Lithologic Reservoirs ›› 2018, Vol. 30 ›› Issue (5): 154-160.doi: 10.12108/yxyqc.20180519

Previous Articles     Next Articles

Mechanism and influencing factors of foam mixed flowback of sand production

JING Ziyan1, ZHANG Jia2, LI Guobin1, ZHU Biao3, HAN Guoqing2, LIU Shuangshuang4   

  1. 1. PetroChina Research Institute of Petroleum Exploration & Development-Northwest, Lanzhou 730020, China;
    2. College of Petroleum Engineering, China University of Petroleum, Beijing 102249, China;
    3. Production Optimization, China Oilfield Services Limited., Tianjin 300450, China;
    4. Schlumberger(Beijing), Beijing 100084, China
  • Received:2018-03-20 Revised:2018-05-19 Online:2018-09-14 Published:2018-09-14

PDF (PC)

583

Abstract: With the increase of oil recovery,wellbore blockage in sandstone reservoir is becoming more and more serious. How to remove blockage and increase output has become a key issue of efficient development. From the angle of improving the permeability of oil layer to improve the production,many countries have generally adopted the methods of oil layer acidification and hydraulic fracturing to increase the oil recovery rate,but it also brings many negative problems,such as reservoir damage. Based on the mechanism of foam temporary support,state equation was used to deduce the change equation of formation pressure under the condition of foam compressibility,and study the influence of the main formation conditions and construction parameters under the condition of foam compressi-bility by combining the physical simulation experiment. The results show that gas liquid ratio, fracture,porosity and pressure drop are the main factors that affect the sand carrying capacity and the discharge of fine sand. This study can provide a theoretical and technical guidance for improving foam mixed flowback theoretical model and practical construction,and can help to improve single well recovery.

Key words: foam mixed flowback, mechanism research, simulation experiment, influencing factors, recovery ratio

CLC Number: 

