JPH06205937A - Flue gas decarboxylation device - Google Patents

Abstract

PURPOSE:To absorb and remove CO2 from waste combustion gas and to convert the absorbed and removed CO2 into a CO2 clathrate which is morphologically stable and easy to handle when treating it. CONSTITUTION:This device is provided with an absorber 1 in which CO2 in waste combustion gas is absorbed under desired pressure by an absorbent consisting of a refrigerant which does not solidify even at <=0 deg.C and water to form liquid consisting of CO2 and the absorbent, and the waste combustion gas from which CO2 has been removed is discharged to the outside, a CO2 clathrate forming device 2 in which the liquid consisting of the CO2 formed in the absorber 1 and the absorbent is cooled and agitated to form a CO2 clathrate, and a separator 3 in which the CO2 clathrate formed in the CO2 clathrate forming device 1 and the absorbent contg. CO2 which has not been used for forming the clathrate and remains are separated and the CO2 clathrate separated from the absorbent contg. CO2 which has not been used for the formation of the clathrate and remains is extracted and the absorbent contg. CO2 which has not been used for the formation of the clathrate and remains is returned to the absorber 1.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flue gas decarbonator.

[0002]

2. Description of the Related Art In recent years, a trace amount of gas in the atmosphere (for example, methane gas, carbon dioxide gas, nitrous oxide gas, etc.) absorbs infrared rays emitted from the surface of the earth, and the temperature to return the heat escaping to outer space to the surface of the earth. It has been pointed out that there is a possibility that the climate will warm up due to the greenhouse effect of rising energy prices. In particular, recently, carbon dioxide (CO ₂ ) has tended to increase, and the combustion exhaust gas from boilers and the like contains a large amount of this carbon dioxide, so countermeasures are urgently needed.

[0003]

However, regarding the treatment of CO ₂ contained in the combustion exhaust gas of the above-mentioned boiler or the like, effective measures have not yet been put into practical use.

In view of the above situation, the present invention is capable of absorbing and removing CO ₂ from combustion exhaust gas, converting the absorbed and removed CO ₂ into a morphologically stable and easily handleable CO ₂ clathrate, and treating it. It is intended to provide an obtained flue gas decarbonator.

[0005]

According to the present invention, CO ₂ contained in combustion exhaust gas is absorbed under a desired pressure by an absorbent composed of a refrigerant and water which do not solidify even at 0 ° C. or less, and CO ₂ and the absorbent are absorbed. CO ₂ is removed and the combustion exhaust gas from which CO ₂ has been removed is discharged to the outside, and the CO ₂ produced in the absorption tower and the liquid containing the absorbent are cooled and stirred to produce CO ₂
A CO ₂ clathrate generator for generating clathrates,
Separating the absorbent containing the CO ₂ clathrate generator CO ₂ clathrate clathrate of is not in the remaining CO ₂ produced by, CO ₂ that remains without being the clathrate of
A flue gas decarboxylation device characterized in that a separator for returning the absorbent containing the above to the absorption tower is provided.

[0006] Further, in the flue decarbonation apparatus, a part of CO ₂ clathrate extracted from the separator may be configured to return to the CO ₂ clathrate generator.

Furthermore, in the above-mentioned flue gas decarbonator, C
O ₂ clathrate mixed fine spheroids in CO ₂ clathrate fed from generator to the separator, to separate the CO ₂ clathrate and spherical bodies extracted from the separator, the spherical body An auxiliary separator may be provided for extracting the separated CO ₂ clathrate and returning the spheres to the CO ₂ clathrate generator.

[0008]

The combustion exhaust gas comes into contact with the absorbent under a desired pressure in the absorption tower, CO ₂ is absorbed and removed by the absorbent, and then discharged from the upper part of the absorption tower to the outside. At a desired pressure, when CO ₂ is absorbed and removed from the combustion exhaust gas by the absorbent, a liquid composed of CO ₂ and the absorbent is generated, and the liquid is supplied from the absorption tower to the CO ₂ clathrate generator, In the CO ₂ clathrate generator, the liquid is cooled and agitated to remove the CO ₂ contained in the liquid.
And water _{(CO 2 + 7H 2 O →} CO 2 · 7H 2 O) and comprising reacting undergo CO ₂ clathrate is generated and CO ₂ clathrate clathrate of generated in CO ₂ clathrate generator The absorbent containing CO ₂ left without
The CO ₂ clathrate is supplied to a separator, where the CO ₂ clathrate and the absorbent containing CO ₂ which has remained without being clathrated are separated, and the CO ₂ which has not been clathrated and remains
The absorbent containing is returned to the absorption tower.

