JP2003225533A - Exhaust gas treating system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an exhaust gas treating system at a low running cost. <P>SOLUTION: Since a cooling medium discharged from a heat exchanger 67 for cooling a carbon based adsorbing material of an elimination tower 60 and heated by heat exchange accompanying with cooling of the carbon based adsorbing material is used as a heat source of an ammonia vaporizer 98 for vaporizing liquid ammonia from a liquid ammonia feeding device 93, a utility vapor or the like for vaporization is not required. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to an exhaust gas treatment system for desulfurizing exhaust gas.

[0002]

2. Description of the Related Art Conventionally, in an adsorption tower, a downward moving bed of a carbonaceous adsorbent such as activated carbon is formed, and an exhaust gas containing ammonia gas is contacted with the moving bed to remove SO _x in the exhaust gas. Sulfuric acid, ammonium sulfate, etc. were adsorbed to and removed from the carbonaceous adsorbent, and in the desorption tower, the carbonaceous adsorbent that adsorbed the sulfur content was heated to desorb and reactivate the sulfur content. An exhaust gas treatment system is known in which a carbonaceous adsorbent is cooled with a cooling medium and returned to an adsorption tower. Such an exhaust gas treatment system usually includes an ammonia vaporizer that heats and vaporizes liquid ammonia in order to obtain ammonia gas to be added to the exhaust gas.

[0003]

However, the ammonia vaporizer of the conventional exhaust gas treatment system consumes utility steam or the like as a heat source, and its running cost is high.

The present invention has been made in view of the above problems, and an object of the present invention is to provide an exhaust gas treatment system having a low running cost that does not require utility steam for ammonia vaporization.

[0005]

The exhaust gas treatment system according to the present invention comprises an adsorption tower for adsorbing the sulfur content in the exhaust gas to the carbonaceous adsorbent by passing the supplied exhaust gas through the carbonaceous adsorbent, and a sulfur content. A desorption tower that heats the adsorbed carbonaceous adsorbent to desorb sulfur and cools the heated carbonaceous adsorbent with a cooling medium, and adds ammonia gas to the exhaust gas supplied to the carbonaceous adsorbent. And an ammonia vaporizer for vaporizing liquid ammonia by a cooling medium heated as the carbonaceous adsorbent in the desorption tower is cooled to obtain ammonia gas.

According to the exhaust gas treatment system of the present invention, the vaporization of the liquid ammonia is carried out by utilizing the heat of the cooling medium heated in the desorption tower, so that the utility steam for the liquid is unnecessary. .

Here, it is preferable that the ammonia vaporizer has a tank for storing a predetermined amount of the heated cooling medium, and the liquid ammonia is vaporized by the cooling medium stored in the tank.

As a result, even if the temperature of the heated cooling medium from the desorption tower fluctuates, a predetermined amount of the cooling medium is stored in the tank and the temperature of the cooling medium does not fluctuate easily. It is easy to control the vaporization amount of gas.

[0009]

DETAILED DESCRIPTION OF THE INVENTION Referring to the accompanying drawings,
A preferred embodiment of the exhaust gas treatment system according to the present invention will be described in detail. FIG. 1 is a schematic configuration diagram showing an exhaust gas treatment system 100 according to this embodiment.

The exhaust gas treatment system 100 of this embodiment
In the adsorption tower 11, a carbonaceous adsorbent such as activated carbon is introduced from the upper part through the rotary valve 12 and discharged from the lower part through the rotary valve 13 to form a downward moving layer of the carbonaceous adsorbent, Exhaust gas containing sulfur such as SO _x is horizontally supplied to the moving bed through the step-up blower 20 and the line L8, and ammonia gas is added to the exhaust gas by an ammonia gas adding device 90 (described later in detail). The sulfur content in the exhaust gas is added and adsorbed to the carbonaceous adsorbent in the form of sulfuric acid or ammonium sulfate to be removed, and the desulfurized exhaust gas is discharged from the chimney 40.

Further, the exhaust gas treatment system 100 is
Bucket conveyor 2 for carbonaceous adsorbent that adsorbs sulfur
2. Introduced from the upper part of the desorption tower 60 via the rotary valve 62, and discharged from the bottom part via the rotary valve 63 to form a downward moving layer, and the heating gas generated in the hot stove 65 is removed by the blower 66. The carbonaceous adsorbent is supplied to the multi-tube heat exchanger 61 in the central part of the separation tower 60 to heat the carbonaceous adsorbent to desorb the adsorbed sulfur component and to reactivate the carbonaceous adsorbent. Cooling water (cooling medium) is supplied to the lower tubular heat exchanger 67 to cool the desorbed / reactivated carbonaceous adsorbent, and the carbonaceous adsorbent is removed by a sieving machine 64 and a bucket. The adsorption tower 1 again via the conveyor 23
While returning to the upper part of 1, the by-product recovery device 70 recovers sulfuric acid, sulfur, etc. from the desorbed sulfur content.

