The present invention relates to a device and method for extracting and separating sodium and potassium from a material containing sodium, potassium, and chlorine.
Household and industrial wastes have been usually incinerated in incinerators. Ash generated by the incineration has been provided for, for example, landfill. However, household wastes contain sodium and potassium but, in particular, sodium in the form of chloride, that is, salt in many cases. Thus, at least certain amounts of sodium, potassium, and chlorine are contained also in incineration ash. Once the incineration ash is buried, the resources can be neither collected nor recycled.
Meanwhile, a method has been already proposed for collecting sodium and potassium from wastewater such as domestic wastewater (for example, see Japanese Patent Application Laid-Open Publication No. 2001-26418). The collecting method includes the electrodialysis step of separating and collecting the wastewater as concentrated water containing monovalent ions by an electrodialyser including a monovalent ion selective ion-exchange membrane, and the step of separating and collecting sodium chloride and potassium chloride from the collected water by crystallization.
An object of the present invention is to provide a new device and method for effectively separating and collecting sodium and potassium in the form of salt from a material containing sodium, potassium, and chlorine, such as household and industrial wastes.
In order to solve the problem, a first aspect of the present invention is a device for extracting and separating sodium and potassium, including: a water solution preparing unit for preparing a solution containing sodium, potassium, and chlorine by using a material containing sodium, potassium, and chlorine, the solution having a first temperature; a cooling crystallizer for reducing the temperature of the solution to a second temperature which is lower than the first temperature to produce and separate potassium chloride; an absorption tower for reacting the solution with carbon dioxide-containing gas to produce and separate sodium hydrogen carbonate; and a returning unit for returning to the water solution preparing unit a liquid obtained after the production and separation of the potassium chloride in the cooling crystallizer and the sodium hydrogen carbonate in the absorption tower.
In the device for extracting and separating sodium and potassium, the cooling crystallizer and the absorption tower are tandemly arranged in this order.
In the device for extracting and separating sodium and potassium, the water solution preparing unit is an ash reactor, the material further contains magnesium and calcium, the liquid returned to the ash reactor contains carbonate ions produced by the reaction of the solution with the carbon dioxide in the absorption tower, and the ash reactor is capable of reacting the carbonate ions contained in the liquid returned to the ash reactor with the magnesium and the calcium contained in the material to produce magnesium carbonate and calcium carbonate.
Another aspect of the present invention is a method for extracting and separating sodium and potassium, including the steps of: producing a solution containing sodium, potassium, and chlorine by using a material containing sodium, potassium, and chlorine, the solution having a first temperature; producing and separating potassium chloride from the solution by reducing the temperature of the solution to a second temperature which is lower than the first temperature; reacting the solution with carbon dioxide-containing gas to produce and separate sodium hydrogen carbonate from the solution; and providing a liquid obtained after the production and separation of the potassium chloride and the sodium hydrogen carbonate for the production of the solution having the first temperature.
In the method for extracting and separating sodium and potassium, the sodium hydrogen carbonate is produced and separated from the solution after the production and separation of the potassium chloride from the solution.
In the method for extracting and separating sodium and potassium, the material further containing magnesium and calcium is used, a liquid containing carbonate ions produced by the reaction of the solution with the carbon dioxide-containing gas is provided for the production of the solution having the first temperature, and the carbonate ions contained in the liquid are reacted with the magnesium and calcium contained in the material to produce magnesium carbonate and calcium carbonate.
According to the present invention, it is possible to extract and separate potassium in the form of potassium chloride and sodium in the form of sodium hydrogen carbonate, from a material containing sodium, potassium, and chlorine.
A residual liquid obtained after the separation of the potassium and sodium is provided for the preparation of the solution having the first temperature, and can, be circulated in the system for recycling.
Carbon dioxide-containing gas is used for producing sodium hydrogen carbonate, and exhaust gas from, for example, a combustor can be used as the carbon dioxide-containing gas. Thus, according to the present invention, carbon dioxide can be immobilized concurrently with the extraction of sodium and potassium.
