TH62535B - Desulfurization equipment to flu-gas using sea water and desulfurization methods of seawater treatment. - Google Patents

Abstract

DC60 (21/04/15) The device was processed using first sea water 10-1 in accordance with this design, including an absorption device. Desulfurization to flu-gas 13, dilution bath 16 and gas storage unit 20A in desulfurization to flu-gas 13, sulfur content in flue gas 11 was introduced into contact with seawater, absorbed 12A as part of seawater 12, and by purification of flue gas 11, a dilute mixing bath 16 was provided collectively on the bottom of the desulfurise sorbent. In a dilution bath 16, seawater absorbed, the sulfur content 14A was produced by desulfurization using sea water, with the sulfur content in flue gas 11 reduced by In contact with seawater, 12A absorbed in a desulfurization agent against flu-gas 13, mixed / diluted using seawater, 12B dilution, fed into its main body 15, total 20A gas storage unit. To block 18 and first baffle 19, closure 18 was provided on the lower end of the side wall 17 of the desulfurization fluid-gas absorber 13 to be extended along the side. The length of the dilution bath 16 to cover the dilution bath 16 the first baffle 19 hung from the side of the back face of the cover 18 and the end of the first baffle 19 is immersed under the sea water surface in the dilution bath. 16 2nd day correction 1/04/2558 The device was processed using sea water at 10-1 in accordance with this figure, including an absorption device Desulfurization to flu-gas 13, dilution bath 16 and gas storage unit 20A in desulfurization to flu-gas 13, sulfur content in flue gas 11 was introduced into contact with seawater, absorbed 12A as part of seawater 12, and by purification of flue gas 11, a dilute mixing bath 16 was provided collectively on the bottom of the desulfurise sorbent. In a dilution bath 16, seawater absorbed, the sulfur content 14A was produced by desulfurization using sea water, with the sulfur content in flue gas 11 reduced by In contact with seawater, 12A absorbed in a desulfurization agent against flu-gas 13, mixed / diluted using seawater, 12B dilution, fed into its main body 15, total 20A gas storage unit. To block 18 and first baffle 19, closure 18 was provided on the lower end of the side wall 17 of the desulfurization fluid-gas absorber 13 to be extended along the side. 16 to cover the first baffle 16 to cover the first baffle 19 hang from the side of the rear front end of the trim 18 and the end of the first baffle 19 is immersed under The surface of the sea water in a dilute bath 16 --------------------------------------- ---------

Claims (2)