A water tank 30 for introducing and storing the heated cooling water after cooling the carbonaceous adsorbent through a line L7 is installed on the downstream side of the cooling water of the multitubular heat exchanger 67.
On the downstream side of the water tank 30, a cold water tower 31 for introducing and cooling the cooling water of the water tank 30 via a line L5 equipped with a pump 32 is installed. A multi-tube heat exchanger 67 is connected to the downstream side of the cold water tower 31 via a line L6, and the cooling water cooled in the cold water tower 31 is transferred to the multi-tube heat exchanger 6
It is configured so that it can be introduced in 7.

Here, the exhaust gas treatment system 100 of this embodiment comprises an ammonia vaporizer 98 for vaporizing liquid ammonia supplied from the liquid ammonia supply device 93 into ammonia gas, and an exhaust gas flowing through the line L8. Ammonia gas addition device 90 added to
And are equipped with.

The ammonia vaporizer 98 has a hot water bath (tub) 91 having a predetermined capacity. A line L2 branched from a line L7 is connected to the hot tub 91, and the hot tub 91 is a part of heated cooling water returned from the multitubular heat exchanger 67 to the water tank 30 via the line L7. Is introduced through this line L2 and a predetermined capacity is stored. A line L3, which joins the line L7 on the downstream side of the branch point of the line L2, is connected to the hot water bath 91 to return the cooling water overflowing from the hot water bath 91 to the water tank 30.

The ammonia vaporizer 98 is used in the hot water bath 9
A coil-shaped vaporization tube 92 that is immersed in the cooling water in the inside 1 is provided. This vaporization tube 92 is provided with a liquid ammonia supply device 93.
Is connected by a line L4, and liquid ammonia introduced through the line L4 is vaporized by the heat of the heated cooling water stored in the hot water bath 91 into ammonia gas.

A valve 94 for adjusting the flow rate of the cooling water supplied to the hot water bath 91 is installed in the line L2, and the hot water bath 91 has a thermoelectric device for measuring the temperature of the heated cooling water in the hot water bath 91. Pair 95 is installed. These valves 9
4 and the thermocouple 95 are connected to a temperature control device 96, and this temperature control device 96 is based on the temperature of the cooling water in the hot water bath 91 measured by the thermocouple 95.
The opening of the valve 94 is adjusted so that the internal temperature becomes a desired value. The desired temperature is, for example, the adsorption tower 11
The temperature is set to correspond to the amount of vaporization of ammonia gas required for the exhaust gas supplied to the.

The ammonia gas addition device 90 includes a vaporization tube 9
2 is provided with a line L1 connecting the line L8, and the ammonia gas from the vaporization pipe 92 is added to the exhaust gas of the line L8.

Next, the operation of the exhaust gas treatment system 100 according to this embodiment will be described.

In this system, in the adsorption tower 11,
The exhaust gas is supplied to the moving bed of the carbonaceous adsorbent that moves from the upper portion to the lower portion, and the ammonia gas addition device 90
Ammonia gas is added to the exhaust gas by the action (described later).

As a result, the exhaust gas comes into contact with the moving bed of the carbonaceous adsorbent, and the sulfur content such as SO _{x in} the exhaust gas reacts with the water in the exhaust gas to form sulfuric acid, and the sulfuric acid and ammonia. Are adsorbed on the carbonaceous adsorbent in the form of ammonium sulfate or the like produced by the reaction. Note that in the moving bed of the carbonaceous adsorbent, if it contains NO _x in the exhaust gas, NO _x is reduced to N ₂ by reaction with ammonia by the catalytic action of the carbonaceous adsorbent, the exhaust gas When dioxin is contained in the dioxin, dioxin is adsorbed and dust in the exhaust gas is removed.

On the other hand, the carbonaceous adsorbent that has adsorbed sulfur is
It is introduced into the desorption tower 60 from the upper part and discharged from the bottom part by a predetermined amount, and a moving bed is formed in the desorption tower 60. At this time, the heating gas is introduced into the shell-and-tube heat exchanger 61 in the central portion of the desorption tower 60, so that the carbonaceous adsorbent is heated to 400 °.
When heated to about C, the sulfur content adsorbed on the carbon adsorbent is desorbed as SO _{x and the} like, and the carbonaceous adsorbent is reactivated, and this carbonaceous adsorbent is moved to the lower part of the desorption tower 60. On the other hand, the desorbed sulfur content is recovered by the byproduct recovery device 70 as sulfuric acid or elemental sulfur.

