| NO. |
Title |
Presented at
&
Date |
Author |
Project Team / Research Division |
| Abstract |
| 11476 |
CO2-EOR Injection Studies in Chicontepec Fields |
The Mexican Petroleum Congress, Monterrey 2008
2008/5/28-31 |
M. Abbaszadeh (IPS)、Kenji Ohno, Hirofumi Okano(Japan Oil, Gas and Metals National Corporation) |
Petroleum Engineering Research Division |
| [Abstract]Chicontepec fields are tight clastic deposits comprised of stacked turbiditic events with extreme geological and fluid heterogeneity. Huge reserves of oil are left behind because of loss of system energy by primary depletion; offering challengingopportunities for IOR/EOR processes. Detailed geostatistical geological reservoir models are first constructed and calibrated to the available primary and waterflood performance data for use as predictive tools for CO2-EOR in three simulated pilot sector models in the fields of Tajin and Agua Fria. Alternative fluid injections of water, associated gas, methane and flue gas are also considered in these studies. PVT and EOS analyses are provided to gauge MMP of CO2 and other fluid injectants with Chicontepec oils of varying hydrocarbon composition. Detailed studies on various CO2 injection scenarios investigate applicability and limitations of CO2-EOR and provide information when CO2-EOR could be beneficial. Continuous water and CO2 injection studies determine limiting values for injectivity and incremental recovery factors. WAG studies for mobility control determine optimum WAG ratio, considering limitations on CO2 availability and unfavorable fluid and rock characteristics. MMP studies illustrate the significance of variability in fluid PVT and the required injection pressure range for achieving miscibility through a dimensionless injection pressure parameter. Advantages and disadvantages of associated gas, methane and flue gas injections are demonstrated. CO2-WAG ratios of 1-3 are determined to be optimum. The CO2 utilization factor is less than 10 Mscf/bbl, indicating economic viability. EOR recovery factors in excess of 20% are possible for these tight rocks, depending on the PVT, MMP and geology of specific pilot sites. This high recovery efficiency is remarkable as contrasted with the 2-5% primary recovery factor established by 20-30 years of production history. Key parameters are identified that impact oil recovery factor. Flue gas and associated gas injections are found to act as pressure maintenance because they are immiscible with Chicontepec oils that contain higher percentages of heavy-end hydrocarbon fractions. This presentation shows factors and process mechanisms that influence oil recovery in Chicontepec reservoirs. It is shown how optimum CO2 application schemes are identified by conducting a suite of sensitivity studies, which contribute to a deeper understanding of how reservoir and fluid characteristics are combined for oil recovery expectations. These studies illustrate the potential of CO2-EOR technology as an optimized oil recovery plan, and open possibilities for future enriched CO2 injection for improved miscibility. |
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| 11468 |
Japanese National Programs on the Methane Hydrate Research |
6th International Workshop on Methane Hydrate Research & Development (Fiery ice)2008/5/13-16 |
Koji Yamamoto (Japan Oil, Gas and Metals National Corporation) |
Methane Hydrate Research Project Team |
| [Abstract]Japanese National Programs on the Methane Hydrate Research |
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| 11467 |
Resource Assessment of Methane Hydrate in the Eastern Nankai Trough, Japan |
6th International Workshop on Methane Hydrate Research & Development (Fiery ice)2008/5/13-15 |
Tetsuya Fujii, Tatsuo Saeki, Toshiaki Kobayashi, Takao Inamori, Masao Hayashi, Osamu Takano, Tokujiro Takayama, Tatsuji Kawasaki, Sadao Nagakubo, Masaru Nakamizu, Kenichi Yokoi (Japan Oil, Gas and Metals National Corporation) |
Methane Hydrate Research Project Team |
[Abstract]Resource assessment of methane hydrate (MH) in the Eastern Nankai Trough was conducted through probabilistic approach using 2D/3D seismic data and drilling survey data from METI exploratory test wells “Tokai-oki to Kumano-nada” We have extracted more than 10 prospective “MH concentrated zones” characterized by high resistivity in well log, strong seismic reflectors, seismic high velocity, and turbidite deposit delineated by sedimentary facies analysis.
The amount of methane gas contained in MH bearing layers was calculated using volumetric method for each zone. Each parameter, such as gross rock volume (GRV), net-to-gross ratio (N/G), MH pore saturation (Sh), porosiry, cage occupancy, and volume ratio was given as probabilistic distribution for Monte Carlo simulation, considering the uncertainly of these evaluations.
The GRV for each hydrate bearing zones was calculated from both strong seismic amplitude anomaly and velocity anomaly. Time-to-depth conversion was conducted using interval velocity derived from Seismic Vision While Drilling (SVWD). Risk factor was applied for the estimation of the GRV in 2D seismic area considering the uncertainly of seismic interpretation. The N/G was determined based on the relationship between LWD resistivity and grain size in zones with existing wells. Seismic ficies map created by sequence stratigraphic approach was also used for determination of the N/G in zone without well controls. Porosity was estimated using density log, together with calibration by core analysis. The Sh was estimated by the combination of density log and NMR log, together with the calibration by observed gas volume from onboard MH dissociation tests using Pressure Temperature Core Sampler (PTCS). The Sh in zone without well control was estimated using relationship between seismic P-wave internal velocity and Sh from NMR log at well location.
Total amount of methane gas in place contained in MH within survey area in the eastern Nankai Trough was estimated to be 40 tcf as Pmean value. Total gas in place for MH concentrated zone was estimated to be 20 tcf (Half of total amount) as Pmean value. Sensitivity analysis indicated that the N/G and Sh have higher sensitivity than other parameters, and they are important for further detail analysis.