The same operation is repeated thereafter, the CO ₂ absorbed and removed from the combustion exhaust gas is completely converted to a clathrate, and the CO ₂ clathrate extracted from the separator is appropriately dumped into the ocean or the like. .

[0010] Further, in the flue decarbonation apparatus, when to return a portion of the CO ₂ clathrate extracted from the separator to the CO ₂ clathrate generator, returned to the CO ₂ clathrate generator CO ₂ clathrate, CO ₂ is to become the seed at the time of clathrate of, CO ₂ clathrate generator 2 clathrate of CO ₂ in is accelerated further.

Furthermore, in the above-mentioned flue gas decarbonator, C
When fine spheres are mixed in the CO ₂ clathrate fed from the O ₂ clathrate generator to the separator and an auxiliary separator is provided, the CO ₂ clathrate adheres in the separator by the spheres. And the spherical bodies separated from the CO ₂ clathrate by the auxiliary separator are CO ₂
Since returned to clathrate generator CO ₂ is seed at the time of clathrates of clathrate of CO ₂ in the CO ₂ clathrate generator is also promoted.

[0012]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows an embodiment of the present invention, in which 1 is an absorbent composed of a refrigerant (for example, ethylene glycol) and water which does not solidify at 0 ° C. or lower under a desired pressure (about 20 kgf / cm ² ). The absorption tower 2 which is sprayed from the spray nozzle 4 and absorbs CO ₂ contained in the combustion exhaust gas to generate a liquid composed of CO ₂ and an absorbent and discharges the combustion exhaust gas from which CO ₂ is removed to the outside. C produced in tower 1
O ₂ and CO ₂ clathrate generator and stirred to produce a CO ₂ clathrate liquid consisting of absorbent by cooling pipes 5 by 0 ℃ agitator 6 and is cooled to below 3 in CO ₂ clathrate generator 2 the generated CO ₂ clathrate clathrate of are absorbent containing the remaining CO ₂ without separating returns the absorbent containing CO ₂ that remains without being the clathrate of the said absorption tower 1 Hydro It is a separator such as a cyclone.

Next, the operation of the above embodiment will be described.

The combustion exhaust gas sent from the boiler or the like is
Under the desired pressure in the absorption tower 1, the spray nozzle 4
Contact with the absorbent sprayed from the
_{After 2} is absorbed and removed, it is discharged from the upper part of the absorption tower 1 to the outside, and is discharged into the atmosphere from a chimney or the like.

On the other hand, when CO ₂ is absorbed and removed from the combustion exhaust gas by the absorbent sprayed from the spray nozzle 4 under a desired pressure in the absorption tower 1, a liquid composed of CO ₂ and the absorbent is produced, The liquid is supplied from the absorption tower 1 to the CO ₂ clathrate generator 2.

CO₂In the clathrate generator 2, the liquid
Is cooled to below 0 ° C. by a cooling pipe 5 and a stirrer 6
CO contained in the liquid after being stirred by₂And water (CO₂+
7H ₂O → CO₂・ 7H₂O) to react with CO₂
A clathrate is generated.

The absorbent containing the remaining CO ₂ without being CO ₂ clathrate clathrate of generated in CO ₂ clathrate generator 2 is supplied to the separator 3, in the separator 3, CO ₂ clathrate clathrate of are absorbent containing the remaining CO ₂ without and are separated, together with the CO ₂ clathrate separation of the absorbent containing the CO ₂ that remains without being the clathrate of is extracted, The CO ₂ -containing absorbent remaining without being clathrated is returned to the absorption tower 1.

The same operation is repeated thereafter, the CO ₂ absorbed and removed from the combustion exhaust gas is completely converted to a clathrate, and the CO ₂ clathrate extracted from the separator 3 is appropriately dumped into the ocean or the like. It

In this manner, CO ₂ can be absorbed and removed from the combustion exhaust gas, and the CO ₂ that has been absorbed and removed can be converted into a CO ₂ clathrate that is morphologically stable and can be easily handled, and processed.

