油气藏评价与开发 >
2020 , Vol. 10 >Issue 4: 113 - 118
DOI: https://doi.org/10.13809/j.cnki.cn32-1825/te.2020.04.018
轻质原油注空气热特征及氧化动力学研究
收稿日期: 2019-07-19
网络出版日期: 2020-08-07
Thermal characteristics and oxidation kinetics study of light crude oil during air injection process
Received date: 2019-07-19
Online published: 2020-08-07
为深入分析油藏注空气过程中原油的氧化热行为,进一步发展注空气提高原油采收率技术,采用热重/微商热重—差热联用(TG/DTG-DTA)分析手段进行研究,并基于经典的Arrhenius动力学模型定量地表征原油化学组成和储层岩石对氧化活性影响的大小。原油在整个升温过程中经历了三个化学机理完全不同的反应:低温氧化、燃料沉积和高温氧化。在低温度区间原油氧化表现出一定的吸热现象。由于不同的碳烃组成,三组原油在各个反应区域表现出不同的质量损失速率,与单独原油相比,储层岩石的加入降低了原油低温和高温氧化活化能。研究表明:重质组分含量越高,原油低温氧化反应速率越大,所沉积的燃料越多,高温氧化阶段燃烧释放的热量越强;原油在高温阶段的活化能大于低温阶段,高含量的重质组分使氧化反应活化能增大;储层岩石的催化特性和比表面积作用降低原油氧化活化能,起到非均相催化氧化的效果。
侯剑锋 , 刘鹏刚 , 曹廷义 . 轻质原油注空气热特征及氧化动力学研究[J]. 油气藏评价与开发, 2020 , 10(4) : 113 -118 . DOI: 10.13809/j.cnki.cn32-1825/te.2020.04.018
In order to deeply analyze the thermal oxidation behavior of crude oil during air injection process in reservoir and further develop air injection enhance oil recovery technology, the TG/DTG-DTA analysis methods were used for study. Based on the classical Arrhenius kinetic model, the effects of oil chemical composition and reservoir rock on the oxidation activity of tested samples were quantitatively characterized. Crude oil undergoes three completely different chemical reactions during the whole heating process: low-temperature oxidation, fuel deposition and high-temperature oxidation. The oxidation of crude oil at low temperature shows a certain endothermic phenomena. Because of different hydrocarbon composition, crude oil with three samples added show different mass loss rates in each reaction area. Compared with that only contains crude oil, the addition of reservoir rocks reduces the activation energy of low temperature and high temperature oxidation. Researches show that: the higher the content of heavier components, the quicker the reaction of crude oil in LTO stage, the more fuel is deposited, and the higher the heat released from the combustion in HTO stage. The activation energy of crude oil in the high temperature stage is greater than that in the low temperature stage. High content of heavy components make the activation energy of oxidation reaction increase. The catalytic properties and specific surface area of reservoir rock reduce the activation energy of crude oil, playing an important role in the heterogeneous catalytic oxidation.
Key words: light crude oil; thermal behavior; kinetic analysis; SARA component; rock minerals
| [1] | 蒲万芬, 袁成东, 金发扬 , 等. 轻质油藏高压注空气技术应用前景分析[J]. 科技导报, 2013,31(17):72-79. |
| [1] | PU W F, YUAN C D, JIN F Y , et al. High pressure air injection technique for light oil reservoir: Its development history and application prospect[J]. Science & Technology Review, 2013,31(17):72-79. |
| [2] | K?K M V . Characterization of medium and heavy crude oils using thermal analysis techniques[J]. Fuel Processing Technology, 2011,92(5):1026-1031. |
| [3] | K?K M V . Thermal behavior and kinetics of crude oils at low heating rates by differential scanning calorimeter[J]. Fuel Processing Technology, 2012,96(12):123-127. |
| [4] | GUNDOGAR A S, K?K M V . Thermal characterization, combustion and kinetics of different origin crude oils[J]. Fuel, 2014,123(2):59-65. |
| [5] | LIU P G, PU W F, NI J H , et al. Thermal investigation on crude oil oxidation kinetics through TG/DTG and DTA tests[J]. Petroleum Science and Technology, 2016,34(7):685-692. |
| [6] | 刘鹏刚, 蒲万芬, 贾虎 , 等. 岩屑存在下油藏注空气原油的氧化热解分析[J]. 燃烧科学与技术, 2015,21(5):464-470. |
| [6] | LIU P G, PU W F, JIA H , et al. Oil oxidation pyrolysis analysis of oil reservoir air injection in the presence of cutting[J]. Journal of Combustion Science and Technology, 2015,21(5):464-470. |
| [7] | 张永刚, 罗懿, 刘岳龙 , 等. 红河油田轻质原油低温氧化实验及动力学研究[J]. 油气藏评价与开发, 2013,3(6):43-47. |
| [7] | ZHANG Y G, LUO Y, LIU Y L , et al. LTO experiment and kinetics analysis of light crude in Honghe oilfield[J]. Reservoir Evaluation and Development, 2013,3(6):43-47. |
| [8] | FAN C, ZAN C, ZHANG Q , et al. The oxidation of heavy oil: thermogravimetric analysis and non-isothermal kinetics using the distributed activation energy model[J]. Fuel Processing Technology, 2014,119(6):146-150. |
| [9] | K?K M V, ACAR C . Kinetics of crude oil combustion[J]. Journal of Thermal Analysis and Calorimetry, 2006,83(2):445-449. |
| [10] | GREENSFELDER B S, VOGE H H, GOOD G M . Catalytic and thermal cracking of pure hydrocarbons: mechanisms of reaction[J]. Industrial and Engineering Chemistry, 1949,41(11):2573-2584. |
| [11] | MOTHé M G, CARVALHO C H M, SéRVULO E F C , et al. Kinetic study of heavy crude oils by thermal analysis[J]. Journal of Thermal Analysis and Calorimetry, 2013,111(11):663-668. |
| [12] | FASSIHI M R, MEYERS K O, BASILE P F . Low-temperature oxidation of viscous crude oils[J]. SPE Reservoir Engineering, 1990,5(4):609-616. |
| [13] | PU W F, LIU P G, JIA H , et al. Comparative study of light and heavy oils oxidation using thermal analysis methods[J]. Petroleum Science and Technology, 2015,13(33):1357-1365. |
| [14] | NI J H, JIA H, PU W F , et al. Thermal kinetics study of light oil oxidation using TG/DTG techniques[J]. Journal of Thermal Analysis and Calorimetry, 2014,117(3):1349-1355. |
/
| 〈 |
|
〉 |