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Reference numeral 17 denotes a pulverizer which can pulverize incineration ash from an incinerator (not shown) and supply it to the ash reactor 12. Examples of the incinerator include one which incinerates household and industrial wastes. Generally, incineration ash generated in such an incinerator contains sodium, potassium, and chlorine, and further contains calcium and magnesium. Sodium and chlorine typically take the form of salt. Potassium and chlorine typically take the form of potassium chloride. The ash reactor 12 includes an agitator 18.
The carbon dioxide absorption tower 11 allows exhaust gas containing carbon dioxide gas (CO2) from the flue of the incinerator (not shown) to pass through, so that the carbon dioxide absorption tower 11 can absorb (treat) the carbon dioxide and return the absorbed gas to the flue. Reference numeral 19 denotes a supply port for exhaust gas from the flue, and reference numeral 20 denotes an exhaust port for exhaust gas to the flue. Reference numeral 21 denotes a shower nozzle which can splash a water solution from the circulation path 13 on exhaust gas passing through the carbon dioxide absorption tower 11.
In this configuration, water is initially circulated in the circulation path 13. As described above, the incineration ash generated in the incinerator (not shown) contains sodium, potassium, chlorine, calcium, and magnesium in the form of chloride such as salt. The incineration ash is supplied to the pulverizer 17, is finely pulverized, and is fed to the ash reactor 12.
In the ash reactor 12, the sodium, potassium, calcium, and magnesium in the form of chloride dissolve in water, the calcium and magnesium react with carbonate ions in the water to form a carbonate as will be described later, and the carbonate is precipitated and removed. As will hereinafter be described in detail, the temperature of the ash reactor 12 is set so as to perform treatment at about 60° C. (a first temperature).
The salt solution which excludes calcium and magnesium and has a temperature of 60° C. is obtained in the form of a salt solution containing sodium chloride and potassium chloride, and is supplied to the cooling crystallizer 16 via the solution supply path 14.
In the cooling crystallizer 16, the supplied solution is cooled to about 30° C. (a second temperature). Potassium chloride has a saturation concentration at 30° C. which is significantly lower than, that at 60° C. Thus, the potassium chloride in the solution is crystallized as salt in the cooling crystallizer 16 and is precipitated on the bottom thereof, so that potassium can be separated from the solution as the potassium chloride (KCl).
The cooling crystallizer 16 may forcibly cool the solution or may simply include a cyclone separator in the form of natural radiation of heat in some cases.
The solution, from which potassium chloride is separated in the cooling crystallizer 16, is supplied to the carbon dioxide absorption tower 11, and is sprinkled in the tower through the shower nozzle 21.
The exhaust gas containing carbon dioxide has been supplied to the carbon dioxide absorption tower 11 from the flue of the incinerator (not shown). The exhaust gas contacts the solution sprinkled in the tower. The carbon dioxide dissolves in the solution in the form of carbonate ions, and the carbonate ions react with the sodium in the solution, so that sodium hydrogen carbonate (NaHCO3) is produced. The sodium hydrogen carbonate is crystallized and precipitated in the solution in the carbon dioxide absorption tower 11, and is discharged and removed out of the system. Thus, the sodium contained in the incineration ash is extracted, selectively separated, and removed.
The solution excluding sodium contains residual carbonate ions, but is fed as it is to the ash reactor 12. In the ash reactor 12, the calcium and magnesium immediately react with carbonate ions in the water as described above to produce calcium carbonate (CaCO3) and magnesium carbonate (MgCO3) which are precipitated with residual ash. The precipitated calcium carbonate, magnesium carbonate, and residual ash are discharged out of the system, and are used for landfill or recycled as a cement material.
Specifically, in the system of
The exhaust gas supplied to the carbon dioxide absorption tower 11 will be described. For example, the carbon dioxide concentration of exhaust gas of a refuse incinerator is about 10%. The exhaust gas is supplied in an appropriate amount to the carbon dioxide absorption tower 11 and dissolves in a solution, so that the exhaust gas is used for the extraction of sodium and the precipitation and separation of calcium carbonate and magnesium carbonate in the ash reactor 12. Thus, the carbon dioxide in the exhaust gas is immobilized.
The gas from which the immobilized carbon dioxide is removed is returned to the flue through the exhaust port 20 of the carbon dioxide absorption tower 11.