FIG. 2 shows another embodiment of the present invention. In the figure, the parts denoted by the same reference numerals as those in FIG. 1 represent the same things, and the basic construction is the same as that shown in FIG. In Although,
It is a feature of this embodiment, as shown in FIG. 2, there a part of CO ₂ clathrate extracted from the separator 3 to a point configured to return to the CO ₂ clathrate generator 2.

In the case of the embodiment shown in FIG. 2, the combustion exhaust gas sent from the boiler or the like comes into contact with the absorbent sprayed from the spray nozzle 4 under a desired pressure in the absorption tower 1, and the absorbent is sprayed. After the CO ₂ is absorbed and removed by the absorption tower 1, it is discharged to the outside from the upper part of the absorption tower 1 and released into the atmosphere from the stack or the like, while being absorbed by the spray nozzle 4 under the desired pressure in the absorption tower 1. When CO ₂ is absorbed and removed from the combustion exhaust gas by the agent, a liquid composed of CO ₂ and the absorbent is generated, and the liquid is supplied from the absorption tower 1 to the CO ₂ clathrate generator 2 and the CO ₂ clathrate generator. In 2, the liquid is cooled to 0 ° C. or lower by the cooling pipe 5 and is stirred by the stirrer 6 so that CO ₂ and water contained in the liquid become (CO ₂ + 7H ₂ O → CO ₂ · 7H ₂ O) Cause CO ₂ class Rate is generated, the absorbent including the remaining CO ₂ without being CO ₂ clathrate clathrate of generated in CO ₂ clathrate generator 2 is supplied to the separator 3, in the separator 3, The CO ₂ clathrate and the CO ₂ -containing absorbent remaining without being clathrated are separated, and the CO remaining without being clathrated
Part with CO ₂ clathrate separation of the absorbent comprising ₂ is extracted is returned to the CO ₂ clathrate generator 2, the absorbent comprising CO ₂ that remains without being clathrate of said absorption tower Returned to 1.

[0023] In the embodiment shown in FIG. 2, a portion of CO ₂ clathrate extracted from the separator 3 is returned to the CO ₂ clathrate generator 2, nucleus when the CO ₂ is clathrate of (so-called , The seed crystal), so that the CO ₂ clathrate generator 2 further promotes the clathration of CO ₂ .

FIG. 3 shows another embodiment of the present invention.
In the figure, the parts denoted by the same reference numerals as those in FIG. 1 represent the same things, and the basic configuration is the same as that shown in FIG. 1, but the feature of the present embodiment is shown in FIG. As shown,
By mixing fine spherical particles in the CO ₂ clathrate fed from the CO ₂ clathrate generator 2 to the separator 3,
The CO ₂ clathrate extracted from the separator 3 is separated from the spherical body, the CO ₂ clathrate obtained by separating the spherical body is extracted, and the spherical body is returned to the CO ₂ clathrate generator 2. The auxiliary separator 7 is provided.

As the spherical body, for example, a diameter of several mm
Using the degree of iron balls, mixed amount of CO ₂ clathrate generator 2 CO ₂ clathrate fed to separator 3 from the clathrate of by absorbent containing the remaining CO ₂ without flow It is about 10% or less.

In the case of the embodiment shown in FIG. 3, the combustion exhaust gas sent from the boiler or the like comes into contact with the absorbent sprayed from the spray nozzle 4 under a desired pressure in the absorption tower 1, and the absorbent is sprayed. After the CO ₂ is absorbed and removed by the absorption tower 1, it is discharged to the outside from the upper part of the absorption tower 1 and released into the atmosphere from the stack or the like, while being absorbed by the spray nozzle 4 under the desired pressure in the absorption tower 1. When CO ₂ is absorbed and removed from the combustion exhaust gas by the agent, a liquid composed of CO ₂ and the absorbent is generated, and the liquid is supplied from the absorption tower 1 to the CO ₂ clathrate generator 2 and the CO ₂ clathrate generator. In 2, the liquid is cooled to 0 ° C. or lower by the cooling pipe 5 and is stirred by the stirrer 6 so that CO ₂ and water contained in the liquid become (CO ₂ + 7H ₂ O → CO ₂ · 7H ₂ O) Cause CO ₂ class Rates are generated.

