化工学报
化工學報
화공학보
JOURNAL OF CHEMICAL INDUSY AND ENGINEERING (CHINA)
2014年
6期
2232-2240
,共9页
周昊%张志中%鲍强%刘建成%岑可法
週昊%張誌中%鮑彊%劉建成%岑可法
주호%장지중%포강%류건성%잠가법
污染%NOxOUT%脱除特点%温室气体%N2O%添加剂%动力学%生成规律
汙染%NOxOUT%脫除特點%溫室氣體%N2O%添加劑%動力學%生成規律
오염%NOxOUT%탈제특점%온실기체%N2O%첨가제%동역학%생성규률
pollution%NOxOUT%removal characteristic%greenhouse gas%N2O%additive%kinetics%formation rule
通过试验研究了NOx污染的NOxOUT脱除特点和温室气体N2O及CO的生成规律,结合动力学分析,探讨了添加剂的作用。结果表明:在不同氨氮比(NSR)下,最佳反应温度为950℃,最高脱硝效率可达76.33%;N2O随温度的生成曲线类似于效率曲线,在950℃左右达到最大排放量;N2O的排放随NSR和氧量的增加而升高;温度较高时,N2O的排放随停留时间的延长先增加后减少;碳酸钠、乙酸钠、谷氨酸钠及乙醇可有效提高低温侧的脱硝效率和拓宽相应的温度窗口,其中谷氨酸钠最为明显;脱硝效率随钠盐添加量的变化与温度有关,钠原子最佳添加量为60μl·L-1;上述添加剂均可明显降低中高温段的N2O、CO排放,低温端则相反;N2O、CO的排放随温度、添加剂种类及浓度的不同而呈现各自的变化趋势。
通過試驗研究瞭NOx汙染的NOxOUT脫除特點和溫室氣體N2O及CO的生成規律,結閤動力學分析,探討瞭添加劑的作用。結果錶明:在不同氨氮比(NSR)下,最佳反應溫度為950℃,最高脫硝效率可達76.33%;N2O隨溫度的生成麯線類似于效率麯線,在950℃左右達到最大排放量;N2O的排放隨NSR和氧量的增加而升高;溫度較高時,N2O的排放隨停留時間的延長先增加後減少;碳痠鈉、乙痠鈉、穀氨痠鈉及乙醇可有效提高低溫側的脫硝效率和拓寬相應的溫度窗口,其中穀氨痠鈉最為明顯;脫硝效率隨鈉鹽添加量的變化與溫度有關,鈉原子最佳添加量為60μl·L-1;上述添加劑均可明顯降低中高溫段的N2O、CO排放,低溫耑則相反;N2O、CO的排放隨溫度、添加劑種類及濃度的不同而呈現各自的變化趨勢。
통과시험연구료NOx오염적NOxOUT탈제특점화온실기체N2O급CO적생성규률,결합동역학분석,탐토료첨가제적작용。결과표명:재불동안담비(NSR)하,최가반응온도위950℃,최고탈초효솔가체76.33%;N2O수온도적생성곡선유사우효솔곡선,재950℃좌우체도최대배방량;N2O적배방수NSR화양량적증가이승고;온도교고시,N2O적배방수정류시간적연장선증가후감소;탄산납、을산납、곡안산납급을순가유효제고저온측적탈초효솔화탁관상응적온도창구,기중곡안산납최위명현;탈초효솔수납염첨가량적변화여온도유관,납원자최가첨가량위60μl·L-1;상술첨가제균가명현강저중고온단적N2O、CO배방,저온단칙상반;N2O、CO적배방수온도、첨가제충류급농도적불동이정현각자적변화추세。
An experiment was performed to study the removal of NOx pollution and formation of greenhouse gas (N2O) and CO in NOxOUT process. Kinetic analysis was combined with the experiment results to discuss the effect of additives. The optimum reaction temperature was 950℃ and the highest denitration efficiency could reach 76.33%with different normalized stoichimetric ratios (NSR). The formation curves of N2O with temperature were similar to the efficiency curve and N2O emission reached a peak value at the temperature around 950℃. Increasing NSR and O2 concentration made N2O emission level higher. N2O emission first increased and then decreased with increasing residence time at higher temperatures (950℃,1000℃). Sodium carbonate, sodium acetate, sodium glutamate and ethanol could effectively improve the denitration efficiency on the low temperature side and extend corresponding temperature window, especially obviously for sodium glutamate. Denitration efficiency was related to temperature when altering the concentration of sodium salts and the optimum addition amount was 60μl·L-1 for sodium atom. Above-mentioned additives could all remarkably reduce the emission of N2O and CO at medium and high temperatures, but adversely at the end point of low temperature. N2O and CO emission presented respective variation trends with the differences of temperature, type and concentartion of additives.
