KR20200060818A - Method and system for mineralization of carbon dioxide using kiln dust - Google Patents

Abstract

Disclosed are a method and a system for mineralization of carbon dioxide using kiln dust. A method for mineralization of carbon dioxide using kiln dust includes: a step of manufacturing an effluent, in which Ca and Mg are included, by adding water to the kiln dust generated during a cement manufacturing process and then agitating the mixture; and a step of separating ionic water from the effluent such that the ionic water reacts with carbon dioxide collected in advance and then mineralizing the reactant. Accordingly, because carbon dioxide can be mineralized with a minimized process as the kiln dust generated as a side-product in the cement manufacturing process reacts with carbon dioxide, economic benefits due to recycling of the mineralized calcium carbonate and magnesium carbonate and a subsidiary economic benefits due to reduction of discharged carbon can be expected.

Description

Method and system for mineralization of carbon dioxide using kiln dust}

The present invention relates to a method and system for mineralization of carbon dioxide using kiln dust, and more specifically, kiln dust capable of mineralizing carbon dioxide, which is a major cause of greenhouse gas, by reacting kiln dust and carbon dioxide generated in a cement manufacturing process. It relates to a method and system for mineralization of carbon dioxide utilizing.

As industrial technology develops, global warming is accelerating as the concentration of carbon dioxide increases in the atmosphere, and thus, awareness and the need to reduce carbon emissions are increasing.

Despite this recognition and necessity, cement is inevitably used as a material for constructing buildings, and cement has a problem that it emits a large amount of carbon dioxide during the manufacturing process.

In order to solve the above problems, as shown in Korea Patent Registration No. 10-1450697 (registered on Oct. 07, 2014), cement kiln dust is added to the solvent and stirred to prepare an eluate containing calcium (Ca) and the like. , Separation of sediments from the prepared eluate is known, and a technique is known in which the precipitated sediments react with carbon dioxide at a low temperature to produce calcium carbonate.

However, in order to effectively and productively separate sediments, a plurality of sedimentation/filtering processes in which a plurality of methods are mixed are usually carried out, but since environmental factors or other incidental conditions may change from time to time, individual sedimentation/filtration processes are appropriate. It is a reality that it is difficult to design each one.

Accordingly, a plurality of sedimentation/filtration processes are carried out, and a sedimentation/filtration process suitable for individual situations is performed, so that unnecessary processes are omitted, and a search for a method for promoting economic efficiency of mineralization is required.

Republic of Korea Registered Patent Publication 10-1450697

The present invention has been devised to solve the above problems, and the object of the present invention is to minimize the carbon dioxide that is the main cause of greenhouse gasification by reacting kiln dust and carbon dioxide generated in the cement manufacturing process. It is to provide a method and system for mineralization of carbon dioxide utilizing.

The mineralization method of carbon dioxide utilizing kiln dust according to an embodiment of the present invention for achieving the above object is by adding water to the kiln dust generated by the cement manufacturing process, followed by stirring, and then eluent containing Ca and Mg. Preparing a; And separating ionic water from the eluate and mineralizing it by reacting with bubbled carbon dioxide.

In addition, the mineralization system of carbon dioxide utilizing kiln dust according to an embodiment of the present invention for achieving the above object includes Ca and Mg by stirring after adding water to the kiln dust generated by the cement manufacturing process. An extraction device for preparing the eluate; An ionic water separation device for separating ionic water from the eluate through a plurality of separation processes; And a mineralization device that mineralizes by reacting carbon dioxide with the separated ionized water.

Here, the ion water separation device, the first filtering unit for receiving the eluate containing the Ca and Mg from the extraction device, filtered using a specific gravity difference and re-delivered to the extraction device; And a second filtration unit receiving the eluate filtered by the first filtration unit from the extraction device, filtering it based on centrifugal force by rotation, and re-transmitting it to the extraction device.

In addition, the ion water separation device includes: a third filtration unit that receives the eluate filtered by the second filtration unit from the extraction device, filters it through a filtration network, and redistributes it to the extraction device; And a fourth filtration unit that receives the eluate filtered by the third filtration unit from the extraction device, filters it through a filtration network, and then delivers it to the mineralization device.