  • TE358.1
[1] 张保康,徐国瑞,铁磊磊,等. "堵水+调剖"工艺参数优化和油藏适应性评价——以渤海SZ36-1油田为例. 岩性油气藏, 2017,29(5):155-161. ZHANG B K,XU G R,TIE L L,et al. Optimization of technological parameters and evaluation of reservoir adaptation by water plugging and profile control:a case from Bohai SZ36-1 oilfield. Lithologic Reservoirs,2017,29(5):155-161.
[2] 杨红,王宏. 油藏CO2驱提高采收率适宜性评价. 岩性油气藏,2017,29(3):140-146. YANG H,WANG H. Suitability evaluation of enhanced oil recovery by CO2 flooding. Lithologic Reservoirs,2017,29(3):140-146.
[3] PRICE B P,GOTHARD B. Foam assisted lift-importance of selection and application. SPE 106465,2007.
[4] YANG J,SIDDIQUI S. The use of foam to improve liquid lifting from low-pressure gas wells. Technical Meeting/Petroleum Conference of The South Saskatchewan Section,Regina Petroleum Society of Canada,1999.
[5] 崔桂胜,田延喜,樊娜. 泡沫混排解堵技术在孤北21区块的研究和应用.内江科技,2013(1):101-102. CUI G S,TIAN Y X,FAN N. Research and application of foam mixing and plugging technology in Gubei 21 block. Neijiang Science and Technology,2013(1):101-102.
[6] 曹小朋. 泡沫混排解堵的理论研究及应用.北京:中国石油大学(北京),2008. CAO X P. Theoretical study and application of foam plug removal technology. Beijing:China University of Petroleum(Beijing),2008.
[7] 李兆敏,王冠华,曹小朋.泡沫混排解堵技术研究与应用.西南石油大学学报(自然科学版),2010,32(2):178-181. LI Z M,WANG G H,CAO X P. Research and application of foam mixing and plugging technology. Journal of Southwest Petroleum University(Science & Technology Edition),2010,32(2):178-181.
[8] 王飞,李兆敏,李松岩,等.泡沫混排解堵数学模型及数值模拟.计算物理,2015,32(1):58-64. WANG F,LI Z M,LI S Y,et al. Mathematical model and numerical simulation of foam plug removal. Chinese Journal of Computational Physics,2015,32(1):58-64.
[9] EVREN M,OZBAYOGLU,STEFAN Z,et al. Cuttings transport with foam in horizontal & highly-inclined wellbores,SPE 79856,2003.
[10] 杨肖曦,李松岩,林日亿,等. 泡沫流体携砂能力的数值模拟. 中国石油大学学报(自然科学版),2006,30(3):89-92. YANG X X,LI S Y,LIN R Y,et a1.Numerical simulation for prop-carrying capacity of foam fluid. Journal of Southwest Petroleum University(Science & Technology Edition),2006,30(3):89-92.
[11] 李兆敏,李松岩,尚朝辉,等. 流速和环空偏心对泡沫携砂能力的影响数值模拟. 石油钻采工艺,2007,29(3):97-100. LI Z M,LI S Y,SHANG Z H,et al. Numerical simulation of the influence of velocity and annular eccentricity on the sand carrying capacity of foam. Oil Drilling & Production Technology,2007,29(3):97-100.
[12] 孙茂盛. 泡沫流体冲砂洗井数值模拟研究及应用.北京:中国石油大学(北京),2007. SUN M S. Study on horizontal well sand-flushing with foam fluid. Beijing:China University of Petroleum(Beijing),2007.
[13] SAINTPERE S,MARCILAT Y,BRUNI F,et al. Hole cleaning capabilities of drilling foams compared to conventional fluids. SPE 63049,2000.
[14] MARTINS A L,LOURENCO A M F. Foam property requirements for proper hole cleaning while drilling horizontal wells in underbalanced conditions. SPE 64382,2001.
[15] 范学平,徐向荣. 地应力对岩心渗透率伤害实验及机理分析. 石油勘探与开发,2002,29(2):117-119. FAN X P,XU X R. Experimental and mechanism research about permeability damage with the change of stress. Petroleum Exploration and Development,2002,29(2):117-119.
[16] OZBAYOGLU M E,KURU E,MISKA S Z,et al. Cuttings transport with foam in horizontal and highly inclined wellbores. SPE 79856,2003.
[17] 梅海燕,张茂林,任敏红,等.气驱起泡剂综合性能评价. 断块油气田,2006,13(1):26-28. MEI H Y,ZHANG M L,REN M H,et al. Comprehensive performance evaluation of gas drive foaming agent. Fault-Block Oil & Gas Field,2006,13(1):26-28.
[18] 郑力军,张涛,王兴宏,等.氮气泡沫驱油用起泡剂的筛选与评价.石油与天然气化工,2011,40(6):607-609. ZHENG L J,ZHANG T,WANG X H,et al. Screening and evaluation of foaming agent for nitrogen foam flooding. Chemical Engineering of Oil & Gas,2011,40(6):607-609.