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| 11466 |
Elastic Property Changes of Bitumen Reservoir during Steam Injection |
2008 CSPG CSEG CWLS Convention
2008/5/12 |
Ayato Kato, Shigenobu Onozuka (Japan Oil, Gas and Metals National Corporation), Toru Nakayama (Japan Petroleum Exploration Co.,Ltd.) |
Geology & Geophysics Research Division |
| [Abstract]Elastic property changes of oil sands reservoir during steam injection are poorly understood. We measured and analyzed ultrasonic velocities of the oil sands and then obtained a relation of the velocities with temperature and pressure individually. We also investigated validity of the Gassmann equation for predicting velocity changes and confirmed that the Gassmann equation can be applicable at temperatures greater than 80℃. We combined the laboratory measurement results to obtain a sequential rock physic model that can predict velocity changes induced by steam injection. We predicted elastic property changes during the steam injection according to the model. P-wave velocity is a relatively all-around player for distinguishing steam fronts, while S-wave velocity can be used only for distinguishing a gentle-warmed area. |
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| 11465 |
NOC-JOGMEC Joint Study on “Produced Water Treatment and Oily Soil Remediation” |
First International Petroleum Environmental Conference and Exhibition
2008/5/12 |
Hiroyuki Sekino (Japan Oil, Gas and Metals National Corporation) |
Petroleum Engineering Research Division |
[Abstract]1) JOGMEC has been conducting a joint study with Libya NOC regarding “Produced Water Treatment and Oily Soil Remediation” on a few selected oil fields (model site). The study team consists of topnotch specialists on water treatment, soil remediation, NORM survey, GIS and plant engineering. Based on the environmental site survey of evaporation ponds and produced water in the model site conducted as Phase 1 (October-December2007) of the study, findings and subsequent practical countermeasures will be presented in the final report at the end of Phase 2 (January-October 2008).
2) In the site survey conducted during Phase 1, utilizing hand-held instruments such as multi parameter water quality monitoring system, several parameters of surface water and soil including pH, electrical conductivity, etc. were measured at over 50 spots and 14 samples were collected and later analyzed chemically at LPI and laboratories in Japan.
3) In Phase 2, sample collection in trenchs/pits is planned to identify oil contamination mechanism. We will also research on internationally-accepted laws and regulations in relation to environmental protection and try to come up with appropriate countermeasures adoptable in Libya.
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| 11464 |
Extraction of methane hydrate concentrated zone for resource assessment in the Eastern Nankai Trough, Japan |
2008 Offshore Technology Conference
2008/5/7 |
Tatsuo Saeki, Tetsuya Fujii, Takao Inamori, Toshiaki Kobayashi, Masao Hayashi, Sadao Nagakubo, Osamu Takano (Japan Oil, Gas and Metals National Corporation) |
Methane Hydrate Research Project Team |
[Abstract]Aiming commercialization of methane hydrate development, the Research Consortium for Methane Hydrate Resources in Japan (MH21) has been executing geological and geophysical surveys around the eastern Nankai Trough since 2001 as a national project.
Interpretation and analysis studies based on 2D/3D reflection seismic surveys, multi-wells drilling campaign and other geological surveys revealed existences of methane hydrate concentrated zones, of which reservoirs were composed of turbidite sand layers. In the view of resource explorations, methane hydrate concentrated zones are more attractive than other methane hydrate bearing zones because they can reserve much amount of methane hydrate locally.
We developed an optimal interpretation workflow for delineation of methane hydrate concentrated zones. The workflow includes evaluation and integration of following four indicators: (A) BSR, (B) Turbidite sequence, (C) Strong seismic reflector and (D) relatively higher interval velocity. It enabled in the eastern Nankai Trough to extract more than 10 methane hydrate concentrated zones and evaluate their rock volume successfully.
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| 11463 |
Resource Assessment of Methane Hydrate in the Eastern Nankai Trough, Japan |
2008 Offshore Technology Conference
2008/5/7 |
Tetsuya Fujii, Tatsuo Saeki, Toshiaki Kobayashi, Takao Inamori, Masao Hayashi, Osamu Takano, Tokujiro Takayama, Tatsuji Kawasaki, Sadao Nagakubo, Masaru Nakamizu, Kenichi Yokoi (Japan Oil, Gas and Metals National Corporation) |
Methane Hydrate Research Project Team |
[Abstract]Resource assessment of methane hydrate (MH) in the Eastern Nankai Trough was conducted through probabilistic approach using 2D/3D seismic data and drilling survey data from METI exploratory test wells “Tokai-oki to Kumano-nada” We have extracted more than 10 prospective “MH concentrated zones” characterized by high resistivity in well log, strong seismic reflectors, seismic high velocity, and turbidite deposit delineated by sedimentary facies analysis.
The amount of methane gas contained in MH bearing layers was calculated using volumetric method for each zone. Each parameter, such as gross rock volume (GRV), net-to-gross ratio (N/G), MH pore saturation (Sh), porosiry, cage occupancy, and volume ratio was given as probabilistic distribution for Monte Carlo simulation, considering the uncertainly of these evaluations.
The GRV for each hydrate bearing zones was calculated from both strong seismic amplitude anomaly and velocity anomaly. Time-to-depth conversion was conducted using interval velocity derived from Seismic Vision While Drilling (SVWD). Risk factor was applied for the estimation of the GRV in 2D seismic area considering the uncertainly of seismic interpretation. The N/G was determined based on the relationship between LWD resistivity and grain size in zones with existing wells. Seismic ficies map created by sequence stratigraphic approach was also used for determination of the N/G in zone without well controls. Porosity was estimated using density log, together with calibration by core analysis. The Sh was estimated by the combination of density log and NMR log, together with the calibration by observed gas volume from onboard MH dissociation tests using Pressure Temperature Core Sampler (PTCS). The Sh in zone without well control was estimated using relationship between seismic P-wave internal velocity and Sh from NMR log at well location.
Total amount of methane gas in place contained in MH within survey area in the eastern Nankai Trough was estimated to be 40 tcf as Pmean value. Total gas in place for MH concentrated zone was estimated to be 20 tcf (Half of total amount) as Pmean value. Sensitivity analysis indicated that the N/G and Sh have higher sensitivity than other parameters, and they are important for further detail analysis.