In addition, the extraction device, the ion sensor for sensing the concentration of Ca cations and Mg cations contained in the eluate therein; And a delivery determination unit determining whether to deliver the ionized water to the ionizer based on the concentration sensed by the ion sensor.

Here, the ion sensor, the filtration process by the first filtration unit, the filtration process by the second filter unit, the filtration process by the third filter unit and the filtration process by the fourth filter unit concentration, respectively Sensing, and if the delivery determination unit determines that the sensed concentration exceeds a predetermined concentration in one filtration process among the filtration processes, the eluate is mineralized so that another filtration process after the one filtration process is omitted. Can be delivered to the device.

In addition, the predetermined concentration may be a concentration determined to be sufficient to mineralize the bubbled carbon dioxide into calcium carbonate and magnesium carbonate.

As a result, it is possible to mineralize carbon dioxide in a minimized process by reacting kiln dust and carbon dioxide generated as a by-product in the cement manufacturing process, so that economic benefits through recycling of mineralized calcium carbonate and magnesium carbonate can be expected, and carbon emission The additional economic benefits of mitigation can also be expected.

1 is a view for explaining a mineralization system of carbon dioxide using kiln dust according to an embodiment of the present invention.
2 is a view for explaining the mineralization process of carbon dioxide using a kiln dust according to an embodiment of the present invention.
3 is a view for explaining the configuration of the ion water separation apparatus according to an embodiment of the present invention.
4 is a view for explaining the configuration of the extraction device according to an embodiment of the present invention.
5 is a view provided to explain a process in which a process is omitted according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

The embodiments introduced below are provided as examples for sufficiently conveying the spirit of the present invention to those skilled in the art to which the present invention pertains. The present invention is not limited to the embodiments described below and may be embodied in other forms.

1 is a view for explaining a mineralization system of carbon dioxide using a kiln dust according to an embodiment of the present invention, Figure 2 is a process for mineralizing carbon dioxide using a kiln dust according to an embodiment of the present invention 3 is a view for explaining the configuration of the ion water separation device according to an embodiment of the present invention.

The mineralization system of carbon dioxide utilizing kiln dust according to the present embodiment is capable of mineralizing carbon dioxide, which is a major cause of greenhouse gasification, by minimizing a process by reacting kiln dust and carbon dioxide generated in a cement manufacturing process.

Kiln dust is an industrial waste generated as a by-product in the cement manufacturing process, and is also called cement kiln dust or CKD. The kiln dust is composed of CaO, SiO2, Al2O3, K2O, MgO, and the like.

On the other hand, the mineralization system of carbon dioxide utilizing the kiln dust according to the present embodiment for this purpose, is composed of an extraction device 100, an ionized water separator 200 and a mineralization device 300.

The extraction device 100 is provided at the center of the system, and after adding water to the kiln dust generated by the cement manufacturing process and stirring it, serves to prepare an eluate containing Ca and Mg.

Of course, the solvent added to the kiln dust may be ammonium chloride, ammonium acetate or the like as a solvent other than water.

When water is added to the kiln dust and stirred as described above, Ca and Mg are present in an ionic state in the eluate, and conditions for reacting with carbon dioxide are prepared.

However, since the eluate prepared through stirring in the extraction device 100 contains a large amount of impurities, the extraction device 100 delivers the prepared eluate to the ionized water separator 200 so that impurities are filtered (S11).

The ionized water separator 200 utilizes a precipitation method, a centrifugal force collection method, a filter method, etc. to filter impurities from the eluate prepared in the extraction device 100, and various methods in a state having various configurations to use these methods Can be mixed.

The reason why various methods are used in combination is because it is difficult to filter the impurity at a desired level using only one method, and when filtration is performed only with the method in which the result of the final product is the best, it is time-consuming or expensive. .

That is, when a plurality of methods are mixed and used in stages, impurities can be more quickly and effectively removed.

In this embodiment, the ionized water separation device 200 has a maximum of four configurations: the first filter unit 210, the second filter unit 220, the third filter unit 230, and the fourth filter unit 240. It is assumed that impurities are filtered in at least two different ways.

The first filtration unit 210 filters impurities using the specific gravity difference in the eluate prepared in the extraction device 100. For example, when the eluate prepared in the extraction device 100 is delivered to the first filter unit 210, the first filter unit 210 only stores the eluate for a predetermined time, and then separates the layer by specific gravity difference. The ionized water in the upper layer portion may be transferred back to the extraction device 100 (S12), and impurities in the lower layer portion may be discarded.