Here, the cooling water in the water tank 30 is pumped by the pump 32.
Is sent to the cold water tower 31 to be cooled, and the cooled cooling water is introduced into the multi-tube heat exchanger 67 below the desorption tower 60. As a result, the desorbed and reactivated carbonaceous adsorbent that has reached the bottom of the desorption tower 60 is cooled to about 90 ° C,
The cooled carbonaceous adsorbent is reused and returned to the upper part of the adsorption tower 11 through the sieving machine 64, while the heat accompanying cooling of the carbonaceous adsorbent in the multitubular heat exchanger 67 is generated. The cooling water heated to about 75 ° C. by the exchange is returned to the water tank 30 via the line L7 and is circulated again.

At this time, a part of the cooling water heated by the heat exchange accompanying the cooling of the carbonaceous adsorbent in the multitubular heat exchanger 67 is passed through the lines L7 and L2 to the ammonia vaporizer 98.
Is transferred to the hot water bath 91 and is stored in the hot water bath 91 in a predetermined amount. Here, the amount of heated cooling water flowing into the hot water bath 91 via the line L2 is controlled by adjusting the opening degree of the valve 94 by the temperature control device 96, and the heated cooling water stored in the hot water bath 91 is controlled. The temperature of the water is set to a temperature corresponding to the desired vaporization amount of ammonia. Then, the liquid ammonia supplied by the liquid ammonia supply device 93 is vaporized in the vaporizing pipe 92 immersed in the hot water bath 91, and the vaporized ammonia gas is passed through the line L1 of the ammonia gas adding device 90. Line L
It is added to the exhaust gas flowing through 8 and desulfurized in the adsorption tower 11 described above.

That is, in the present embodiment, a part of the exhaust heat, which has been conventionally dissipated by the cold water tower 31 or the like and wasted, is used as a heat source for vaporizing liquid ammonia, and utility vapor for vaporization is not required. Therefore, the running cost of the exhaust gas treatment system 100 is reduced.

Further, the ammonia vaporizer 98 is composed of the vaporization tube 9
2 is provided with a hot water bath 91 capable of storing a predetermined amount of cooling water, and the hot water bath 9 can be used even when the temperature of the heated cooling water introduced from the multi-tube heat exchanger 67 fluctuates.
Rapid changes in the temperature of the cooling water in 1 are suppressed. Therefore, it is easy for the temperature controller 96 to maintain the vaporization amount of ammonia gas at a predetermined value.

Then, the cooling water cooled by the vaporization of the liquid ammonia in the hot water bath 91 overflows and is returned to the water tank 30 through the line L3. As a result, part of the cooling water from the desorption tower 60 is further cooled in the ammonia vaporizer 98, so the cooling load on the cold water tower 31 is also reduced.

The exhaust gas treatment system according to the present invention is not limited to the above embodiment and can take various modifications. For example, in the above-described embodiment, the moving bed of the carbonaceous adsorbent is formed in the adsorption tower 11 or the like, but the present invention is not limited to this, and the moving bed is formed as a fixed bed or the carbonaceous adsorbent is moved intermittently. May be formed.

In the above embodiment, the carbonaceous adsorbent cooled in the desorption tower 60 is returned to the adsorption tower 11 for reuse, but it may be transferred to another process.

Further, the present system can treat various exhaust gases such as sintering exhaust gas, boiler exhaust gas, waste incinerator exhaust gas, RDF exhaust gas and the like.

[0030]

As described above, since the exhaust gas treatment system of the present invention vaporizes liquid ammonia by using the cooling medium heated by the heat exchange accompanying the cooling of the carbonaceous adsorbent in the desorption tower, Eliminates the need for utility steam for vaporization. This provides an exhaust gas treatment system with low running costs.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram showing an exhaust gas treatment system according to the present embodiment.

[Explanation of symbols]

11 ... Adsorption tower, 60 ... Desorption tower, 90 ... Ammonia gas addition device, 91 ... Hot water bath (tank), 98 ... Ammonia vaporizer, 100 ... Exhaust gas treatment system.

Claims (2)

[Claims] 1. An adsorption tower for adsorbing the sulfur content in the exhaust gas to the carbonaceous adsorbent by passing the supplied exhaust gas through the carbonaceous adsorbent, and heating the carbonaceous adsorbent adsorbing the sulfur content. A desorption tower that desorbs sulfur content and cools the heated carbonaceous adsorbent with a cooling medium; an ammonia gas addition device that adds ammonia gas to the exhaust gas supplied to the carbonaceous adsorbent; An exhaust gas treatment system, comprising: an ammonia vaporizer that obtains the ammonia gas by vaporizing liquid ammonia with a cooling medium that is heated as the carbonaceous adsorbent is cooled in the desorption tower. 2. The ammonia vaporizer is provided with a tank for storing a predetermined amount of the heated cooling medium, and the liquid ammonia is vaporized by the cooling medium stored in the tank. The exhaust gas treatment system described in.