopted as shown in FIG. As shown in FIG. 5, the flue gas treatment facility includes a boiler 20, a denitration device 21, and an AH (air heater).
22), EP (electrostatic precipitator) 23, IDF (induction fan) 24, heat recovery gas gas heater 1, absorption tower 7, BU
The F (fan) 25, the reheating gas gas heater 15, and the chimney 19 are sequentially connected by a duct.

The flue gas treatment facility constructed as described above treats the exhaust gas through the following treatment processes.

As shown in the figure, the exhaust gas after combustion from the boiler 20 is forcibly discharged by the induction fan 24, guided to the denitration device 21, and subjected to denitration processing. Since the exhaust gas after denitration has a considerably high temperature, in order to recover the heat from this, the air heater 22 exchanges heat between the high-temperature exhaust gas and the combustion air at room temperature, and the combustion air becomes hot due to the heat exchange. Will be supplied to the boiler 20. The heat-exhausted exhaust gas is then guided to the electrostatic precipitator 23 for dust removal processing. The exhaust gas after dust removal is introduced into the absorption tower 7 and desulfurized.

In the absorption tower 7 which is a desulfurization device, the exhaust gas and the absorbing liquid are brought into contact with each other in a gas-liquid countercurrent manner to absorb and remove SO _{X in} the exhaust gas. Here, the exhaust gas after desulfurization becomes a low temperature gas saturated with water. Therefore, when exhaust gas is discharged from the chimney 19, the sensible heat recovered by the heat recovery gas gas heater 1 at the preceding stage is supplied to the reheating gas gas heater 15 to reheat the desulfurized exhaust gas. I am trying.

As shown in FIG. 4 which is a side view of an absorption tower, a fan and a reheating gas gas heater in a conventional flue gas treatment facility, the absorption tower 7 used for power generation equipment has a large ground height of about 30 meters. The exhaust duct 13 for discharging the exhaust gas after desulfurization is formed at the top of the absorption tower 7. On the other hand, the reheating gas gas heater 1 on the downstream side of the exhaust gas from the exhaust duct 13 of the absorption tower 7
5, the fan 25 for boosting and pumping the exhaust gas to the chimney and the like is a heavy object, so the fan 25 will be installed on the ground. The exhaust duct 13 and the fan 25 installed on the ground are connected by a descending duct 26 having a predetermined length, and the reheating gas gas heater 15 is provided downstream of the fan 25 via an exhaust gas duct 27. It is provided. Further, the reheating gas gas heater 15 is connected to the duct 28.
It is connected to the chimney via the so as to exhaust the exhaust gas.

[0007]

However, the absorption tower 7 and the reheating gas gas heater shown in FIGS. 4 and 5 are used.
As described above, the turret 15 is a device having a relatively large height of about 30 meters and a weight of several hundred tons. Here, the fan 25 is relatively small in size as compared with the absorption tower 7 and the reheating gas gas heater 15, but since it is a heavy object and vibrates with the motor 36,
Usually installed on the ground. Therefore, the absorption tower 7 and the fan 2
The descending duct 26 is required to connect 5 and the descending duct 26 inevitably has a long length.

Reference numeral 36 is a motor for driving the fans 25 and 35.

The reheating gas gas heater 15 and the heat recovery gas gas heater 1 are provided so as to sandwich the absorption tower 7. That is, the heat recovery gas gas heater 1 is provided on the exhaust gas introduction side or upstream side of the absorption tower 7, and the reheating gas gas heater 15 is provided on the exhaust gas discharge side or downstream side of the absorption tower 7.

The heat recovery gas gas heater 1 recovers sensible heat from the exhaust gas before being introduced into the absorption tower 7, and the reheating gas gas heater 15 recovers the exhaust gas discharged from the absorption tower 7 by the recovered sensible heat. The temperature is raised, and the heat recovery gas gas heater 1 and the reheating gas gas heater 15 are connected to each other by a heat medium circulation pipe 5. For this reason, the heat recovery gas gas heater 1 and the reheating gas gas heater 15 are installed so as to be separated from each other across the absorption tower 7, and the pipe length of the heat medium circulation pipe 5 connecting them is long. .

