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        3. [1]安濤,柴細元,陳寶,等.第59屆SPWLA年會綜述: 地層評價與測井技術新進展[J].測井技術,2018,42(06):612-621.[doi:10.16489/j.issn.1004-1338.2018.06.002]
           AN Tao,CHAI Xiyuan,CHEN Bao,et al.An Overview of the SPWLA 59th Annual Logging Symposium: Advances in Formation Evaluation and Logging Technology[J].WELL LOGGING TECHNOLOGY,2018,42(06):612-621.[doi:10.16489/j.issn.1004-1338.2018.06.002]
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          第59屆SPWLA年會綜述: 地層評價與測井技術新進展()
          分享到:

          《測井技術》[ISSN:1004-1338/CN:61-1223/TE]

          卷:
          第42卷
          期數:
          2018年06期
          頁碼:
          612-621
          欄目:
          綜述
          出版日期:
          2018-12-31

          文章信息/Info

          Title:
          An Overview of the SPWLA 59th Annual Logging Symposium: Advances in Formation Evaluation and Logging Technology
          文章編號:
          1004-1338(2018)06-0612-10
          作者:
          安濤1柴細元2陳寶2陳鵬2楊超登3金平陽4
          1.中國石油集團油田技術服務有限公司,北京100007;2.中國石油集團測井有限公司,陜西 西安710077;3.中國石油長城鉆探工程有限公司,北京100101;4.石油工業出版社,北京100011
          Author(s):
          AN Tao1CHAI Xiyuan2CHEN Bao2CHEN Peng2YANG Chaodeng3JIN Pingyang4
          1. CNPC Technical Service Company, Beijing 100007, China; 2. China Petroleum Logging CO. LTD., Xi’an, Shaanxi 710077, China; 3. CNPC Greatwall Drilling Company, Beijing 100101, China; 4. Petroleum Industry Press, Beijing 100011, China
          關鍵詞:
          巖石物理學家和測井分析家協會測井儀器新方法地層評價發展趨勢
          Keywords:
          SPWLA logging tool new methods formation evaluation the trend of international development
          分類號:
          P631.84
          DOI:
          10.16489/j.issn.1004-1338.2018.06.002
          文獻標志碼:
          A
          摘要:
          以第59屆巖石物理學家和測井分析家協會(SPWLA)年會105篇交流論文為基礎,對近一年來巖石物理與基礎理論研究、測井新儀器與新方法研發、復雜油氣藏及常規油藏、非常規油氣藏綜合評價技術等領域的最新發展,以及會議展覽、專題講座等內容進行了總結與分析。在此基礎上對測井方法、測井儀器、測井評價的國際發展趨勢進行了分析討論。
          Abstract:
          105 technical papers as well as products show, workshop and field trip on well logging and formation evaluation during SPWLA 59th annual logging symposium provide the base for tracing the latest advancement and finding the difference. The advances include the rsearch about petrophysics and basic theory, logging tools and new methods, comprehensive evaluation on complex reservoirs, conventional reservoirs and unconventional reservoirs. Then further discussion about the trend of international development on logging methods, logging tools and log evaluations is presented.

          參考文獻/References:

          [1]MALLAN K R, THORNE J, RICE P, et al. Petrophysical uncertainty analysis using spatial bootstrapping [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [2]NEWGORD C, GARCIA P A, ROSTAMI A, et al. Improved interpretation of electrical resistivity measurements in mixed-wet rocks: an experimental core-scale application and model verification [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [3]DAVIS L, ALLAN F, IBRAHIMOV R, et al. Applications of time lapse LWD to improve petrophysical interpretations and drive operational efficiencies [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [4]SKALINSKI M, MALLAN R, EDWARDS M, et al. Defining net pay cutoffs in carbonates using advanced petrophysical methods [C]∥SPWLA 59th Annual Logging Symposium, 2018.
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          [17]WANG H M, SHEN Q Y, CHEN J F. Sensitivity study and uncertainty quantification of azimuthal propagation resistivity measurements [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [18]THIEL M, OMERAGIC D. Azimuthal imaging using deep-directional resistivity measurements reveals 3D reservoir structure [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [19]MAESO C J, LEGENDRE E, HORI H, et al. Field test results of a new high-resolution, dual physics logging-while-drilling imaging tool in oil base mud [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [20]RONALD A, RABINOVICH M, WARD M, et al. Using directional LWD resistivity measurements to accurately place wells and reduce costs in complex turbidite formations [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [21]OSHIMA A, SYRESIN D, BLYTH M, et al. Advanced dipole shear measurements with a new logging while drilling sonic tool [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [22]WU H H, GOLLA C, PARKER T, et al. A new ultra-deep azimuthal electromagnetic LWD sensor for reservoir insight [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [23]VENKATARAMANAN L, EVIRGEN N, ALLEN D F, et al. An unsupervised learning algorithm to compute fluid volumes from NMR T1—T2 logs in unconventional reservoirs [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [24]DUARTE S B, CANDIDA M D J, VIVIANE F D S, et al. Artificial intelligence use to predict severe fluid losses in pre-salt carbonates [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [25]GLOVER P W J, LORINCZI P, AL-ZAINALDIN S, et al. Advanced fractal modeling of heterogeneous and anisotropic reservoirs [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [26]AKKURT R, CONROY T T, PSAILA D, et al. Accelerating and enhancing petrophysical analysis with machine learning: a case study of an automated system for well log outlier detection and reconstruction [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [27]BLOUNT A, MCMULLEN A, DURAND M, et al. Maintaining and reconstructing in-situ saturations: a comparison between whole core, sidewall core, and pressurized sidewall core in the Permian basin [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [28]GAN Z, GRIFFIN T, DACY J, et al. Fast pressure-decay core permeability measurement for tight rocks [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [29]MERKEL R, MCCHESNEY J, TOMPKINS K. Calculated determination of variable wettability in the Middle Bakken and Three Forks, Williston Basin, USA [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [30]JAGADISAN A, HEIDARI Z. Experimental Quantification of Kerogen Wettability as a Function of Thermal Maturity [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [31]MOHSIN L, ALSHUKAILI A, MAHESH A L, et al. Natih B carbonate source rock: resource assessment to production test [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [32]SHAO W, CHEN S H, EID M, et al. Robust macroporous dolomite pore typing and quantification with LWD T1 or wireline T2 intrinsic logs [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [33]ADOLE S, BOYLE K, SUN B Q, et al. Reducing the uncertainty of porosity, saturation and completions optimization with NMR logging while drilling, Agbami Field West Africa [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [34]KAUSIK R, FELLAH K, FENG L, et al. Temperature dependence of 2D NMR T1—T2 maps of shale [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [35]GARCIA A P, HAN Y, HEIDARI Z. An integrated workflow to estimate permeability through quantification of rock fabric using joint interpretation of nuclear magnetic resonance and electric measurements [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [36]HURSAN G, SILVA A S, ARAMCO S, et al. Slimhole NMR T1 logging while drilling enhances realtime petrophysics [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [37]ELSHAHAWI H, HUANG S, POLLOCK J. Novel smart cement for improved well integrity evaluatio [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [38]MOUSAVI M, SOZA E, HAN X G, et al. Petrophysical surveillance——the key drive in optimising wells performance [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [39]QUINTERO L F, WILSON G, NAJM E, et al. Identification of bypassed hydrocarbon through the integration of 3D resistivity imaging and pulsedneutron logging [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [40]ZHU D, HILL D, ZHANG S. Using tempreture measurements from production logging/downhole sensors to diagnose multistage fractured well flow profile [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [41]BUNCE J, LEONE A, FOGLIO G, et al. Production petrophysics in Liverpool Bay assets: the driver for a successful rejuvenation strategy [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [42]SELVEINDRAN A, CHEN P, BOSE S, et al. An integrated petrophysics driven CO2 EOR scoping study [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [43]JOHNSON A. Upscaling of satuation height functions [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [44]KOSANKE T, PERRY S, GREENE J, et al. High-resolution hyperspectral imaging technology: subsurface characterization through multi-discipline integration [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [45]SIMON M, TKABLADZE A, BEEKMAN S, et al. A revolutionary X-ray tool for true sourceless density logging with superior performance [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [46]NORBISRATH J H. Dielectric permeability logging [C]∥SPWLA 59th Annual Logging Symposium, 2018.
          [47]BACCIARELLI M, ROJAS P R, ELKINGTON P, et al. Focused nuclear magnetic resonance [C]∥SPWLA 59th Annual Logging Symposium, 2018.

          相似文獻/References:

          [1]岳登臺.以經濟效益為中心,推進技術進步,闖出油田開發生產測井儀器、設備發展新路——CNPC油田開發生產測井儀器設備研討會開幕詞[J].測井技術,1999,23(S1):483.
          [2]趙培華.加強技術攻關,搞好科學管理,闖出市場經濟下生產測井儀器設備發展之路——CNPC油田開發生產測井儀器、設備及應用研討會總結[J].測井技術,1999,23(S1):485.
          [3].插針式密封導線[J].測井技術,1977,01(02):12.
          [4]朱世和,李哲,周武,等.遼河測井公司固井質量評價技術[J].測井技術,2004,28(S1):13.
           ZHU Shi-he,LI Zhe,ZHOU Wu,et al.Cement Job Quality Evaluation Technology of Liaohe Wireline Services[J].WELL LOGGING TECHNOLOGY,2004,28(06):13.
          [5]本刊編輯部.國外測井儀器水平[J].測井技術,1978,02(01):86.
          [6]本刊編輯部.困難環境測井[J].測井技術,1978,02(02):70.
          [7].帶有若干串接杜瓦瓶的高溫測井儀器[J].測井技術,1978,02(02):76.
          [8]郝志興.蘇聯七十年代石油測井水平和發展方向[J].測井技術,1978,02(04):51.
          [9].測井技術現狀與展望[J].測井技術,1978,02(04):55.
          [10].測井設備高溫高壓試驗裝置[J].測井技術,1978,02(05):61.

          備注/Memo

          備注/Memo:
          第一作者:安濤,男,1962年生,教授級高級工程師,從事測井、射孔等技術管理工作。E-mail:[email protected]
          更新日期/Last Update: 2018-12-31
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