点汇聚系统的航空器污染物减排效应与机理

交通运输系统工程与信息 ›› 2021, Vol. 21 ›› Issue (5): 165-173.

点汇聚系统的航空器污染物减排效应与机理

胡荣^*，冯慧琳，刘博文，张军峰，王德芸

南京航空航天大学，民航学院，南京 211106

收稿日期:2021-06-23 修回日期:2021-08-31 接受日期:2021-09-01 出版日期:2021-10-25 发布日期:2021-10-21
作者简介:胡荣(1980- )，男，江苏扬州人，副教授，博士。
基金资助:
国家自然科学基金；南京航空航天大学研究生创新基地 (实验室)开放基金

Reduction Benefits and Mechanism of Pollutant Emissions from Civil Aircraft Based on Point Merge System

HU Rong^* , FENG Hui-lin, LIU Bo-wen, ZHANG Jun-feng, WANG De-yun

College of Civil Aviation, Nanjing University of Aeronautics and Astronautics, Nanjing 211106, China

Received:2021-06-23 Revised:2021-08-31 Accepted:2021-09-01 Online:2021-10-25 Published:2021-10-21
Supported by:
National Natural Science Foundation of China；Foundation of Graduate Innovation Center in NUAA

摘要/Abstract

摘要： 为研究点汇聚系统的环境效益及减排机理，采用考虑气象条件修正后的航空器性能、燃油流量及污染物计算模型，设计了理想条件下非高峰时刻与实际运行的高峰时刻两种场景，对比分析了航空器在点汇聚系统与标准进场程序中污染物(即HC、CO、NOX、SOX和PM)的排放情况，并从飞行时间、燃油消耗与排放指数3个方面分析了点汇聚系统的减排机理、识别了减排关键因素。研究发现：在非高峰时刻，点汇聚系统与标准进场程序的污染物排放总量分别为5.79 kg与7.17 kg，点汇聚系统较标准进场程序共减少约19.25%污染物排放，对NOX、SOX和PM减排效果显著；在高峰时刻，点汇聚系统与标准进场程序的污染物排放总量分别为290.01 kg与406.69 kg，点汇聚系统较标准进场程序共减少28.69%污染物排放，其中NOX减排比例最高可达48.32%。结果表明：无论是非高峰时刻还是高峰时刻，点汇聚系统都具有良好的环境效益，可有效减少污染物的排放总量，且对NOX减排效果最佳；较短的飞行时间、较低的燃油流量是点汇聚系统体现减排优势的关键驱动因素。

关键词: 航空运输, 环境效益, 修正模型, 点汇聚系统, 减排机理, 驱动因素

Abstract: To investigate the environmental benefits and pollutant emission reduction mechanism of the point merge system, this study introduced the models of aircraft performance, fuel flow, and pollutant emission calculation under two different operational conditions for off-peak and peak time, and compared the five pollutants (i.e., HC, CO, NOX, SOX, and PM) of the civil aircraft between the point merge system (PMS) and the standard instrument approach procedure (STAR). The pollutant emissions and their reduction mechanism of PMS were also analyzed from three different views of flight time, fuel consumption, and pollutant emission indices. The study found that: for the off-peak condition, the total pollutant emissions of the PMS and STAR were 5.79 kg and 7.17 kg, respectively; the PMS can reduce about 19.25% of total pollutant emissions than STAR, and the emission reduction of NOX, SOX and PM was significant; for the peak condition, the total pollutant emissions of the PMS and STAR were 290.01 kg and 406.69 kg, respectively; the PMS can reduce about 28.69% of total pollutant emissions than STAR, and the NOX emission reduction ratio can reach as high as 48.32%. The results show that the PMS has positive environmental benefits and can effectively reduce the total pollutant emissions; especially for NOX emission reduction; shorter flight time and lower fuel-flow rate are the key driving factors for the pollutant emission reduction of the PMS.

Key words: air transportation, environmental benefits, modified model, point merge system, emission reduction mechanism, driving factors

中图分类号:

U8
V355

胡荣, 冯慧琳, 刘博文, 张军峰, 王德芸. 点汇聚系统的航空器污染物减排效应与机理[J]. 交通运输系统工程与信息, 2021, 21(5): 165-173.

HU Rong, FENG Hui-lin, LIU Bo-wen, ZHANG Jun-feng, WANG De-yun. Reduction Benefits and Mechanism of Pollutant Emissions from Civil Aircraft Based on Point Merge System[J]. Journal of Transportation Systems Engineering and Information Technology, 2021, 21(5): 165-173.

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