That is, the conventional flue gas treatment apparatus tends to be large in size as a whole. Especially, since the flue gas treatment equipment is large and complicated, it is necessary to make the equipment compact in consideration of the equipment cost.

Therefore, an object of the present invention is to provide a compact flue gas treatment device.

[0013]

In order to achieve the above object, the present invention provides a smoke treatment apparatus for discharging desulfurized exhaust gas from an absorption tower to a chimney or the like by a fan installed on the ground. A descending duct for guiding the exhaust gas discharged from the upper part to a fan installed on the ground is provided, and desulfurization discharged from the absorption tower by using sensible heat recovered from the exhaust gas on the upstream side of the absorption tower in the descending duct. A reheating gas gas heater for reheating the exhaust gas is provided.

According to the above construction, by incorporating the reheating gas gas heater in the descending duct connecting the absorption tower and the fan, the installation space of the descending duct having almost the same height as the absorbing tower is effectively used. It is possible to provide a reheating gas gas heater, shorten the distance between the reheating gas gas heater and the heat recovery gas gas heater provided on the upstream side of the absorption tower, and connect the heat medium circulation pipe Can be shortened. That is, the equipment installation area can be greatly reduced, and the apparatus can be made compact.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described below in detail with reference to the accompanying drawings. Note that common members are used for members similar to those of the above-described conventional example.

As shown in FIG. 1, an absorption tower 7 for desulfurizing exhaust gas is installed upright on the ground. The absorption tower 7 is partitioned by an outer shell housing 8 and is internally provided with a plurality of spray header tubes 9 for ejecting an absorption liquid 12 as shown in FIG.
2a is formed. Each spray header tube 9
Are concentrated on the absorption liquid circulation pipe 9a. The absorption liquid circulation pipe 9a is provided so as to face the absorption liquid reservoir 12a and an absorption liquid circulation pump 11 for forcibly circulating the absorption liquid 12 is provided. . A spray nozzle 10 for spraying the absorbing liquid 12 is attached to each of the spray header tubes 9.

Further, the spray header pipe 9 and the absorbing liquid reservoir 1
An exhaust gas introduction duct 6 for introducing the exhaust gas G ₂ is connected to a side portion of the outer shell housing 8 located between the exhaust gas G ₂ and _{2 a,} and the exhaust gas introduction duct 6 is located on the upstream side of the exhaust gas G _2. A gas gas heater 1 for heat recovery is provided in order to do so.

Further, an exhaust port 13a for discharging the desulfurized exhaust gas G ₃ formed at the top of the absorption tower 7
An exhaust duct 13 is connected to the exhaust pipe 13, and a descending duct 16 for connecting these is connected between the exhaust duct 13 and the suction port portion 35a of the fan 35 installed on the ground.

Particularly, the present invention is characterized in that the reheating gas gas heater 15 is provided in the descending duct 16 connecting the absorption tower 7 and the suction port portion 35a of the fan 35 installed on the ground. is there.

More specifically, as shown in FIG. 1, the absorption tower 7
A fan 35 for pumping the desulfurized exhaust gas discharged from the exhaust duct 13 to the downstream side such as a chimney is provided on the ground below the top of the absorption tower 7.

On the other hand, the exhaust duct 13 is connected to the exhaust port 13a formed at the top of the absorption tower 7, and the descending duct 16 connected to the intake port 35a of the fan 35 is connected to the exhaust duct 13. The reheating gas gas heater 15 is formed in the descending duct 16. The reheating gas gas heater 15 has a cross-sectional area of the descending duct 16 enlarged as shown in the drawing, and the reheating heat transfer tube 17 for circulating the heat medium shown in FIG. is there. This reheating heat transfer tube 17 is a heat recovery gas gas heater 1 provided on the upstream side of the absorption tower 7.
The heat recovery heat transfer tube 3 incorporated therein is connected to each other via a heat medium circulation pipe 5. The heat medium circulation pipe 5 is provided with a heat medium circulation pump 4 for forcibly circulating the heat medium.