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| 11446 |
Water, CO2-WAG and Flue Gas IOR/EOR Injection Pilot Studies in South Chicontepec Reservoirs, Mexico |
Second International Oil Congress and Exhibition in Mexico
2007/6/28-30 |
M. Abbaszadeh (IPS)、Kenji Ohno(Japan Oil, Gas and Metals National Corporation) |
Technology Research & Development Department |
| [Abstract]This paper presents results of water, CO2, CO2-WAG and flue gas injection simulation studies in sector models in the fields of south Chicontepec deposit complex. The paper first introduces a general methodology for integrated geostatistical reservoir characterization to construct fine-scale geocellular models of the reservoir, incorporating sources of data at different scales. Sector models for pilot injection studies are extracted from fine-scale geostatistical realizations, upscaled into coarse-grid simulation models and calibrated to production performance data to serve as reliable predictive tools for IOR/EOR recovery process scenarios. EOS analyses and slim-tube simulations are performed to evaluate MMP with CO2 of varying N2 impurity.
Detailed studies of various CO2 injection scenarios investigate applicability and limitations of CO2-EOR, and provide information on conditions under which CO2-EOR could be beneficial. Continuous water and CO2 injection studies determine limiting values of injectivity and incremental oil recovery factors. WAG studies for mobility control determine optimum slug size and WAG ratio, considering limitations on CO2 availability and excessive CO2 gas breakthrough. Flue gas, as an alternative fluid injection, is considered for EOR recovery process and pressure maintenance. Simulated recovery data indicates that flue gas injection is inefficient compared to waterflood and CO2-WAG injections, and that CO2-WAG injections at high pressures outperform waterflooding.
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| 11445 |
Physical modeling of overburden effects |
Geophysics Vol.72
2007/7 |
Mu Luo(JGI),Mamoru Takanashi(Japan Oil, Gas and Metals National Corporation), Kazuo Nakayama, Teruya Esaka(JGI) |
Geology & Geophysics Research Division |
| [Abstract]Physical modeling of overburden effects |
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| 11442 |
RISER MOTION ESTIMATION OF OIL PRODUCTION SYSTEM FOR ULTRA DEEP WATER |
FIFTH CONFERENCE ON BLUFF BODY WAKES AND VORTEX=INDUCED VIBRATIONS
2007/12/12-15 |
Shunji Kato, Shotaro Uto, Sotaro Masanobu(National Maritime Research Institute), Hideyuki Suzuki(Tokyo Univ.), Hiroaki Hirayama, Koji Mochida(Japan Oil, Gas and Metals National Corporation) |
Petroleum Engineering Research Division |
| [Abstract]RISER MOTION ESTIMATION OF OIL PRODUCTION SYSTEM FOR ULTRA DEEP WATER |
|
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| 11440 |
Fusion of 3D seismic exploration and seafloor geochemical survey for methane hydrate exploration |
Exploration Geophysics, 2007,38,1-6
2008/1 |
Sadao ngakubo, Toshiaki Kobayashi, Tetsuya Fujii, Takao Inamori(Japan Oil, Gas and Metals National Corporation) |
Methane Hydrate Research Project Team |
[Abstract]The MH21 Research Consortium has conducted a high-resolution 3D seismic survey and a seafloor geochemical survey, to explore methane hydrate reservoirs in the eastern Nankai Trough, offshore Japan. Excellent geological information about shallow formations was obtained from the high-resolution 3D seismic survey, which was designed to image the shallow formations where methane hydrates exist. The information is useful in constructing a geological and geochemical model, and especially to understand the complex geology of seafloor, including geochemical manifestations and the structure of migration conduits for methane gas or methane-bearing fluid.
By comparing methane seep sites observed by submersibles with seismic sections, some significant relationships between methane hydrate reservoirs, free gas accumulations below he seafloor, and seafloor manifestations are recognised.
Bathymetric charts and seafloor reflection amplitude maps, constructed from seismic reflections from the seafloor, are also useful in understanding the relationships over a vast area. A new geochemical seafloor survey targeted by these maps is required.
The relationships between methane hydrate reservoirs and seafloor manifestations are becoming clearer from interpretation of high-resolution 3D seismic data. The MH21 Research Consortium will continue to conduct seafloor geochemical surveys based on the geological and geochemical model constructed from high-resolution 3D seismic data analysis.
In this paper, we introduce a basis for exploration of methane hydrate reservoirs in Japan by fusion of 3D seismic exploration and seafloor geochemical surveys.
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| 11439 |
A Mathematical Model for the Formation and Dissociation of Methane Hydrates in the Marine Environment |
Journal of Geophysical Research, Vol.113, B01201
2008/1/12 |
Sabodh K. Garg, J. W. Prichett(Science Applications International Corporation), Arata Katoh(JGI), Kei Baba(JAPEX), Tetsuya Fujii(Japan Oil, Gas and Metals National Corporation) |
Methane Hydrate Research Project Team |
| [Abstract]A Mathematical Model for the Formation and Dissociation of Methane Hydrates in the Marine Environment |
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| 11436 |
Introduction of the 2007-2008 JOGMEC/NRCan/Aurora Mallik Gas
Hydrate Production Research Program, NWT, Canada |
2007 AGU Fall Meeting
2007/12/10-14 |
Koji Yamamoto, Masaaki Numasawa, Masato Yasuda, Kasumi Fujii, Tetsuya Fujii(Japan Oil, Gas and Metals National Corporation), Scott R Dallimore, J. Fred Wright, F. Mark Nixon (NRCan) |
Methane Hydrate Research Project Team |
| [Abstract]Introduction of the 2007-2008 JOGMEC/NRCan/Aurora Mallik Gas
Hydrate Production Research Program, NWT, Canada |
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| 11434 |
Research and Development Studies of the Mallik Gas Hydrate Deposit, Mackenzie Delta |
Geological Association of Canada Annual Meeting
2007/5/23-25 |
Scott R. Dallimore(NRCan), Kenichi Yokoi, Yutaka Imasato(Japan Oil, Gas and Metals National Corporation), A.Applejohn(Aurora Research Institute) |
Methane Hydrate Research Project Team |
| [Abstract]Research and Development Studies of the Mallik Gas HydrateDeposit, Mackenzie Delta |
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| 11431 |
Core Velocity Measurements of Oil Sands for Quantitative Interpretation of Seismic 3D Seismic Steam Front Monitoring. |
SEG Development & Production Forum "Heavy Oils"
2007/7/31 |
Shigenobu Onozuka, Ayato Kato(Japan Oil, Gas and Metals National Corporation), Toru Nakayama (JAPEX), Ray E. Nasen(JACOS) |
Geology & Geophysics Research Division |
| [Abstract]Core Velocity Measurements of Oil Sands for Quantitative Interpretation of Seismic 3D Seismic Steam Front Monitoring. |
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| 11416 |
Application of Oil-Water Kr/Pc Upscaling Methodology
Based on Pore-Type Ratios |
2007 International Symposium of the Society of Core
Analysts
2007/9/12 |
Kazuhito Oseto, Osamu Himeno, Makoto Watanabe, Toshinori
Nakashima(Japan Oil, Gas and Metals National Corporation) |
Petroleum Engineering Research Division |
[Abstract]Our methodology provides fast
and robust computation of upscaling by introducing a new
averaging technique as a part of the capillary limit method,
that is basically suited to giant, heterogeneous and oil
wet reservoirs. In our past studies, its effectiveness
was verified at core scale upscaling, i.e. pore scale
to core scale, as well as reservoir simulation scale upscaling,
i.e. fine model to coarse model. This paper introduces
a practical approach for upscaling which bridges the various
scales.
