Wet desulfurization apparatus capable of improving desulfurization efficiency and wet desulfurization method using the same

What is claimed is: 1. A wet desulfurization apparatus, comprising: a chamber enclosing a space for passing flue gas and including a first barrier partitioning the space into first and second chamber regions, a flue gas inlet configured to introduce raw flue gas into the first chamber region, and a flue gas outlet configured to discharge desulfurized flue gas from the second chamber region; a slurry reservoir including a second barrier partitioning the slurry reservoir into a first reservoir part configured to receive and store an alkaline slurry of a first pH value and a second reservoir part configured to receive and store an alkaline slurry of a second pH value; a first sprayer disposed in the first chamber region and configured to receive the alkaline slurry stored in the first reservoir part and to spray the received alkaline slurry into the first chamber region in order to remove sulfur (S) from the flue gas in the first chamber region; a second sprayer disposed in the second chamber region and configured to receive the alkaline slurry stored in the second reservoir part and to spray the received alkaline slurry into the second chamber region in order to remove sulfur (S) from the flue gas in the second chamber region; and a demister disposed in the second chamber region between the second sprayer and the flue gas outlet and configured to remove mist from the flue gas in the second chamber region. 2. The wet desulfurization apparatus of claim 1 , wherein the second pH value is higher than the first pH value. 3. The wet desulfurization apparatus of claim 1 , wherein the first pH value falls in a range of 4.5 to 5.0, and the second pH value falls in a range of 5.5 to 6.0. 4. The wet desulfurization apparatus of claim 1 , wherein the flue gas in the first chamber region forms a descending air current that passes through an opening between the first and second barriers to form an ascending air current in the second chamber region. 5. The wet desulfurization apparatus of claim 1 , wherein the first chamber region is disposed over the first reservoir part, and the second chamber region is disposed over the second reservoir part. 6. The wet desulfurization apparatus of claim 1 , further comprising: a first slurry supply pipe for supplying the first reservoir part with alkaline slurry; and a second slurry supply pipe for supplying the second reservoir part with alkaline slurry. 7. The wet desulfurization apparatus of claim 1 , further comprising: a first oxygen gas supply pipe for supplying the first reservoir part with oxygen gas; and a second oxygen gas supply pipe for supplying the second reservoir part with oxygen gas. 8. The wet desulfurization apparatus of claim 1 , wherein the first sprayer comprises: a first spray pipe communicating with the first reservoir part; and multiple spray nozzles disposed along the first spray pipe to spray the alkaline slurry of the first reservoir part. 9. The wet desulfurization apparatus of claim 1 , wherein the first sprayer consists of a plurality of sprayers respectively communicating with the second reservoir part and forming a multi-tiered structure arranged vertically in the first chamber region along a flow direction of the flue gas in the first chamber region. 10. The wet desulfurization apparatus of claim 1 , wherein the second sprayer comprises: a second spray pipe communicating with the second reservoir part; and multiple spray nozzles disposed along the second spray pipe to spray the alkaline slurry of the second reservoir part. 11. The wet desulfurization apparatus of claim 1 , wherein the second sprayer consists of a plurality of sprayers respectively communicating with the second reservoir part and forming a multi-tiered structure arranged vertically in the second chamber region along a flow direction of the flue gas in the second chamber region. 12. The wet desulfurization apparatus of claim 1 , wherein the demister comprises: an upper support frame fixed to an inner wall of the chamber; a lower support frame fixed to the inner wall of the chamber; and a plurality of corrugated plates spaced apart from each other, each corrugated plate having an upper end joined to the upper support frame and a lower end joined to the lower support frame. 13. The wet desulfurization apparatus of claim 12 , wherein each of the corrugated plates comprises: a crest plate extending vertically and protruding in a first direction; a valley plate extending vertically and protruding in a second direction opposite to the first direction; a plate fastener extending vertically to fasten the upper end of the corrugated plate to the upper support frame and to fasten the lower end of the corrugated plate to the lower support frame; and a plurality of coupling plates extending obliquely to couple the plate fastener to each of the crest plate and the valley plate and to couple the crest plate and the valley plate to each other. 14. The wet desulfurization apparatus of claim 12 , wherein the demister further comprises: a demisting pipe communicating with the second reservoir part; and multiple spray nozzles disposed along the demisting pipe to spray the alkaline slurry of the second reservoir part downward onto the demister in order to remove mist attached to the upper support frame, the lower support frame, and the corrugated plates. 15. The wet desulfurization apparatus of claim 1 , further comprising a slurry transfer controller for controlling an amount of the alkaline slurry being transferred from the slurry reservoir to at least one of the first sprayer, the second sprayer, and the demister. 16. The wet desulfurization apparatus of claim 15 , wherein the second sprayer comprises: a second spray pipe communicating with the second reservoir part; and multiple spray nozzles disposed along the second spray pipe to spray the alkaline slurry of the second reservoir part, wherein the second sprayer consists of a plurality of sprayers forming a multi-tiered structure arranged vertically in the second chamber region along a flow direction of the flue gas in the second chamber region, and each second spray pipe of the second sprayer communicates with the second reservoir part separately. 17. The wet desulfurization apparatus of claim 16 , wherein the slurry transfer controller is configured to control the amount of the alkaline slurry being transferred from the slurry reservoir to each sprayer of the plurality of sprayers, such that a higher-positioned sprayer of the multi-tiered structure receives more alkaline slurry than a lower-positioned sprayer of the multi-tiered structure. 18. The wet desulfurization apparatus of claim 17 , wherein the demister further comprises: a demisting pipe communicating with the second reservoir part; and multiple spray nozzles disposed along the demisting pipe to spray the alkaline slurry of the second reservoir part downward onto the demister in order to remove mist attached to the upper support frame, the lower support frame, and the corrugated plates and in order to remove sulfur from the flue gas in the second chamber region, and wherein the slurry transfer controller is further configured to control the amount of the alkaline slurry being transferred from the slurry reservoir to the demisting pipe, by intermittently supplying alkaline slurry to remove mist attached to the upper support frame. 19. A method for removing sulfur (S) from flue gas using a wet desulfurization apparatus comprising a chamber enclosing a space for passing the flue gas and i