[19] 杜立智,蔡玲玲,郑建辉,等.用混排工艺清洗注水管网.油气田地面工程,2011,30(1):60-61. DU L Z,CAI L L,ZHENG J H,et al. Cleaning water injection pipe network by mixing process. Oil-Gas Field Surface Engineering,2011,30(1):60-61.
[20] 皮彦夫.石英砂环氧树脂胶结人造岩心的技术与应用.科学技术与工程,2010,10(28):6998-7000. PI Y F. Technology and application of making artificial cores by the cementation of quartzite and colophony. Science Technology and Engineering,2010,10(28):6998-7000.
[21] 尹遵素. 人造砂岩的制备(一种环氧树脂方法)及其物理性质.江汉石油译丛,1990,18(1):15-18. YIN Z S. The manufacture(epoxy method) and physical properties of artificial rock sample. Jianghan Petroleum Renditions, 1990,18(1):15-18.
[22] 卢祥国,高振环,闫文华. 人造岩心渗透率影响因素试验研究.大庆石油地质与开发,1994,13(4):53-55. LU X G,GAO Z H,YAN W H. Study on the development of man-made core and the influencing factors of permeability. Petroleum Geology and development in Daqing,1994,13(4):53-55.
[23] 李芳芳,杨胜来,高旺来,等.大尺寸石英砂环氧树脂胶结人造岩心制备技术研究及应用.科学技术与工程,2013,13(3):685-689. LI F F,YANG S L,GAO W L,et al. The manufacturing methods of large size heterogeneity artificial cores. Science Technology and Engineering,2013,13(3):685-689.
[24] 杨筱璧.泡沫排水起泡剂室内实验优选.特种油气藏,2009, 16(2):70-71. YANG X B. Indoor experiment optimization of foam drainage agent. Special oil and Gas Reservoirs,2009,16(2):70-71.
[25] 梁万林.人造岩心制备技术研究.石油仪器,2008,22(2):72-76. LIANG W L. Research on artificial core preparation technology. Petroleum Instruments,2008,22(2):72-76.
[1] ZHAO Changhong, SUN Xinge, LU Yingbo, WANG Li, HU Pengcheng, XING Xiangrong, WANG Guiqing. Physical simulation experiment of steam chamber evolution in compound development of thin-layer ultra-heavy oil flooding and drainage [J]. Lithologic Reservoirs, 2023, 35(5): 161-168.
[2] QIAN Zhen, MAO Zhiqiang, ZHENG Wei, HUANG Yuanjun, CHEN Lifeng, ZENG Huiyong, LI Gang, SONG Ai. Experiment on profile control and water plugging of rubber particles in inter-well single fractured-vuggy reservoir [J]. Lithologic Reservoirs, 2023, 35(4): 161-168.
[3] MA Kuiqian, LIU Dong, HUANG Qin. Physical simulation experiment of steam flooding in horizontal wells of Neogene heavy oil reservoir in Lvda oilfield,Bohai Sea [J]. Lithologic Reservoirs, 2022, 34(5): 152-161.
[4] QU Tong, GAO Gang, XU Xinde, WANG Rui, GAN Jun, LIANG Gang, YOU Junjun. Simulation experiment of argillaceous sedimentary law of delta-shallow sea sedimentary system: A case study of Yanan Sag, Qiongdongnan Basin [J]. Lithologic Reservoirs, 2022, 34(1): 24-33.
[5] YAN Min, ZHAO Jingzhou, CAO Qing, WU Heyuan, HUANG Yanzhao. Reservoir characteristics of Permian Shihezi Formation in Linxing area,Ordos Basin [J]. Lithologic Reservoirs, 2021, 33(2): 49-58.
[6] HUANG Yun, YANG Dexiang, LI Yubang, HU Mingyi, JI Hancheng, FAN Jie, ZHANG Xiaofang, WANG Yuanjie. Reservoir characteristics and main controlling factors of Ordovician Yangshuiwu deep buried hill in Jizhong Depression [J]. Lithologic Reservoirs, 2021, 33(2): 70-80.
[7] LIU Xiuchan, CHEN Xipan, LIU Wei, WANG Xia. Influencing factors of dynamic imbibition displacement effect in tight sandstone reservoir and application [J]. Lithologic Reservoirs, 2019, 31(5): 114-120.
[8] YUAN Bochao, XIAO Wenhua, WEI Haoyuan, ZHANG Nan, DENG Yilin, ZHANG Guangwei. Characteristics and controlling factors of glutenite reservoir of Cretaceous Xiagou Formation in Ya' erxia area, Jiuquan Basin [J]. Lithologic Reservoirs, 2018, 30(3): 61-70.