In this study, the reservoir rock from a giant carbonate
reservoir in the Middle East was characterized as the
aggregate of three Pore-Types. The representative Kr/Pc
curves for each Pore-Type were derived from core flood
simulation as a result of matching with water-oil displacement
tests. Then, Pore-Type Ratio, i.e. the population ratio
of each Pore-Type, was quantified by the geological observation
of the core slabs for the whole interval of the reservoir.
Based on the Pore Type Ratios, Kr/Pc curves were upscaled
to the simulation grid scale using an in-house software
called CAVLUP.
The simulation results showed that the Pore Type Ratio
model reasonably reproduced water cut performances without
any history matching manipulations. As a result, applied
methodology in this study demonstrated its effectiveness
to upscale pore scale data to reservoir simulation scale.
This advantage is suited especially to the upscaling of
big and heterogeneous geological models. |
|
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| 11415 |
Comprehensive Approach of Core Analysis to Predict Waterflooding
Performance in a Heterogeneous Carbonate Reservoir |
International Energy Agency Collaborative Project on
Enhanced Oil recovery
2007/9/7 |
Kazuhito Oseto, Komei Okatsu(Japan Oil, Gas and Metals
National Corporation) |
Petroleum Engineering Research Division |
[Abstract]The field of interest is a heterogeneous
carbonate reservoir, offshore Abu Dhabi. A pore system
in the field is classified into three categories based
on the pore throat size, i.e. Macropore, Mesopore and
Micropore. Such pore size variation is a key parameter
that controls oil/water displacement, especially when
imbibition/drainage processes can frequently take place
in a reservoir in conjunction with subsequent wettability
alteration.
This study deeply evaluates the cross-correlation between
the pore system, imbibition/drainage processes, wettability
alteration and oil recovery by integrative core analyses.
Two core waterflooding tests were conducted under different
wettability conditions, i.e. water wet and oil wet. The
oil recoveries were both high while there were some differences
in Swir. These similarity and differences can be explained
by different controls with different pore size in the
proposed pore system. |
|
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| 11413 |
Detailed analysis of methane hydrate concentrated zone of lobe type |
2007 AGU Fall Meeting
2007/12/11 |
Toshiaki Kobayashi, Tatsuo Saeki, Takao Inamori, Tetsuya Fujii, Naoyuki Shimoda(Japan Oil, Gas and Metals National Corporation) |
Methane Hydrate Research Project Team |
| [Abstract]Japan Oil, Gas and Metals National Corporation (hereinafter called JOGMEC), as a member of MH21 Research Consortium, takes charge of a study of the Research for Resources Assessment, and is pursuing a possibility that methane hydrate, which is presumed to be distributed around ocean area of Japan, will be energy resources. JOGMEC is currently conducting analysis of seismic data which was acquired by 3D seismic survey conducted from Tokai-Oki to kumano-nada in the eastern Nankai Trough by METI (Ministry of Economy, Trade and Industry )in 2002 under the national program of assessment for methane hydrates as energy resources. It was understood that methane hydrate was correlated to high resistivity and high velocity based on the results of drilling surveys and velocity analysis, and that methane hydrate concentrated zones can be roughly classified into the channel type and lobe type by seismic geomorphology because they were characterized with reserves consisting turbidite sand bodies. In this study, the detailed analysis of the inner structure of the methane hydrate concentrated zone of lobe type was conducted to understand the occurrence configurations of methane hydrates. The reflected waves that construct the methane hydrate concentrated zones in the seismic data were extracted and those reflected waves were classified into some groups every one reflector. As the result, some reflectors that construct the methane hydrate concentrated zones were revealed. Those reflectors show the layers including methane hydrates, and the detailed distribution of the methane hydrates in those layers was revealed by the intensity distribution of the amplitude. This time, we introduce the example of the detailed analysis of the methane hydrate concentrated zone in the lobe of submarine fan. |
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| 11412 |
Methane Hydrate reservoir model around the Eastern Nankai Trough area affshore Japan |
2007 AGU Fall Meeting
2007/12/10-14 |
Takao Inamori, Masao Hayashi, Toshiaki Kobayashi, Naoyuki Shimoda, Osamu Takano, Tokujiro Takayama, Tetsuya Fujii, Sadao Nagakubo, Tatsuo Saeki(Japan Oil, Gas and Metals National Corporation) |
Methane Hydrate Research Project Team |
| [Abstract]The Research Consortium for Methane Hydrate Resources in Japan (hereafter the MH21 Research Consortium) was established to undertake research in accordance with Japan's Methane Hydrate Exploitation Program. In 1996 and 2001, 2D seismic surveys were conducted and delineated the BSR distribution. The 3D seismic survey was conducted in this area in 2002. Bottom Simulating reflectors (BSRs) were widely found on the marine seismic data acquired in the shelf-slope in the Eastern Nankai Trough area. BSRs indicate the existence of methane hydrates. However, we cannot estimate detail reservoir information from distribution of BSRs. The gas hydrate-bearing sediments are heterogeneous and complex both vertically and horizontally, because methane hydrate-bearing layers are mainly turbidite sands - channel-levee or lobe sediments. The occurrence of methane hydrates was first confirmed by corings and borehole logging data around the Eastern Nankai Trough offshore Japan in 2000. METI conducted two drilling campaigns around the