烷烃脱氢加热炉排烟余热深度回收协同烟压控制性能分析

炼化装置加热炉为石油炼化生产工艺中高能耗、高碳排放设备之一,但低温下烟气冷凝水会腐蚀换热设备,增设排烟余热回收换热设备还会增加烟气系统阻力,对生产工艺造成影响,降低加热炉燃烧效率。排烟余热回收利用系统的防腐、高效、低阻力及烟压控制是余热回收系统能效最大化技术难题。本文以炼化装置加热炉为对象,以烷烃脱氢加热炉为例,提出加热炉低温排烟余热深度回收协同炉膛烟压控制系统方案,采用自主研发的防腐、高效、低阻力排烟余热回收设备,建立加热炉低温排烟余热回收利用节能改造示范工程,并跟踪实测,将实测值与理论值进行对比。结果表明:该系统可将炉膛烟压控制在满足生产工艺要求范围内,控制精度达(-35±6.4)Pa;排烟温度由178.3~178.7℃降至54.3~78.7℃,系统节能率达4.75%~6.9%,烟气余热回收率达28.1%~40.4%,其中梯级换热比单级换热性能提高43.8%,(火用)效率可达52.8%~63.7%,并减少CO_(2)排放2884.5~4197.9t/a,且降低NO_(x)和SO_(2)等污染物排放,节能、减污、降碳效果显著。为炼化装置加热炉的排烟低温余热利用技术开发与应用提供了参考和示范。

Waste heat recovery and denitrification of flue gases from gas-fired boilers

A waste heat recovery and denitrification system was developed for improving energy conservation and emissions control especially for control of PM2.5 particles and haze. The system uses enhanced heat and mass transfer techniques in a packed heat exchange tower with self-rotation and zero-pressure spraying, low temperature NO oxidation by ozone, and neutralization with an alkali solution. Operating data in a test project gave NOx in the exhaust flue gas of less than 30 mg/Nm3 with an ozone addition rate of 8 kg/h and spray water p H of 7.5–8, an average heat recovery of 3 MW, and an average heat supply of 7.2 MW.