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Selective non catalytic reduction (SNCR)
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- Bu səhifədəki naviqasiya:
- 2.2.6. Selective catalytic reduction (SCR)
- Fuel / boiler NOx control % NOx reduction Advantages Drawbacks
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2.2.5. Selective non catalytic reduction (SNCR)
SNCR is a postcombustion technique consisting in injecting ammonia or urea into combustion flue gases. A reaction with NOx occurs to produce nitrogen and water. There are not many experiences to evaluate effectiveness of this technique. 2.2.6. Selective catalytic reduction (SCR) SCR is another postcombustion technique consisting in injecting ammonia into the combustion zone in presence of a catalyst to reduce NOx into nitrogen and water. This method allows achieving NOx emission reduction by 75 to 90%. This technique is rather common. Both SNCR and SCR are influenced by sulfur content of the flue gas. The table below (table 2-1) summarizes available techniques for NOx control for process heaters. It uses information from the “Alternative Control Techniques Document - NOx Emissions from Industrial/Commercial/Institutional (ICI) Boilers” published by the US EPA. This table can help in a first approach for identifying the best technology to use in function of the type of boiler and the fuel. However, many other parameters are to be taken into account such as the NOx emissions threshold wanted, the budget, etc. 7 Fuel / boiler NOx control % NOx reduction Advantages Drawbacks Residual oil / watertube LNB 20 - 50 - Relatively inexpensive - Minimal furnace modification, retrofit feasible for old units - Many designs and vendors available. - Specific emissions data from industrial boilers with LNB are lacking. - Staged air burners could result in flame impingement on furnace walls of smaller units. FGR 4 - 30 - Available - Best suited for new units - Requires extensive modifications to the burner and windbox. - Possible flame instability at high FGR rates. SCA 5 - 50 - BOOS applicable for boilers with multiple burners only. - Retrofit is not feasible or not available for all design types. LNB + FGR N.A. LNB + SCA N.A. SNCR 40 - 70 - Commercially offered. - Not widely demonstrated on large boilers. - Elaborate reagent injection, monitoring, and control system required. - Must have sufficient residence time at proper temperature. SCR N.A. - Applicable to most boiler designs as a retrofit technology . - Available but not widely demonstrated. Distillate oil / watertube LNB 20 - 50 - New burners generally applicable to all boilers. - Comercially available. - Specific emissions data from industrial boilers equipped with LNB are lacking. FGR 20 - 68 - Available. - Best suited to new units. - Requires extensive modifications to the burner and windbox. - Possible flame instability at high FGR rates. SCA 17 - 44 - Limited application except BOOS, Bias and OFA for large watertube. LNB + FGR N.A. - Most common technique. LNB + SCA N.A. - Common technique. SNCR 40 - 70 - Commercially offered - Not widely demonstrated on large boilers. - Elaborate reagent injection, monitoring, and control system required. - Must have sufficient residence time at proper temperature. Natural gas / watertube WI 50 - 77 - Thermal efficiency loss of 0.5 to 2.5% and CO increase is expected. SCA 15 - 50 - BOOS applicable for boilers with multiple burners only. LNB 40 - 85 - Popular technique. Many designs and vendors available. - LEA LNBs more applicable to single-burner systems. - Staged air burners could result in flame impingement on furnace walls. FGR 50 - 75 - Requires extensive modifications to the burner and windbox. LNB + FGR 55 - 90 - Most popular technique for clean fuels. LNB + SCA N.A. - Applicable principally to multi-burner boilers. SNCR 10 - 40 SCR 80 – 90 - No data available. Residual oil / firetube LNB 30 – 60 - Staged air could result in operational problems. SCA 50 - Technique not practical unless incorporated in new burner design. Distillate oil/ firetube LNB 20 - 50 - Several designs are available. - Specific emissions data from industrial boilers with LNB are lacking. FGR 55 - 75 - Effective technique for clean fuels. - Requires extensive modifications to the burner and windbox. Natural gas / firetube SCA 5 - Technique not practical unless incorporated in new burner design. LNB 30 - 80 - Several designs are available. - Specific emissions data from industrial boilers with LNB are lacking. FGR 55 - 75 - Effective technique used in many applications. LNB + FGR N.A. - Most popular technique for very low NOx levels. Table A-2-1: Comparison of available techniques for NOx control for process heaters 8 2.3. Control techniques for SOx emissions reduction On the contrary to NOx, SO x emissions are directly linked to the initial sulfur content of the fuel and the combustion parameters do not influent on the amount of SOx emitted. Two strategies can be used to reduce SOx emissions: the formation prevention (low sulfur fuel usage, fuel desulfurization) or the flue gas desulfurization (wet or dry scrubbing, dual-alkali, spray drying, Wellman-Lord process, etc.). There are many postcombustion flue gas desulfurization techniques. Almost all techniques are based on the acid-alkaline reaction between SO 2 (and SO 3 ) and an alkaline agent such as often lime or limestone, caustic soda, magnesium hydroxide or ammonia. Other techniques are selective adsorption or absorption. Flue gas desulfurization is mostly used in thermal power plant. Few refineries have a flue gas desulfurization, except in Japan where principally dry processes are used. The principles of four major techniques are given below. Yüklə 0,62 Mb. Dostları ilə paylaş:
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