日本地球惑星科学連合2018年大会

講演情報

[JJ] ポスター発表

セッション記号 S (固体地球科学) » S-CG 固体地球科学複合領域・一般

[S-CG64] 脆性延性境界と超臨界地殻流体:島弧地殻エネルギー

2018年5月21日(月) 13:45 〜 15:15 ポスター会場 (幕張メッセ国際展示場 7ホール)

コンビーナ:土屋 範芳(東北大学大学院環境科学研究科環境科学専攻)、浅沼 宏(産業技術総合研究所・再生可能エネルギー研究センター)、小川 康雄(東京工業大学理学院火山流体研究センター)

[SCG64-P10] Time-lapse approach for monitoring of change in the supercritical water zone during drilling operation and production

*笠原 順三1,4,5羽佐田 葉子1,2山口 隆志1三ケ田 均3高市 和義6 (1.エンジニアリング協会、2.大和探査(株)、3.京都大学、4.東京海洋大学、5.静岡大学、6.伊藤忠テクノソリューションズ(株))

キーワード:超臨界水、地震学的モニタリング、地熱エネルギー、フルウエーブインバージョン、DAS

Introduction

Due to increase of the energy consumption in Japan, the geothermal energy is getting one of the most important energy sources. The supercritical water is attracting world geothermal people as the future important renewable energy in the world. The critical point of pure water is 374 degree C and 22 MPa. In Kakkonda geothermal filed, the scientific drilling WD-1a in 1995 showed the temperature was >500°C at 3,800 m depth. Other areas in the world, there are many geothermal fields showing the circumstances close to supercritical point of water or above the critical point. There are several leading countries including Japan for this supercritical energy source. In Japan, NEDO is promoting the supercritical geothermal exploration as the future important energy source. The current technologies to know the physical status of deep geothermal zone are not many. We propose the seismic time lapse technology to monitor the temporal change of supercritical water zone.

Method of monitoring

The authors have worked on the time-lapse method for the monitoring of temporal changes in oil and gas reservoirs and CO2 storage (Kasahara and Hasada, 2016). In this approach, we used a stable seismic source and array of geophones. According to the supercritical CO2 or high temperature water injection in the reservoirs or production of oil or gas, the physical properties and locations of reservoirs could change, and they could change the nature of scattering of seismic waves from the reservoirs, and the change of scattering seismic waves could make the change of waveforms at receivers. Using reciprocity principle of Green’s function for the residual waveforms before and after the injection or production we can image the temporal change of reservoirs by the waveform inversion. We will use this approach to the temporal change of supercritical water caused by drilling and production. We propose to use downhole seismic source(s) and high temperature fiber optic DAS (Distributed Acoustic Sensors). DAS technology uses the backscattering of an input laser light due to strain caused by seismic waves. The DAS could provide huge sensor array at a few m spacing. The reciprocal principle suggests the trade of source(s) and receivers. By use of fiber optic receiver array provided by DAS technology, we could have extremely dense source array in the borehole(s).

Efforts toward time-lapse method for the supercritical geothermal exploration

To evaluate the quality of data provided by DAS, we carried out a comparison of geophone and 3C seismometer and DAS in the campus of the CRIEPI. We used fiber optic DAS equipment’s provided by Schlumberger hDVS technology. Because hDVS measures the strain rate cause by seismic waves, we calculated the strain rate from seismometer records and compared to DAS data for natural earthquakes in Japan. The results showed nearly identical waveforms between two (Kasahara et al., 2018a). For reconstruction of supercritical water zone, we developed the full-wave inversion technique (Kasahara et al, 2018b). By this method, the physical properties of Vp, Vs and density for the model at 4 km depth was nicely recovered.

Discussion and Conclusions

The combination of stable downhole seismic source, DAS technology and full-wave inversion will give new feature in the geothermal exploration, in particular supercritical water development. If we obtain information of physical property change during the drilling, we could the most appropriate decision for the next stop.

Acknowledgements

The DAS field test was funded by The Mechanical Social Systems Foundation. We express our great thanks to them for their financial support and kind assistances. The CRIEPI institute provided the test field, and we also express our great thanks to them for their kind assistances. This presentation is based on results obtained from a project commissioned by the New Energy and Industrial Technology Development Organization (NEDO).