A mechanism for separating potassium and sodium will be described.
The following will describe the ionic behavior in the system.
As shown in the graph of
[K++Na+]=[Cl−+HCO3−+2CO32-]
A large amount of CO32- is advantageous to the immobilization of calcium carbonate and magnesium carbonate in the ash reactor 12. That is, the concentration of Cl− cannot be increased. Thus, under the condition that potassium chloride is crystallized, the concentration of K+ inevitably increases. However, since sodium hydrogen carbonate is selectively crystallized in the carbon dioxide absorption tower 11, an appropriate upper limit is set on the concentration of K+.
The operating temperature of the carbon dioxide absorption tower 11 will be described. In order to react carbon dioxide with sodium, the carbon dioxide absorption tower 11 is favorably set at a low temperature. However, if sodium hydrogen carbonate is excessively crystallized in the carbon dioxide absorption tower 11, the amount of carbonate ions supplied to the ash reactor 12 is reduced. Further, the ash reactor 12 set at a high temperature is advantageously short in reaction time. Thus, it is preferable that the temperature of the carbon dioxide absorption tower 11 be not excessively reduced. However, in the case where carbon dioxide-containing gas supplied to the carbon dioxide absorption tower 11 is gas exhausted from an incinerator, the exhaust gas exceeds, for example, a high temperature of 160° C., and the absorption reaction of the carbon dioxide is exothermic reaction. Thus, efforts to reduce the temperature are desirably made. Moreover, the carbon dioxide absorption tower 11 set at above 60° C. is likely to decompose sodium hydrogen carbonate, so that the crystallization of sodium hydrogen carbonate may be obstructed.
In view of the foregoing, the following will describe the optimum conditions of a water solution in the circulation path 13, that is, the conditions of a water solution which can be circulated.
First, the pH level of the solution circulating in the circulation path 13 will be described.
The pH level can be controlled by the amounts of absorbed carbon dioxide and incineration ash without using other agents. In the case where the pH level is controlled by the amount of absorbed carbon dioxide, the amount of gas introduced to the carbon dioxide absorption tower 11 is adjusted and the solution circulating in the circulation path 13 is bypassed, so that the pH level can be controlled. As shown in
CO32-+CO2(g)+H2O=2HCO3−
However, it has to be considered how the pH control affects the above-described temperature control of the carbon dioxide absorption tower 11.
The conditions of a solution to be circulated will be specifically described.
The solution to be circulated has to be properly controlled to prevent undesired compounds from being crystallized, since the crystallization of undesired compounds may interrupt the continuation of circulation or reduce the economic efficiency. In response, in the extracting and separating device of the present invention, the optimum ranges of temperature of a solution in the cooling crystallizer 16, temperature of a solution in the absorption tower 11 (crystallization temperature of hydrogen carbonate), and pH value of a solution at the outlet of the absorption tower 11 (amount of absorbed carbon dioxide) were investigated by experiments and simulations. The results of the investigation are shown in the graphs of
In the graphs, the pH of a solution at the outlet of the absorption tower 11 is set as a parameter, the abscissa indicates the temperature of the absorption tower 11, the ordinate indicates the temperature of the cooling crystallizer 16, and the solubility curves are shown. The circulation of a solution can be continued in areas indicated by oblique lines.
It is noted from the graphs that since the optimum ranges are safer away from the solubility curves, the optimum temperature range of a solution in the cooling crystallizer 16 is 30° C. to 35° C., the optimum temperature range of a solution in the carbon dioxide absorption tower 11 is 35° C. to 60° C. (preferably, 40° C. to 45° C.), and the optimum pH value of a solution at the outlet of the carbon dioxide absorption tower 11 is 9.5 to 10.0.
The solution circulating in the circulation path 13 is heated by exhaust gas in the absorption tower 11, so that scale is effectively prevented from being generated.
Next, the amount of water in a solution circulating in the circulation path 13 will be described. In the case where carbon dioxide-containing gas is exhausted from an incinerator, the gas contains moisture, and the amount of water increases accordingly. Meanwhile, since ash supplied to the ash reactor 12 is discharged after absorbing moisture, the amount of water decreases. A solution, in particular, a saturated solution obtained by being concentrated can be used as a rinse for the discharged residual ash. Further, water condensed during cooling of the introduced exhaust gas can be also used as a rinse for the discharged residual ash.
