广东电力
廣東電力
엄동전력
GUANGDONG ELECTRIC POWER
2014年
11期
36-40
,共5页
冯晓鸣%廖永进%徐齐胜%曾庭华
馮曉鳴%廖永進%徐齊勝%曾庭華
풍효명%료영진%서제성%증정화
选择性催化还原%喷氨格栅%偏差系数%优化
選擇性催化還原%噴氨格柵%偏差繫數%優化
선택성최화환원%분안격책%편차계수%우화
selective catalytic reduction%ammonia injection grid%deviation factor%optimization
正确的喷氨格栅优化调整能确保选择性催化还原(selective catalytic reduction,SCR)系统发挥最佳性能。列举了分区域控制式喷射格栅的水平布置和垂直布置两种布置形式,以某电厂600 MW机组 SCR 装置垂直布置的喷氨格栅优化试验为例,在氨、空气混合物对称转移原则基础上探讨了一种喷氨格栅分区域优化调节的方法,根据现场实际情况把喷氨格栅区域分割成18个小区域进行精细化调整。试验表明通过调节喷嘴喷氨量之间的差异性来耦合流场分布的差异性可使反应器出口烟气中NOx 浓度场的偏差系数达到15%左右,对改善反应器出口的NOx 浓度场的均匀分布是有效的。
正確的噴氨格柵優化調整能確保選擇性催化還原(selective catalytic reduction,SCR)繫統髮揮最佳性能。列舉瞭分區域控製式噴射格柵的水平佈置和垂直佈置兩種佈置形式,以某電廠600 MW機組 SCR 裝置垂直佈置的噴氨格柵優化試驗為例,在氨、空氣混閤物對稱轉移原則基礎上探討瞭一種噴氨格柵分區域優化調節的方法,根據現場實際情況把噴氨格柵區域分割成18箇小區域進行精細化調整。試驗錶明通過調節噴嘴噴氨量之間的差異性來耦閤流場分佈的差異性可使反應器齣口煙氣中NOx 濃度場的偏差繫數達到15%左右,對改善反應器齣口的NOx 濃度場的均勻分佈是有效的。
정학적분안격책우화조정능학보선택성최화환원(selective catalytic reduction,SCR)계통발휘최가성능。열거료분구역공제식분사격책적수평포치화수직포치량충포치형식,이모전엄600 MW궤조 SCR 장치수직포치적분안격책우화시험위례,재안、공기혼합물대칭전이원칙기출상탐토료일충분안격책분구역우화조절적방법,근거현장실제정황파분안격책구역분할성18개소구역진행정세화조정。시험표명통과조절분취분안량지간적차이성래우합류장분포적차이성가사반응기출구연기중NOx 농도장적편차계수체도15%좌우,대개선반응기출구적NOx 농도장적균균분포시유효적。
Correct optimization and adjustment on ammonia injection grid can ensure best performance of selective catalytic reduction system. Two layout forms of partition control AIG were introduced in this paper,horizontal layout and vertical layout. Taking one optimization experiment for vertical AIG of SCR device of 600 MW unit in some power plant as an ex-ample,a kind of AIG partition optimization and adjustment method was discussed based on symmetrical transfer principle for ammonia-air mixture which was to divide AIG area into 1 8 small areas for elaborate adjustment according to field situa-tion. Experiment indicated that by adjusting differences of ammonia spraying amount to realize coupling of differences of flow field distribution,it was able to make deviation coefficient of NOx concentration field in gas at reactor outlet reach a-bout 1 5% which might be effective to improve uniform distribution of NOx concentration field at the reactor outlet.
