日本地球惑星科学連合2014年大会

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セッション記号 M (領域外・複数領域) » M-IS ジョイント

[M-IS22_29PM1] ガスハイドレートと地球環境・資源科学

2014年4月29日(火) 14:15 〜 16:00 213 (2F)

コンビーナ:*戸丸 仁(千葉大学理学部地球科学科)、八久保 晶弘(北見工業大学環境・エネルギー研究推進センター)、森田 澄人(独立行政法人 産業技術総合研究所 地圏資源環境研究部門)、座長:八久保 晶弘(北見工業大学環境・エネルギー研究推進センター)、戸丸 仁(千葉大学理学部地球科学科)

14:15 〜 14:30

[MIS22-01] 第1回海洋産出試験実施地点におけるメタンハイドレートの地層評価と生産区間の選定

*藤井 哲哉1高山 徳次郎1鈴木 清史1山本 晃司1 (1.石油天然ガス・金属鉱物資源機構)

キーワード:メタンハイドレート, 海洋産出試験, 地層評価, 生産区間, 東部南海トラフ, 第二渥美海丘

In order to evaluate productivity of gas from marine methane hydrate (MH) by the depressurization method, on March 2013, the first offshore production test form MH concentrated zone (MHCZ) was conducted by the Research Consortium for Methane Hydrate Resource Development in Japan (MH21) at the AT1 site located in the north-western slope of Daini-Atsumi Knoll in the eastern Nankai Trough, Japan.Before the production test, during the pre-drilling campaign conduced in 2012, extensive geophysical logging and pressure coring using Hybrid Pressure Coring System were conducted at monitoring well (AT1-MC) and coring well (AT1-C), in order to obtain fundamental information about reservoir properties of MH bearing formation for reservoir characterization, and also to decide on the production interval. The MHCZ confirmed by the geophysical logging at AT1-MC has a thin-turbidite assemblage (from several tens of centimeters to a few meters) with 60 m of gross thickness; it is composed of lobe/sheet type sequences in the upper part, and relatively thick channel sand sequences in the lower part. The MHCZ at AT1-MC is thicker than those found in wells drilled in 2004 (β1, 45 m), which were located about 150 m northeast of MT1-MC. This fact indicates that the predictions provided by a seismic interpretation and an inversion analysis were reasonable. Moreover, we confirmed that the silt-dominant formation just above the MHCZ was more than 20 m thick ; this was expected to be a seal formation. The well-to-well correlation between two monitoring wells (AT1-MC and MT1) in a 40 m distance shows fairly good lateral continuity of these sand layers (upper part of MHCZ), indicating an ideal reservoir for the production test. In the upper part of the MHCZ, hydrate pore saturation (Sh) estimated from resistivity log showed distinct difference in value between sand and mud layers, compared to Sh from Nuclear Magnetic Resonance (NMR) log. Resistivity log has higher vertical resolution than NMR log, so it is favorable for these kinds of thin bed evaluation. In this part, 50 to 80% of Sh was observed in sandy layer. On the other hand, lower part of the MHCZ, Sh estimated from both resistivity and NMR log showed higher background value and relatively smoother curve than upper part. In this part, 50 to 80% of Sh was observed in sandy layer as well.On the basis of the above observations, a production interval was planed. When we consider an effective depressurization, the existence of sealing layers is critical both above and below the interval. We expect that thin silty layers within the lower part of MHCZ will serve as a sealing layer that will prevent water coning from water-bearing layers. Therefore, we stopped drilling the production well at about 20 m above BSR, and decided to produce from approximately 40 m from the top of the MHCZ.Our future (ongoing) work is to integrate reservoir characterizations based on well logs and pressure core data for the history matching of production test results.This study is a part of the program of the Research Consortium for Methane Hydrate Resources in Japan (MH21 Research Consortium).