[0027] Subsequently, CO ₂ clathrate generator 2 absorber comprising CO ₂ that remains without being CO ₂ clathrate clathrate of generated in the separator 3 in a state of being mixed fine spherical body is supplied to, in the separator 3, and the absorbent containing CO ₂ clathrate clathrate of by remaining CO ₂ without including the spherical body is separated, CO ₂ containing spheroids separation of the absorbent The clathrate is sent to the auxiliary separator 7, and the CO ₂ -containing absorbent remaining without being clathrated is returned to the absorption tower 1.

The spherical particles-containing CO ₂ clathrate sent to the auxiliary separator 7 are separated and removed in the auxiliary separator 7 to be extracted, and the spherical particles separated and removed from the CO ₂ clathrate are extracted. Is returned to the CO ₂ clathrate generator 2.

In the embodiment shown in FIG. 3, since fine spherical particles are mixed in the CO ₂ clathrate fed from the CO ₂ clathrate generator 2 to the separator 3, the separator is made by the spherical particles. with adhesion is avoided CO ₂ clathrate in the 3, when the spherical body is separated from the CO ₂ clathrate auxiliary separator 7 is returned to the CO ₂ clathrate generator 2, CO ₂ is clathrate of CO ₂ clathrate generator ₂ because it becomes the nucleus (so-called seed crystal) of
The CO ₂ clathrate conversion is also promoted.

The flue gas decarbonator of the present invention is not limited to the above-described embodiment, and it goes without saying that various modifications can be made without departing from the gist of the present invention.

[0031]

Effect of the Invention] According to the smoke decarboxylation apparatus of the present invention, as described, obtained by absorbing and removing CO ₂ from the flue gas, the CO ₂ that the absorbent removed and easily form stable The CO ₂ clathrate can be processed by converting it into a handleable CO ₂ clathrate, and in the flue gas decarbonator, part of the CO ₂ clathrate extracted from the separator is sent to the CO ₂ clathrate generator. The one I tried to put back,
Further promote the CO ₂ clathrate CO ₂ clathrate returned to generator, because the CO ₂ is seed at the time of clathrate of a clathrate of CO ₂ in the CO ₂ clathrate generator 2 In addition, in the above-mentioned flue gas decarbonation device, fine spherical particles are mixed in the CO ₂ clathrate fed from the CO ₂ clathrate generator to the separator, and the auxiliary is provided. In the case where the separator is provided, CO ₂ in the separator is formed by the spherical body.
Together may avoid adhesion of clathrate, since the auxiliary separator with separated from CO ₂ clathrate spheroids is returned to the CO ₂ clathrate generator CO ₂ is seed when clathrate of, CO ₂ in the CO ₂ clathrate generator
It is possible to exert an excellent effect that it also helps promote the clathrate.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram of an embodiment of the present invention.

FIG. 2 is a schematic configuration diagram of another embodiment of the present invention.

FIG. 3 is a schematic configuration diagram of still another embodiment of the present invention.

[Explanation of symbols]

 1 absorption tower 2 clathrate generator 3 separator 5 cooling pipe 6 stirrer 7 auxiliary separator

Claims (3)

[Claims] 1. Under a desired pressure, CO ₂ contained in combustion exhaust gas is absorbed by an absorbent composed of a refrigerant that does not coagulate even at 0 ° C. or less and water to produce a liquid composed of CO ₂ and the absorbent. an absorption tower for discharging the flue gas to remove CO ₂ to the outside, CO ₂ clathrate generation liquid consisting of CO ₂ with the absorbent which is generated by the absorption column was cooled and stirred to produce a CO ₂ clathrate vessels and, the CO ₂ clathrate the generator CO ₂ clathrate generated by the clathrate of are absorbent containing the remaining CO ₂ without separating, CO ₂ that remains without being the clathrate of
A flue gas decarbonator, which is provided with a separator for returning the absorbent containing the to the absorption tower. 2. A flue decarbonation apparatus according to claim 1, wherein part characterized by being configured to return to the CO ₂ clathrate generator CO ₂ clathrate extracted from the separator. Wherein CO ₂ is the CO ₂ mixed fine spheroids during clathrate fed from clathrate generator to separator to separate the CO ₂ clathrate and spherical bodies extracted from the separator A flue gas decarboxylation device comprising an auxiliary separator for extracting the CO ₂ clathrate obtained by separating the spherical body and returning the spherical body to the CO ₂ clathrate generator.