eastern Nankai Trough area. Total 38 boreholes were drilled, and recorded many logging data by wireline or LWD. We separate three types of methane hydrate reservoir among methane hydrate-bearing zone from reviewing the well logging data mainly the resistivity and P or S wave velocity. One is low saturation-type, the other is uncontinuous high saturation-type, the last is the continuous high saturation-type, and also we call the methane hydrate-concentrated zone as this type. If we will explore and exploit the methane hydrate, our main target is the continuous high saturation-type, as the methane hydrate-concentrated zone. We delineated the methane hydrate reservoir by the picking the reflector as the methane hydrate sub reservoir body for the turbidite channel-levee or lobe system around the eastern Nankai Trough area. On the other hand, we received the P or S wave velocity and the methane hydrate saturation at the wells in the methane hydrate-concentrated zone. We estimated the matrix-support or pore-filling model from the relationship between the P or S wave velocity and the methane hydrate saturation. |
|
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| 11411 |
Extraction of methane hydrate concentrated zone in the eastern Nankai Trough |
2007 AGU Fall Meeting
2007/12/10-14 |
Tatsuo Saeki, Tetsuya Fujii, Takao Inamori, Toshiaki Kobayashi, Masao Hayashi, Sadao Nagakubo, Osamu Takano(Japan Oil, Gas and Metals National Corporation) |
Methane Hydrate Research Project Team |
[Abstract]Methane hydrate, a solid compound formed from methane and water, occurs naturally in permafrost regions on-land and in deep continental slopes offshore and has been examined as future energy resources.
The existence of methane hydrate in the eastern Nankai Trough region, offshore Japan, was confirmed by drilling the MITI well "Nankai Trough" in 1999. Aiming commercialization of methane hydrate production, the Research Consortium for Methane Hydrate Resources in Japan (MH21) has been executing geological and geophysical surveys around the eastern Nankai Trough since 2001 as a nation project.
Interpretation and analysis studies based on 2D/3D reflection seismic surveys, multi-wells drilling campaign and other geological surveys revealed existence of methane hydrate concentrated zones, of which reserves were constructed with turbidite sand layers. In the view of resource explorations, methane hydrate concentrated zones are more attractive than other methane hydrate bearing zones because they can save much amount of methane hydrate locally.
We developed the geological interpretation workflow optimized for delineation of methane hydrate concentrated zones. The workflow consists of following 4 factors: (1) BSR interpretation, (2) Delineation of turbidite sand bodies, (3) Detection of Strong seismic reflectors suggesting methane hydrate concentrated sand layers, and (4) high density velocity analysis. It enabled in the eastern Nankai Trough to extract methane hydrate concentrated zones and evaluate their rock volume successfully. |
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| 11410 |
Origin and Migration of Gas in Gas Hydrate-bearing Sediments In the eastern Nankai Trough, Japan |
2007 AGU Fall Meeting
2007/12/10-14 |
Amane Waseda(JAPEX), Tetsuya Fujii(Japan Oil, Gas and Metals National Corporation) |
Methane Hydrate Research Project Team |
| [Abstract]Origin and Migration of Gas in Gas Hydrate-bearing Sediments In the eastern Nankai Trough, Japan |
|
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| 11409 |
Relation between methane hydrate -bearing formations and geological phenomena on the seafloor In the eastern Nankai Trough, Japan |
2007 AGU Fall Meeting
2007/12/10-14 |
Sadao ngakubo, Toshiaki Kpbayashi, Takao Inamori, Tatsuo Saeki, Naoyuki Shimoda, Tetsuya Fujii(Japan Oil, Gas and Metals National Corporation), Sumito Morita, Manabu Tanahashi(AIST) |
Methane Hydrate Research Project Team |
[Abstract]In 2002, a series of high-resolution 3D seismic surveys was conducted in the Tokai-Oki, the Daini-Atsumi Knoll, the Kumano-nada In the eastern Nankai Trough, Japan. Research Consortium for Methane Hydrate Resources in Japan(MH21) conducted resource assessment of methane hydrate In the eastern Nankai Trough by various seismic data analyses combining results of the exploratory wells conducted in 2005. By these analyses, occurrence of methane hydrate In the eastern Nankai Trough is coming to light.
The MH21 has also interpreted the relation between methane hydrate-bearing formations and various geological phenomena on the seafloor, such as pockmarks and carbonate outcrops, using the 3D seismic data in the three survey areas. Bathymetric maps and seafloor amplitude maps constructed by the high-resolution 3D data provided lots of information on the seafloor.
Some areas show very high intensity on the seafloor amplitude maps. It is expected that the areas showing strong amplitude correspond to the distribution of carbonate outcrops which are likely precipitated by methane seep activities.
By checking the seafloor amplitude maps, seismic sections and methane seep sites observed by the previous submersible dives, some significant correlations are recognized between methane hydrate-bearing formations and various phenomena on the seafloor. It may be likely that the occurrence of methane hydrate and the geological phenomena on the seafloor have a strong implication with some typical geologic structures, e.g. shallow fault, highly-permeable sediments and hydraulic fractures, which may control the fluid migration.
Besides, in this study we learnt that bathymetric map and seafloor amplitude map constructed by the high-resolution 3D seismic data are very useful not only for interpretation of relation between methane hydrate-bearing formation and various phenomena on the seafloor but also for designing the following seafloor investigations.
