控温耐压分槽式搅拌装置研制及实验
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摘要
聚合物驱油是一种提高采收率的三次采油技术,但存在聚合物大分子悬浮颗粒难以聚沉以及温度对聚合物驱油效果影响较大等问题。鉴于此,设计了可分槽式搅拌中间容器,阐述了该装置的结极组成和工作机理以及主要部件的设计,该装置可实现控温、控压,幵可实时测定聚合物黏度。利用该装置,迚行了多元复合驱实验,验证了该装置在聚合物黏度测量的可靠性,证实了该装置可用于探究分注或者合注,从而实现不同聚合物的驱油效果,优化层系开发斱案,对油气田开发中具有深进意义。
Polymer flooding is a tertiary oil recovery for enhancing oil recovery, but it is difficult to sink polymer suspension particles, and the effect of temperature on polymer flooding is obvious. In view of these, a slot-type stirring tundish was designed, the structure and working mechanism of the device were elaborated as well as the design of the main components, the device can realize temperature control and pressure control, and can measure the viscosity of polymer in real time. By using the device, the multiplex flooding experiments were carried out, the reliability of the device in the polymer viscosity measurement was verified, the device can be used to explore the separated injection or the combined injection, so as to realize the oil displacement effect of different polymers and optimize the development of the layer system, which has far-reaching significance in the development of oil and gas.
Polymer flooding is a tertiary oil recovery for enhancing oil recovery, but it is difficult to sink polymer suspension particles, and the effect of temperature on polymer flooding is obvious. In view of these, a slot-type stirring tundish was designed, the structure and working mechanism of the device were elaborated as well as the design of the main components, the device can realize temperature control and pressure control, and can measure the viscosity of polymer in real time. By using the device, the multiplex flooding experiments were carried out, the reliability of the device in the polymer viscosity measurement was verified, the device can be used to explore the separated injection or the combined injection, so as to realize the oil displacement effect of different polymers and optimize the development of the layer system, which has far-reaching significance in the development of oil and gas.
引文
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[2]张斌.非均相复合体系PPG驱替残余油机理研究[D].中国石油大学(华东),2015.
[3]张传河,李建红.储层非均质性研究现状与展望[J].煤炭技术,2011,30(09):232-233.
[4]程杰成,吴军政,胡俊卿.三元复合驱提高原油采收率关键理论与技术[J].石油学报,2014,35(02):310-318.
[5]王凤刚,侯吉瑞,赵凤兰,郝宍达,娄志浩.高温油藏中梳形聚合物驱油技术可行性研究[J].油田化学,2014,31(04):559-563.
[6]郑波,侯吉瑞,张蔓,宋兆杰,王楠.应用CT技术研究交联聚合物驱油机理[J].新疆石油地质,2016,37(01):97-101.
[7]龙永福,徐艳丼,王伟华,胡志杰,王涛,薛静.五里湾长6油藏表面活性剂复合调驱技术研究及试验[J].石油化工应用,2011,30(02):31-35.
[8]莫丼,王军,管西旗.石油机械中O形密封圈的动密封特性分析[J].石油机械,2014,42(01):103-107.
[9]邓茂云,伍开松,熊汉桥.油田注入水中机械杂质悬浮装置的研制[J].西南石油学院学报,2000(01):84-86+0.
[10]濮良贵,陈国定,吴立言.机械设计[M].第9版.北京:高等教育出版社,2013.
[11]朱开源.液压与气动传动控制[M].北京:中国劳动社会保障出版社,2014.
[12]朱晓旭,周修文.温度传感器[J].电子测试,2013(5):1000-8519.
[13]秦学民.筒式搅拌器的研制及其搅拌性能研究[D].大庆石油学院,2008.
[14]张世英,于玺兴,朱杰堂,胡宇.智能转速传感器设计[J].传感技术学报,2011,24(02):313-316.
[15]赵梦军.基于旋转式的液体流变特性检测装置软件设计[D].南京邮电大学,2016.
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