As described above, according to this embodiment, the exhaust gas G _{1 which} has been dust-removed by the electrostatic precipitator passes through the heat recovery gas gas heater _{1 and} is introduced into the absorption tower 7 through the exhaust gas introduction duct 6. To be done. The sensible heat of the exhaust gas G ₂ introduced into the absorption tower 7 is recovered by the heat recovery gas gas heater 1 and becomes the exhaust gas G ₂ set to a predetermined temperature, and then the absorption liquid 12 sprayed from the spray header pipe 9 The gas-liquid countercurrent is contacted, desulfurization is performed, and the gas is discharged from the exhaust duct 13. As shown in FIG. 2, the exhaust gas G ₃ discharged from the exhaust duct 13 has its liquid component removed by the mist eliminator 14 and becomes exhaust gas G ₄ which flows into the descending duct 16.

Since the reheating gas gas heater 15 is provided in the descending duct 16, the exhaust gas G ₄ from which the liquid component has been removed by the mist eliminator 14 by the reheating gas gas heater 16 is heated and heated. After reaching G ₅ , it is sucked by the fan 35 and exhausted to the downstream side of the chimney 19 and the like.

Particularly, by providing the reheating gas gas heater 15 in the descending duct 16 connecting the fan 35 and the absorption tower 7 installed on the ground, the reheating gas gas heater 15 is provided in the area occupied by the descending duct 16. Since it is attached, the space can be effectively used and the size of the entire apparatus can be reduced.

Further, it becomes possible to install the heat recovery gas gas heater 1 and the reheating gas gas heater 15 close to each other by sandwiching the absorption tower 7, and the heat recovery gas gas heater 1 and the reheating gas gas heater can be installed. It is possible to shorten the heat medium circulation pipe 5 that connects with 15, and to reduce heat insulating materials and the like. That is, the downsizing of the equipment can be achieved and the heat exchange efficiency of the gas heater is improved.

Next, a modification of the present invention will be shown.

As shown in FIG. 3, when the absorption tower 7 is installed relatively higher than the ground, the fan 35 is installed on the ground near the lower part of the absorption tower 7 and installed on the top of the absorption tower 7. The exhaust duct 13 and the suction port portion 35a of the fan 35 are connected to the descending duct 16 with the vertical or inclination angle set small, and the reheating gas gas heater 15 is provided in the middle of the descending duct 16. . Therefore, the reheating gas gas heater 15 is elevated above the fan 35, the area occupied by the reheating gas gas heater 15 is further reduced, and the equipment installation area can be significantly reduced. . By providing the reheating gas gas heater 15 close to the absorption tower 7 in this manner, the frame supporting the reheating gas gas heater 15 can be shared with the frame supporting the absorption tower 7, and the size of the equipment can be reduced. Can be achieved. Needless to say, this modification also exhibits the same effect as the present invention.

[0028]

As described above, the flue gas treatment apparatus according to the present invention has an excellent effect that the pipe length of the piping equipment such as ducts and pipes is shortened, the equipment installation area is reduced, and the apparatus is compact. Exert.

[Brief description of drawings]

FIG. 1 is a perspective view showing a smoke exhaust processing apparatus according to the present invention.

FIG. 2 is a flow sheet showing a smoke exhaust processing apparatus according to the present invention.

FIG. 3 is a side view showing a modified example of the smoke exhaust processing apparatus in the present invention.

FIG. 4 is a side view showing a conventional flue gas treatment device.

FIG. 5 is a schematic system diagram showing a conventional flue gas treatment facility.

[Explanation of symbols]

7 the absorption tower 8 outer shell housing 15 reheating Gasugasuhi - motor 16 downward duct 19 chimney 35 fan G ₁ ~G ₆ gas

Claims (1)

[Claims] 1. In a flue gas treatment device for exhausting desulfurized exhaust gas from an absorption tower to a chimney or the like by a fan installed on the ground, the exhaust gas discharged from the upper part of the absorption tower main body is guided to a fan installed on the ground. And a reheating gas gas heater for reheating the desulfurized exhaust gas discharged from the absorption tower by using sensible heat recovered from the exhaust gas on the upstream side of the absorption tower. A characteristic smoke exhaust treatment device.