This study is conducted by the MH21. |
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| 11408 |
The particle size effect on Gas hydrate Formation in powdered silica particles |
2007 AGU Fall Meeting
2007/12/10-14 |
Tatsuji Kawasaki(Japan Oil, Gas and Metals National Corporation), Hailong Lu, John A.Ripmeester, Huang Zeng(National Research Council Canada), Tetsuya Fujii, Masaru Nakamizu(Japan Oil, Gas and Metals National Corporation) |
Methane Hydrate Research Project Team |
[Abstract]Based on the investigations in the past years, it has been recognized that methane hydrates in Nankai Trough primarily occur in turbidite sediments (Fujii et al. 2005; Uchida et al., 2005). Turbidite is composed of a set of sediments, generally becoming finer upward in particle size, from coarse sand to clay (Bouma, 1962). In natural environment the formation of methane hydrate will be inevitably subject to the influence of sediments, so the modes of gas hydrate formation and occurrence might be different in the sediments with various particle sizes and mineral compositions. The elucidation of this issue, how sediments affect methane hydrate formation and occurrence will help in efficient hydrate exploration, accurate estimation of hydrate reserve, and the design of hydrate production method.
In this research, we especially studied the particle size effect on the water conversion degree to hydrate using a set of powdered silica particles with the size from medium silt (<20 μm) to medium sand (250-500 μm). The test specimens were saturated with 3.5% NaCl solution, simulating the interstitial water of marine sediments, and reacted with methane gas at the pressure of 〜 10 MPa and temperature of 3 ℃. The water conversion degree to hydrate in a test specimen was estimated with the amount of gas that was clathrated in hydrate.
The obtained results indicate a clear relationship between water conversion degree to hydrate and particle size: only 3.2% when particle size is <20μm, increasing dramatically from 5.7% to 82.8% when particle size changes from 〜30μm(coarse silt ) to 〜200μm(fine sand), and almost stable at 〜80% when particle size is > 250μm (medium sand). Because the test materials are all silica, the difference in water conversion degree to hydrate should be resulted from physical properties of silica particle, specific surface area, and/or the property confined by silica particle, pore size.
This study was carried out as a part of Research Consortium for Methane Hydrate Resources in Japan(MH21). |
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| 11407 |
Resource Assessment of Methane Hydrate In the eastern Nankai Trough, Japan |
2007 AGU Fall Meeting
2007/12/10-14 |
Tetsuya Fujii, Tatsuo Saeki, Toshiaki Kobayashi, Takao Inamori, Masao Hayashi, Osamu Takano(Japan Oil, Gas and Metals National Corporation) |
Methane Hydrate Research Project Team |
[Abstract]Resource assessment of methane hydrate(MH) in the eastern Nankai Trough was conducted through probabilistic approach using 2D/3D seismic survey data and drilling survey data from METI exploratory test wells "Tokai-oki to Kumano-nada"[1,2,3]. We have extracted several prospective "MH concentrated layers (structures)" [4] characterized by high resistivity in well log, seismic high amplitude, seismic high velocity, and turbidite deposit by sedimentary facies analysis.
The amount of methane gas derived from MH bearing layers were calculated using volumetric method for each structure. Each parameter, such as Gross Rock Volume (GRV), net-to-gross ratio (N/G), MH pore saturation (Sh), porosity, cage occupancy, and volume ratio was given as probabilistic distributions for Monte Carlo simulation considering the uncertainly of these value.
GRV for each hydrate bearing structures was calculated from both strong seismic amplitude anomaly and velocity anomaly. Time-to depth conversion was conducted using interval velocity derived from SVWD (Seismic Vision While Drilling). Risk factor was applied for the estimation of GVR in 2D seismic area considering the uncertainty of seismic interpretation. N/G was determined based on the relationship between LWD resistivity and grain size in the structure with existing wells. 3 ohm-m was used for the typical cut off value for the net intervals. Seismic facies map created by sequence stratigraphic approach [5] was also used for the determination of N/G in the structure without well controls. Porosity was estimated using density log, together with the calibration by core analysis. Sh was estimated by combination of density log and NMR log (DMR method), together with the calibration using observed gas volume from onboard hydrate dissociation tests of PTCS (Pressure Temperature Core Sampler) [6]. Sh in the structure without well control was estimated using relationship between P-wave interval velocity and Sh from NMR log at well location. Cage occupancy was determined to be around 0.95 by refereeing recent field observations. Constant value of 172 in standard condition was used for volume ratio.
Total amount of methane gas in place contained in MH in the eastern Nankai Trough within survey area was estimated to be 40 tcf as Pmean value (10 tcf as P90 value, 82 tcf as P10 value). Total gas in place for MH concentrated layer was estimated to be 20 tcf (Half of total amount) as Pmean value. Sensitivity analysis indicated that sensitivity of N/G and Sh is higher than other parameters, and important for further detail analysis.
[1] Takahashi et al. (2005): Proc. of 2005 OTC, 2-5 May, Houston, Texas, U.S.A..
[2] Fujii et al. (2005): Proc. of 5th ICGH, Trondheim, Norway, 974-979.
[3] Tsuji et al. (2007): AAPG Special Publication (in press)
[4] Saeki et al. (2007): Abst. of 2007 Technical Meeting of the JAPT, June 5-7, 2007, Tokyo, p49.
[5] Takano et al. (2007): Abst. of 2007 Technical Meeting of the JAPT, June 5-7, 2007, Tokyo, p34.
[6] Fujii et al. (2007): AAPG Special Publication (in Press).
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| 11406 |
Turbidite channel as methane hydrate concentrated zone - study results of 3D seismic data interpretation - |
2007 AGU Fall Meeting
2007/12/10-14 |
Naoyuki Shimoda, Tatsuo Saeki, Takao Inamori, Toshiaki Kobayashi, Tetsuya Fujii(Japan Oil, Gas and Metals National Corporation) |
Methane Hydrate Research Project Team |
[Abstract]3D seismic data were acquired In the eastern Nankai Trough area, offshore Japan by METI in 2002 in order to evaluate resource potential of methane hydrates. Through the studies on these seismic data and the results of multi-well drilling surveys carried out in 2004, more than 10 methane hydrate concentrated zones were delineated in this area. The methane hydrate concentrated zones were characterized by turbidite sand bodies which can be roughly classified into channels and lobes in the seismic geomorphology point of view.
