Determination of time- and size-dependent fine particle emission with varied oil heating in an experimental kitchen
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- 作者:Shuangde Li1 ; sdli@ipe.ac.cn ; Jiajia Gao2 ; Yiqing He2 ; Liuxu Cao2 ; Ang Li2 ; Shengpeng Mo1 ; 3 ; Yunfa Chen1 ; yfchen@ipe.ac.cn ; chenyf@ipe.ac.cn ; Yaqun Cao2
- 关键词:Cooking fume ; Ultrafine particle ; Number concentration ; Size distribution ; Emission character
- 刊名:Journal of Environmental Sciences
- 出版年:2017
- 出版时间:January 2017
- 年:2017
- 卷:51
- 期:Complete
- 页码:157-164
- 全文大小:966 K
- 卷排序:51
文摘
Particulate matter (PM) from cooking has caused seriously indoor air pollutant and aroused risk to human health. It is urged to get deep knowledge of their spatial–temporal distribution of source emission characteristics, especially ultrafine particles (UFP < 100 nm) and accumulation mode particles (AMP 100–665 nm). Four commercial cooking oils are auto dipped water to simulate cooking fume under heating to 265°C to investigate PM emission and decay features between 0.03 and 10 μm size dimension by electrical low pressure impactor (ELPI) without ventilation. Rapeseed and sunflower produced high PM2.5 around 6.1 mg/m3, in comparison with those of soybean and corn (5.87 and 4.65 mg/m3, respectively) at peak emission time between 340 and 460 sec since heating oil, but with the same level of particle numbers 6–9 × 105/cm3. Mean values of PM1.0/PM2.5 and PM2.5/PM10 at peak emission time are around 0.51–0.66 and 0.23–0.29. After 15 min naturally deposition, decay rates of PM1.0, PM2.5 and PM10 are 13.3%–29.8%, 20.1%–33.9% and 41.2%–54.7%, which manifest that PM1.0 is quite hard to decay than larger particles, PM2.5 and PM10. The majority of the particle emission locates at 43 nm with the largest decay rate at 75%, and shifts to a larger size between 137 and 655 nm after 15 min decay. The decay rates of the particles are sensitive to the oil type.