Explosive Behavior of CH4/C2H6/C3H8 Mixtures in the SAGD Process with CO2 Fusion Gases in Extra-Heavy Oil Reservoirs

Wang, Kan; Xue, Zhang; Zun, Zhou; Hu, Qianqian; Zhou, M.; Ji, Xing

doi:10.1007/s10553-022-01334-2

Cited by 1 publication

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“… 13 examined mixed fuels of methane/propane based on the flammability limit theory model, the flammability limits under high temperature and high-pressure coupling conditions were predicted, and the changing law of the flammability limits with temperature and pressure in a variety of environmental atmospheres was explored. Wang et al 14 investigated the explosion behavior of methane/ethane/propane gas mixtures and the inerting mechanism of carbon dioxide gas in a standard-designed 20 L spherical explosion vessel at ambient temperature and pressure. The results show that a small amount of ethane/propane can significantly intensify the explosion characteristics of methane, and the addition of carbon dioxide has a inerting effect on the explosion behavior of methane/ethane/propane, continuous carbon dioxide addition to the mixture resulted in a linear decline of the UFLs and exponential increase of the LFLs of methane/ethane/propane decreases linearly.…”

Section: Introductionmentioning

confidence: 99%

Experimental Study on Flammability Limits Behavior of Methane, Ethane, and Propane with Dilution of Nitrogen

et al. 2023

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The dilution inerting process of multi-component flammable gaseous mixtures is an important emergency disposal technology that has been widely applied in the explosion-proof field of flammability gases (vapors). In this study, we examined the flammability limits (LFLs and UFLs) of mono and binary alkane mixtures of methane, ethane, and propane when nitrogen is used for dilution inerting. The HY12474B explosion limit test device was used to determine the flammability limits, and the obtained data were compared with the literature data and Chatelier's law. Additionally, the sensitivity coefficient of the chemical reaction chain for LFLs and UFLs of the binary alkane mixtures was analyzed. The minimum inerting concentration (MIC) of methane was found to be sequentially higher than that of ethane and propane when using nitrogen for dilution inerting, and the MIC of the binary alkane mixtures follows the rule of methane/ethane > methane/propane > ethane/propane. Chemical kinetics calculation revealed that the maximum positive sensitivity coefficient of methane/ethane, methane/propane, and ethane/propane are both R5 H + O 2 ↔ O + OH, and the reaction with the maximum negative sensitivity coefficients are both R34 H + O 2 (+M) ↔ HO 2 (+M) and R43 CH 3 + H(+M) ↔ CH 4 (+M), respectively. The limiting oxygen concentration (LOC) for both mono alkane and binary alkane mixtures ranged between 10 and 13%. The region of the triangular flammability diagram for methane and ethane was greater than the regions for methane/ethane and methane/propane. In contrast, propane had a smaller region compared to other mono alkane or binary alkane mixtures.

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Section: Introductionmentioning

confidence: 99%