We focused our attempt to reveal internal structure of a channel type methane hydrate concentrated zone using high resolution 3D seismic data. Basically, channel complex can be recognized by reflectors suggesting erosion surfaces and internal bodies of sand layers. The whole channel is vertically divided to the upper and lower parts bounded by BSR. As it is difficult to interpret the internal structure in the lower part due to the less continuous reflectors, only the upper part was geomorphologically analyzed by picking the high amplitude reflectors which suggest the hydrate concentrated sand dominated bodies.
The group of the picked reflectors suggests the 3D feature of the channel development. The channel was bended during its sediment deposition. The original channel flowed from northeast to south. And later, the flow was from northeast to west-southwest. Thus, we can find the detailed shape of each sand dominated body within channel, and therefore, it is expected that detailed analysis of many reflector patches in the channel can teach us the properties of methane hydrate bearing thin sand dominated bodies by classifying their shapes. Further, such properties will contribute to the future precise volume estimation of methane hydrates, and also to the model construction for production simulation.
This study is carried out for Research Consortium for Methane Hydrate Resources in Japan (MH21). |
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| 11405 |
Numerical Simulation of Generation and Migration of Methane and Accumulation of Methane Hydrate In the eastern Nankai Trough |
2007 AGU Fall Meeting
2007/12/10-14 |
Ryosuke Aoyagi(Mizuho Information and Research Institute), Tetsuya Fujii(Japan Oil, Gas and Metals National Corporation), Minoru Yoshikawa, Yutaka Nakama(Mizuho Information and Research Institute), Tatsuji Kawasaki, Sadao Nagakubo, Tokujiro Takayama, Toshiaki Kobayashi, Takao Inamori, Masaru Nakamizu(Japan Oil, Gas and Metals National Corporation) |
Methane Hydrate Research Project Team |
[Abstract]We have developed 2-D numerical simulator "SIGMA-MH" for methane hydrate(MH) accumulation in order to simulate geological/physicochemical phenomena related to MH deposits formation in deepwater sediment and to clarify controlling factors for MH accumulation. SIGMA-MH is a modified version of "SIGMA-2D", basin simulator for petroleum system developed by JOGMEC. SIGMA-MH has models such as microbial methane generation model and MH formation/dissociation model, with which MH accumulation can be simulated.
An empirical model is used for microbial methane generation model. In this model, maximum gas generation rate is estimated from organic accumulation rate, which are derived from ODP gas sample analysis. Kinetic reaction model is applied for MH formation/dissociation. MH formation/dissociation rate is expressed as a function of the difference between the fugacity of methane at gas phase and fugacity of methane at the three-phase equilibrium for MH-water-methane gas.
Using SIGMA-MH, case studies were conducted for two sections including boreholes at Tokai-Oki and Daini-Atsumi area where MH concentration is detected.
Geological structure used in the simulation was estimated by seismic survey. Rock facies were determined by logging and core sample. Heat flow was calibrated by present temperature measured by geothermometer. Base case, shallow case, and deep case were conducted as a sensitivity analysis for paleo-water depth.
As a result, a series of recycling process, that is, methane gas generation, MH formation, MH dissociation, gas migration, and MH formation, was simulated. MH accumulation estimated by simulation nearly corresponds to that of actual borehole. The phenomena that methane gas migrates through permeable sand layers and MH accumulates in them suggests that permeability are a key of MH accumulation. It was found that paleo-water depth plays an important role because it affects on present MH accumulation.
For future work, we will conduct sensitivity analyses of quantitative parameters and paleo-water depth and improve SIGMA-MH as a tool for understanding controlling factors of MH accumulation.
This study was carried out as a apart of Research Consortium for Methane Hydrate Research in Japan(MH21). |
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| 11404 |
The Stabilization of Methane Hydrate by Pressurization with He or N2 Gas |
The Journal of Physical Chemistry
2007/12 |
Hailong Lu(National Research Council Canada), Yoshihiro Tsuji(Japan Oil, Gas and Metals National Corporation), John A. Ripmeester(National Research Council Canada) |
Geology & Geophysics Research Division |
| [Abstract]The behavior of methane hydrate was investigated after it was pressurized with helium or nitrogen gas in a test system by monitoring the gas compositions. The results obtained indicate that even when the partial pressure of methane gas in such a system is lower than the equilibrium pressure at a certain temperature, the dissociation rate of methane hydrate is greatly depressed by pressurization with helium or nitrogen gas. This phenomenon is only observed when the total pressure of methane and helium (or nitrogen) gas in the system is greater than the equilibrium pressure required to stabilize methane hydrate with just methane gas. The following model has been proposed to explain the observed phenomenon: (1) Gas bubbles develop at the hydrate surface during hydrate dissociation, and there is a pressure balance between the methane gas inside the gas bubbles and the external pressurizing gas (methane and helium or nitrogen), as transmitted through the water film; as a result the methane gas in the gas bubbles stabilizes the hydrate surface covered with bubbles when the total gas pressure is greater than the equilibrium pressure of the methane hydrate at that temperature; this situation persists until the gas in the bubbles becomes sufficiently dilute in methane or until the surface becomes bubble-free. (2) In case of direct contact of methane hydrate with water, the water surrounding the hydrate is supersaturated with methane released upon hydrate dissociation; consequently, methane hydrate is stabilized when the hydrostatic pressure is above the equilibrium pressure of methane hydrate at a certain temperature, again until the dissolved gas at the surface becomes sufficiently dilute in methane. In essence, the phenomenon is due to the presence of a nonequilibrium state where there is a chemical potential gradient from the solid hydrate particles to the bulk solution that exists as long as solid hydrate remains. |
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| 11403 |
Development and experimental feasibility study of the prediction method for hot corrosion of gas turbine components |
International Gas Turbine Congress 2007 Tokyo
2007/12/2 |
Hironori Kamoshida, Hideki Tamaki, Yoshitaka Kojima(Hitachi Research Lab.,Hitachi,Ltd.,), Tomoko Watanabe(Japan Oil, Gas and Metals National Corporation) |
Petroleum Engineering Research Division |
| [Abstract]Development and experimental feasibility study of the prediction method for hot corrosion of gas turbine components |
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| 11401 |
Pore space reconstruction of vuggy carbonates using microtomography and multiple-point statistics |
Water Resources Research Vol.43
2007/11/29 |
Hiroshi Okabe(Japan Oil, Gas and Metals National Corporation/Imperial College London), Martin J. Blunt(Imperial College London) |