[9] LI Min, WANG Hao, CHEN Meng. Distribution characteristics and influencing factors of movable fluid in tight sandstone reservoirs: a case study of Lucaogou Formation in Jimsar Sag,NW China [J]. Lithologic Reservoirs, 2018, 30(1): 140-149.
[10] CUI Zhouqi, LI Li, WANG Hongxia, WANG Yuanjie, GUO Liuxi, HOU Fengmei. Characteristics of deep sandstone reservoirs and lithologic reservoir exploration of Paleogene in Baxian Sag [J]. Lithologic Reservoirs, 2017, 29(2): 51-58.
[11] WANG Weibin, ZHU Jing, MA Wenzhong, FENG Shunyan, LIU Yanni, ZHAO Jing. Characteristics and influencing factors of Chang 8 tight sandstone reservoir of Triassic Yanchang Formation in Zhoujiawan area, Ordos Basin [J]. Lithologic Reservoirs, 2017, 29(1): 51-58.
[12] Kou Yu, Zhou Wen, Zhao Yinan, Chen Wenling, Li Na, Xu Hao. Adsorption characteristics,types and influencing factors of Chang 7 shale of Triassic Yanchang Formation in Ordos Basin [J]. Lithologic Reservoirs, 2016, 28(6): 52-57.
[13] LIU Shuangquan,CAO Yuanting,ZHAO Guangliang,ZHU Jun,SHI Ji’an,ZHANG Shuncun. Influencing factors of Carboniferous volcanic reservoir in Ludong-Wucaiwan area, Junggar Basin [J]. Lithologic Reservoirs, 2014, 26(5): 23-29.
[14] PAN Rong, ZHU Xiaomin, WANG Xingxing, ZHANG Jianfeng. Advancement on formation mechanism of deep effective clastic reservoir [J]. Lithologic Reservoirs, 2014, 26(4): 73-80.
[15] TANG Zhaoxing,CAO Zicheng,WANG Xinwen,SHA Xuguang. Reservoir characteristics and influencing factors in the inner Yingshan Formation in Guchengxu uplift,Tarim Basin [J]. Lithologic Reservoirs, 2013, 25(4): 44-49.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
[1] PANG Xiongqi,CHEN Dongxia, ZHANG Jun. Concept and categorize of subtle reservoir and problems in its application[J]. Lithologic Reservoirs, 2007, 19(1): 1 -8 .
[2] LEI Bianjun, ZHANG Ji,WANG Caili,WANG Xiaorong, LI Shilin, LIU Bin. Control of high r esolution sequence str atigr aphy on microfacies and reservoir s: A case from the upper Ma 5 member in Tong 5 wellblock, Jingbian Gas Field[J]. Lithologic Reservoirs, 2008, 20(1): 1 -7 .
[3] YANG Jie,WEI Pingsheng, LI Xiangbo. Basic concept, content and research method of petroleum seismogeology[J]. Lithologic Reservoirs, 2010, 22(1): 1 -6 .
[4] WANG Yan-qi1,HU Min-yi1,LIU Fu-yan1,WANG Hui1,HU Zhi-hua1,2. [J]. LITHOLOGIC RESERVOIRS, 2008, 20(3): 44 -48 .
[5] DAI Liming, LI Jianping, ZHOU Xinhuai, CUI Zhongguo, CHENG Jianchun. Depositional system of the Neogene shallow water delta in Bohai Sea area[J]. Lithologic Reservoirs, 2007, 19(4): 75 -81 .
[6] DUAN Youxiang, CAO Jing, SUN Qifeng. Application of auto-adaptive dip-steering technique to fault recognition[J]. Lithologic Reservoirs, 2017, 29(4): 101 -107 .
[7] HUANG Long, TIAN Jingchun, XIAO Ling, WANG Feng. Characteristics and evaluation of Chang 6 sandstone reservoir of Upper Triassic in Fuxian area, Ordos Basin[J]. Lithologic Reservoirs, 2008, 20(1): 83 -88 .
[8] YANG Shiwei, LI Jianming. Characteristics and geological significance of seismites[J]. Lithologic Reservoirs, 2008, 20(1): 89 -94 .
[9] LI Chuanliang, TU Xingwan. Two types of stress sensitivity mechanisms for reservoir rocks:Being favorable for oil recovery[J]. Lithologic Reservoirs, 2008, 20(1): 111 -113 .
[10] LI Jun, HUANG Zhilong, LI Jia, LIU Bo. The pool-forming pattern in the condition of arching in the southeast uplift in Songliao Basin[J]. Lithologic Reservoirs, 2007, 19(1): 57 -61 .
TRENDMD:

Copyright © 2018 Lithologic Reservoirs

Support by Beijing Magtech support@magtech.com.cn