Since sodium hydrogen carbonate is crystallized in the carbon dioxide absorption tower 11, it is difficult to use filler in the carbon dioxide absorption tower 11.
Since the wall surface of the carbon dioxide absorption tower 11 has a relatively low temperature, sodium hydrogen carbonate is easily deposited. However, since it is difficult to prevent scale from being generated by heating the wall surface, salt water having a low concentration or the like is effectively sprayed to the wall surface.
It is preferable that sodium hydrogen carbonate undergo crystal growth without reducing a crystallized particle size. A small crystallized particle size may cause adhesion to the flue during gas injection to the carbon dioxide absorption tower 11, in addition to a reduction in settleability and filtration properties. Further, sodium hydrogen carbonate which is of excessively high purity is easily degraded but is not suitable for recycling. Thus, the process has to be manipulated such that the sodium hydrogen carbonate becomes a highly conservative constituent.
The operating temperature of the ash reactor 12 will be described. In view of the performance of the system in
Ash finely pulverized by the pulverizer 17 has high extractability. How finely ash is pulverized depends on a balance with energy required for the pulverization.
In the ash reactor 12, when calcium is melted from incineration ash, the calcium instantly becomes a carbonate on the particle surface, which coats the particle itself. Thus, calcium remained inside the particle is not extracted, decelerating reaction. Strong agitation is preferably performed by the agitator 18 to remove the coating. Alternatively, gentle mechanochemical polishing is preferably performed.
A material supplied to the ash reactor 12 will be described.
The material has to satisfy the following formula in molarity:
[K+Na]>Cl
If the above formula is not satisfied, the circulation in the system does not function.
Further, in the case where potassium is smaller in amount than chlorine (K<Cl), sodium chloride is deposited, exerting a negative impact on the production of sodium hydrogen carbonate.
The above-described relationships are fundamentally determined in accordance with constituents of incineration ash which is a material supplied to the ash reactor 12. Meanwhile, salt waste water, fly ash, and an agent are added, so that favorable results may be produced.
In the above-described embodiment, incineration ash generated in an incinerator is exemplified as a material containing constituents. However, other materials can be used. For example, fly ash can be used. In this case, since the content of chlorine is large, under the condition that potassium (K) is required to be equal to or larger than chlorine (Cl), potassium has to be externally added.
Further, in the case where potassium is larger in amount than chlorine (K>Cl), redundant potassium is crystallized as potassium hydrogen carbonate together with sodium hydrogen carbonate in the carbon dioxide absorption tower 11. Moreover, the sodium hydrogen carbonate with the potassium hydrogen carbonate mixed therein can be separated by using a difference in solubility. Alternatively, the sodium hydrogen carbonate with the potassium hydrogen carbonate can be used for, for example, an acid gas removing agent for an incinerator, without being separated.
In the above-described embodiment, carbon dioxide-containing gas exhausted from the flue of an incinerator is exemplified, but other gas can be used.
As described above, according to the present invention, potassium can be extracted and separated in the form of potassium chloride, and sodium can be extracted and separated in the form of sodium hydrogen carbonate, from a material containing sodium, potassium, and chlorine.
Further, since the residual liquid after the extraction of potassium and sodium is provided for the preparation of a solution having a temperature of about 60° C. (the first temperature), the residual liquid can be circulated in the system for recycling.
Moreover, carbon dioxide-containing gas is used during the formation of sodium hydrogen carbonate, and may be exhaust gas from, for example, combustion equipment. Thus, according to the present invention, carbon dioxide can be immobilized concurrently with the extraction of sodium and potassium.
The extracting and separating device of the present invention can extract and separate potassium in the form of potassium chloride and sodium in the form of sodium hydrogen carbonate, from a material containing sodium, potassium, and chlorine. Thus, the present invention is suitable for collecting, for example, resources contained in incineration residues of household and industrial wastes exhausted from incinerators.
Number | Date | Country | Kind |
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2009-171671 | Jul 2009 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2010/062295 | 7/22/2010 | WO | 00 | 12/15/2011 |