Disclaimer (all) which will not appear on the advertisement page: EDIT 21/04/15 1. Desulfurization equipment. Desulfurization to flu-gas using sea water is included: De-sulfurization-to-flu-gaseous absorber with the sulfur content in the flue gas is exposed to Sea water by fluid-gas purification The dilution bath, which is provided collectively on the bottom of the desulfurization-to-flu-gas sorbent, and by seawater absorbing the sulfur content produced by desulfurization. By using sea water by volume The sulfur in the fluas is reduced by exposure to sea water in the desulfurization agent to flu-gas. It was mixed / diluted using seawater fed into its main body and the gaseous storage unit, including the first block and baffle, the enclosure was provided on the end. The lower part of the lateral wall of the desulfurization against flu-gas to cover the dilution bath, the first baffle hangs from the side of the rear surface of the enclosure. And one end of the baffle was submerged under The surface of the sea water in the dilution bath with length L1 from the side wall of the desulfurization agent to the flu-gas to the inner wall. The first baffle follows one of the following (1) and (2) inequalities and the following equation (3): dG1 < (Formula) 1U1 (dp) (1) Cc> C0e xp (-6Kg / dp (Formula) 1) (2) (Formula) 1 = L1 / UL (3) In the inequality and the above equation, dGI represents the The height of the opening from the first baffle at the exit. Of the gas storage unit to the lower part of the dilution bath, (formula) 1 represents the retention time of seawater in the gaseous storage unit, Ut (dp) represents the rising velocity at the tip of the bubble group with the bubble diameter of dp in sea water, Cc represents the environmental standard concentration SO2, C0 represents the SO2 concentration of the flue gas. The inlet of the desulfurization agent to the flu-gas, Kg represents the total coefficient of mass transfer of SO2 gas at the gas-liquid junction of the bubble, dp represents the bubble diameter and UL represents the rate. The outlet flows at the bottom of the dilution bath. 2. De-sulfurization apparatus against flu-gas using sea water according to claim 1, where the baffle The second was provided on the lower part of the dilution bath. 3. De-sulfurisation apparatus to flu-gas using sea water according to claim No. 2, where the length L2 from the side wall. Of the desulfurization agent to the flu-gas to the inner wall The second baffle follows one of the following inequalities (4) and (5) and the following equation (6): D < (Formula) 2Ut (dp) Cc> c0e xp (-6Kg l dp (formula) 2) (Formula) 2 = L2 l (UL x DldG3) In the inequality and the above equations, D represents the liquid depth of sea water. In the diluted mixing bath, (formula) 2 represents seawater retention time in the catchment unit, Ut (dp) represents the rising velocity at the end of the group. The bubble with the bubble diameter of dp in sea water, Cc represents the environmental standard concentration SO2, C0 represents the SO2 concentration of flu-gas at the inlet of the desulfurization-to-fluid-gas sorbent. , Kg represents the total coefficient of mass transfer of SO2 gas at the gas-liquid junction of the bubble, dp represents the bubble diameter, UL represents the outlet flow rate at the bottom of the dilution bath, and dG2 represents the liquid height between the surface of Sea water and second baffle 4. Desulfurization apparatus against flu-gas using sea water according to claim 1, where the baffle A third is provided on the inside of the containment unit 5. Desulfurization device to flu-gas using sea water according to claim 4, where length L3 from the wall. The outside of the third baffle until the inner wall of the first baffle goes According to one of the following inequalities (7) and (8) and equation (9) following DG1 < (formula) 3Ut (dp) Cc> C0e xp (-6Kg l dp (formula) 3. ) (SUT) 3 = L3 l (UL x D l MIN (dG1, dG2)) In the inequality and the above equation, dGI represents the height of the opening from the first baffle. Of the lower gas storage unit of the dilution bath, (formula) 3 represents the retention time of seawater in the gas storage unit, Ut (dp) represents the rising velocity at the tip of the diameter bubble group. In the frothy medium of dp in sea water, Cc represents the environmental standard concentration SO2, C0 represents the SO2 concentration of the flue gas. The inlet of the desulfurization agent to the flu-gas, Kg represents the total coefficient of transfer by mass of SO2 gas at the gas-liquid joint of the bubble, dp represents the bubble diameter, UL represents the rate flow The outlet at the bottom of the dilution bath, D represents the liquid depth of sea water in the dilution bath, dG3 represents the height between the ends of the third baffle. And the lower part of the dilution bath and MIN (dG1, dG3) represent the lowest values of dG1 and dG3 6. Desulfurization to flu-gas equipment using sea water according to claim 1, Also included: a second barrier, a second baffle on the lower part of the dilution bath, and a third baffle, a third baffle on the inside of the gas reservoir 7. The de-sulphaseisation to flu-gas using seawater according to claim 6, where length L4 from the outer wall of the third baffle to the inner wall of the second baffle is go According to one of the following inequalities (10) and (11) and the following equation (12): D < (formula) 4 Ut (dp) (10) Cc > C0e xp (-6Kg l. dp (formula) 4) (11) (formula) 4 = L4l (UL x D l MIN (dG1, dDG2, dG3)) (12) In the inequality and the above equations, D represents the liquid depth of seawater in the basin. Dilute mixture, (formula) 4 represents the retention time of seawater in the gas storage unit, U1 (dp) represents the rising velocity at the point. The tip of the bubble group, which has the bubble diameter of dp in sea water, Cc represents the environmental standard concentration So2, C0 represents the SO2 concentration of the fluid gas at the entrance of the desulfurization sorbent to the The fluid-gas, Kg represents the total coefficient of mass transfer of SO2 gas at the gas-liquid joint of the bubble, dp represents the bubble diameter, UL represents the outlet flow rate at the bottom of the dilution bath, dG1 represents the height of The opening from the first baffle to the bottom of the dilution bath, dg2 represents the liquid height between the seawater and the second baffle, dG3 represents the height of the opening from the second baffle. Three to the bottom of the dilution bath and MIN (dG1, dG2, dG3) represent the lowest values of dG1, dG2 and dG3. One of the rights No. 4 to 7, in which the air vents connect the gaps formed between the gas and seawater collector to De-sulfurization-to-flu-gas absorber formed on the third baffle 9. De-sulfurization-to-flu-gas device using sea water in accordance with claim No. 2. To any of the 8, where sea water is the emission emitted from the condenser 1 0.Disulfurization to flu-gas using sea water according to claim 2. To any one of the above, further compounded by the oxidation bath which is provided on the end of the dilution bath. And by the sulfur content in sea water mixed with sea water absorbed, the sulfur content in the diluted bath was Oxidized and dehydrated And by restoring the water quality of seawater 1 1. Seawater desulfurization system includes: A steam turbine boiler which uses the flue gas emitted by the boiler as the heat source for the Generate steam to drive the power generator with a fixed steam. A condenser that combines condensed water in a steam turbine to circulate the water. The denitration device to fluid-gas, which denitrates the gas emitted by the boiler. Dust collector equipment which reduces ash dust in the fluid gas. De-sulfurization apparatus to flu-gas using sea water in accordance with Clause 2 to 10, and a flue gas purge which flue gas is de-sulfur by desulphur equipment. Ferrisation to flu-gas was Letting the chest to the outside 1 2. De-sulphurized sea water treatment for protection against SO2 gas contained in sea water. Is used in desulfurization from outward discharge, using the desulfurization apparatus against Flu-gas using sea water in accordance with any of Clause 2 to 10. -------------------------------------------------- -----