When the eluate filtered by the first filtering unit 210 is transferred to the extraction device 100 again (S12), the extraction device 100 transfers it to the second filtering unit 220 using a device such as a pump ( S13).

The second filtering unit 220 filters the eluate in a hydrocyclone method. The second filtration unit 220 collects the ionized water upward to the internal swirl flow based on the centrifugal force, transfers it back to the extraction device 100 (S14), and discards impurities that are downward due to the weight even under the influence of the centrifugal force.

When the eluate filtered by the second filtering unit 220 is transferred back to the extraction device 100 (S14), the extraction device 100 delivers it to the third filtering unit 230 (S15).

The third filtering unit 230 filters the eluate in a filtering network method. The third filtration unit 230 is configured in a mesh form for passing ionic water in the eluate and filtering impurities other than ionic water, collecting the passed ionic water and transferring it back to the extraction device 100 (S16), The impurities are thrown away.

When the eluate filtered by the third filtering unit 230 is transferred back to the extraction device 100 (S16), the extraction device 100 delivers it to the fourth filtering unit 240 (S17).

The fourth filtration unit 240 filters the eluate in the same way as the third filtration unit 230. The fourth filtration unit 240 is configured in a mesh form for passing the ionic water in the eluate and filtering impurities other than ionic water, collecting the passed ionic water and finally reacting with carbon dioxide in an external mineralization device or mineralization device. Transfer to the storage unit 250 is provided so that it can be stored until (S18).

On the other hand, the first filtration unit 210, the second filtration unit 220 and the third filtration unit 230, the ionized water is completely removed from the impurities is transferred back to the extraction device 100, the reason for this is Figure 4 And will be described later with reference to FIG. 5.

By providing various configurations in this way and filtering impurities in various ways, faster and more effective filtration is possible, so most of kiln dust mineralization systems of carbon dioxide use multiple methods by mixing multiple methods. I do it.

In other words, in order to prevent unnecessary investment and to effectively mineralize, before installing a carbon dioxide mineralization system using kiln dust on the site, it is necessary to determine in advance what facilities and methods will be used to filter impurities. Need to build.

In addition, even though it is possible to selectively use all the available configurations, it is not easy to sort out the configurations to be used in the actual field and to rearrange or reconfigure them to operate only the selected configurations.

Hereinafter, with reference to FIGS. 4 and 5, a plurality of precipitation/filtration processes are performed, and a precipitation/filtration process suitable for individual situations is performed, so that unnecessary processes are omitted, and thus a method for promoting economic efficiency of mineralization. I will explain.

4 is a view for explaining the configuration of the extraction apparatus 100 according to an embodiment of the present invention, Figure 5 is a view provided to explain the process of the process is omitted according to an embodiment of the present invention.

As described above, in order to promote the economic efficiency of mineralization, the extraction device 100 includes an ion sensor 110 and a transfer crystal unit 120.

The ion sensor 110 serves to sense the concentrations of Ca cations and Mg cations contained in the eluate inside the extraction device 100. In particular, the ion sensor 110 has a filtration process by the first filter unit 210, a filtration process by the second filter unit 220, a filtration process by the third filter unit 230, and a fourth filter unit The concentration is sensed for each filtration process by 240.

The ion sensor 110 transmits data on the sensed concentration to the transfer determination unit 120, and the transfer determination unit 120 extracts the apparatus 100 based on the received concentration data-the first filtering unit 210 -The extraction device 100-the second filter unit 220-the extraction device 100-the third filter unit 230-the extraction unit 100-shortens the process of the fourth filter unit 240.

That is, if it is determined that the concentration of the ionized water sensed through the ion sensor 110 is sufficient to mineralize the carbon dioxide collected in advance, the transfer determination unit 120 immediately proceeds to the ionized water without going through an additional process even if an additional process remains. Can be stored in the storage unit 250.

For example, if it is determined that the sensing concentration in the ionized water re-transmitted from the second filtering unit 220 to the extraction device 100 exceeds a preset reference concentration, it is determined to be sufficient to mineralize the carbon dioxide collected in advance. The transfer determination unit 120 of the device 100 is to allow the ionized water to be directly transferred to the storage unit 250 without additional filtration in progress in the third filtering unit 230.

Meanwhile, the ion sensor 110 may separately include a first sensing unit (not shown) for sensing the concentration of Ca in ionized water and a second sensing unit (not shown) for sensing the concentration of Mg. Even when provided separately, the transfer determination unit 120 of the extraction apparatus 100 can shorten the basic process if it is determined that the carbon dioxide collected in advance is sufficient to mineralize.

Here, whether the concentration of the sensed ionized water is in a state sufficient to mineralize the pre-captured carbon dioxide can be determined in various ways. As described above, the concentration/amount of the pre-captured carbon dioxide is measured and the pre-captured carbon dioxide is measured. There may be a method of pre-storing a reference value for a concentration/amount of ion water sufficient to mineralize, and a method of pre-storing a value collectively set by a user. This will allow the reference value to be calculated.

Accordingly, it is possible to mineralize carbon dioxide by reacting kiln dust and carbon dioxide generated as a by-product in the cement manufacturing process, and in particular, it is possible to prevent an unnecessary process from proceeding through only the process necessary for mineralization of carbon dioxide.

In the above, preferred embodiments of the present invention have been illustrated and described, but the present invention is not limited to the specific embodiments described above, and it is usually in the technical field to which the present invention belongs without departing from the gist of the present invention claimed in the claims. It is of course possible to perform various modifications by a person having knowledge of, and these modifications should not be individually understood from the technical idea or prospect of the present invention.

100: extraction device 110: ion sensor
120: transfer crystal unit 200: ion water separation device
210: first filter unit 220: second filter unit
230: third filtration unit 240: fourth filtration unit
250: storage unit 300: mineralization device

Claims (7)

Adding water to the kiln dust generated by the cement manufacturing process and stirring to prepare an eluate containing Ca and Mg; And
Separating ionic water from the eluate and reacting with the trapped carbon dioxide to mineralize it; mineralization method of carbon dioxide using kiln dust comprising An extraction device for adding water to the kiln dust generated by the cement manufacturing process and stirring to prepare an eluate containing Ca and Mg;
An ionic water separation device for separating ionic water from the eluate through a plurality of separation processes; And
A mineralization system for carbon dioxide utilizing kiln dust, including a mineralization device that mineralizes by reacting carbon dioxide with the separated ionized water. According to claim 2,
The ion water separation device,
A first filtration unit that receives the eluate containing Ca and Mg from the extraction device, filters it using a specific gravity difference, and re-transmits it to the extraction device; And
Kiln dust characterized in that it comprises; a second filter for receiving the eluate filtered by the first filter unit from the extraction device, filtered based on centrifugal force by rotation and then re-delivered to the extraction device Mineralization system of carbon dioxide utilized. According to claim 3,
The ion water separation device,
A third filtration unit receiving the eluate filtered by the second filtration unit from the extraction device, filtering through a filtration network, and re-transmitting it to the extraction device; And
Carbon dioxide utilizing kiln dust, characterized in that it further comprises; a fourth filtration unit receiving the eluate filtered by the third filtration unit from the extraction device, filtered through a filtration network and then delivered to the mineralization device. Mineralization system. The method of claim 4,
The extraction device,
An ion sensor for sensing the concentration of Ca cations and Mg cations contained in the eluate therein; And
It characterized in that it comprises a; delivery determining unit for determining whether to deliver to the ion water separation device based on the concentration sensed from the ion sensor; CO2 mineralization system using a kiln dust. The method of claim 5,
The ion sensor,
Each of the filtration process by the first filtration unit, the filtration process by the second filtration unit, the filtration process by the third filtration unit, and the filtration process by the fourth filtration unit, each senses concentration,
The delivery decision unit,
When it is determined that the sensed concentration exceeds a predetermined concentration in one filtration process among the filtration processes, the eluate is transferred to the mineralization apparatus so that another filtration process after the one filtration process is omitted. Carbon dioxide mineralization system using kiln dust. The method of claim 6,
The predetermined concentration,
A mineralization system of carbon dioxide utilizing kiln dust, characterized in that it is determined to be sufficient to mineralize the bubbled carbon dioxide into calcium carbonate and magnesium carbonate.

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