Petroleum Engineering Research Division |
| [Abstract]To reconstruct complex porous media, such as carbonates, we propose a two-step approach to combine different types of images: microtomography at the resolution of a few microns to resolve large pores and vugs, with statistically reconstructed high-resolution images for smaller features. Two-dimensional (2-D) thin sections provide multiple-point statistics which describe the statistical relation between multiple spatial locations that can be used to generate 3-D images with accurate connectivity. These statistical reconstructions are combined with images directly measured by microtomography. The integrated method is tested on carbonates for which 3-D images of disconnected vugs are captured, while 2-D thin sections characterize the small-scale structure. The integrated images have permeabilities computed using the lattice Boltzmann method that are similar to laboratory-measured values. |
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| 11400 |
A Wave Propagation-based Method for Improved Seismic Fracture Prediction |
ASEG (Australian Society of Exploration Geophysicists)
2007/11/21 |
Mu Luo(JGI, Ink.), Mamoru Takanashi(Japan Oil, Gas and Metals National Corporation) |
Geology & Geophysics Research Division |
| [Abstract]Using physical model data, this study first physically confirms the significance of P-wave overburden effect, and most importantly, tests the wave-propagation based concept in developing our methodology to study fracture/anisotropy. The 70 m width of fractures in our model, comparing with a minimum offset of 600 m, was produced for conducting fracture study or clarify the observed anisotropy signatures (amplitude and velocity) originated from the fractured model. The model itself, comparing with the wavelength, is optimized for evaluating the fracture and the heterogeneous overburden effect. The vertical fractures contained in the model may be viewed as simplified fracture zone of randomly dispatched fracture swaps or carbonate/channel with fractures and anomalous amplitude and velocity, while the strong source radiation could represent a poor field acquisition. Nevertheless, test results indicate that the new method could identify interval/location of fracture-related velocity slowdown and amplitude attenuation. This will highly contribute to correct interpretation and prevent from misinterpretation of the layer below anomaly, which can be also helpful in the field examples. Another important indication is that the velocity anisotropy, normally considered higher along the fractures than perpendicular to the fractures, could not be true due to overburden heterogeneity.
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| 11399 |
Application of prestack depth migration across the Ichthys field, Browse basin |
ASEG (Australian Society of Exploration Geophysicists)
2007/11/21 |
Masamichi Fujimoto(INPEX Browse Ltd.), Mamoru Takanashi(Japan Oil, Gas and Metals National Corporation), Mike Szczepaniak, Takeshi Yoshida(INPEX Browse Ltd.)
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Research Project Team on Subsurface Technologies for Field Development |
[Abstract]This study aimed to reduce uncertainty of reservoirs’ depth and improve image quality in the Ichthys field, Browse Basin. The following method, detailed tomographic velocity modelling combined with prestack depth migration (PSDM), isotropic Kirchhoff PSDM and the well calibration were implemented.
Initial stacking velocity analysis for 3D prestack time migration (PSTM) revealed geologically implausible and undulating RMS velocity patterns at reservoir depths across the main section of the field, which reduced image quality and reservoir depth accuracy. Further investigation with forward modelling revealed that the velocity distortions might be primarily induced by shallow Tertiary sequences, containing highly contrasting, narrow, elongate velocity anomalies.
Layered/blocky modelling combined with dense residual moveout picking and 3D finite-offset tomography enabled the construction of a complex velocity model in the shallow section. Subsequent gridded/smoothed velocity tomography with constraints was then used for updating the entire velocity field.
The final derived velocity field was more systematically correlated with that observed at the wells and the corresponding depth structure produced from PSDM appeared to contain less distortion and be more geologically realistic. The resultant velocity model is currently being incorporated into the structural evaluation for the Ichthys Field.
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| 11398 |
Investigation of Overburden Heterogeneity Effects and Their Removal through High Resolution Tomography and Prestack Depth Migration
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ASEG (Australian Society of Exploration Geophysicists)
2007/11/21 |
Mamoru Takanashi(Japan Oil, Gas and Metals National Corporation), Dimitri Chagalov, Pierre Plasterie(CGGVeritas), Masamichi Fujimoto(INPEX Browse Ltd.)
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Research Project Team on Subsurface Technologies for Field Development |
[Abstract]For contributing to precise depth delineation in the Ichthys giant gas field offshore northwest Australia, we investigated shallow velocity heterogeneity effects using forward modelling and seismic data review. We discovered that their removal through applications of high-resolution tomographic velocity modelling and prestack depth migration (PSDM) enabled correct representation of the target reservoir structure. Analysis of synthetic seismic pre-stack gathers generated from forward modelling demonstrated that small velocity anomalies, such as channels, in shallow overburdens could give rise to apparent seismic RMS velocity artefacts at deeper target levels. Delineation of “true” velocity anomalies and implementation of PSDM using precise shallow velocity model were required for solving these problems.
In accordance with the phenomenon predicted by forward modelling, examination of coinciding patterns of time-thickness, amplitude and deep prestack time migration (PSTM) velocity allowed determination of the shallow heterogeneous layers that caused target velocity undulation. We employed two iterations of tomographic velocity model updating for PSDM velocity model building. First, the shallow heterogeneous velocity patterns were successfully identified by utilising the dense residual moveout picking and the layer-based 3D high-resolution finite-offset tomography. Subsequent grid-based global tomography with constraints was used for updating the entire velocity field and delivered stable velocity pattern at the deep. This two-step approach successfully eliminated deep velocity artefacts.
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| 11396 |
A Japanese perspective on the use of new technologies |
Windsor Energy Group Houston Meeting
2007/11/6 |
Yoshihiro Tsuj(Japan Oil, Gas and Metals National Corporation) |
Geology & Geophysics Research Division |
[Abstract]The importance of new technology in Exploration and Production to extend the reserves and high production rate is recognized. Therefore, associated with the recently published 'Japan's New National Energy Strategy' by the Ministry of Economy, Trade and Industry (METI), Technology and Research Center (TRC) of Japan Oil, Gas and Metals National Corporation (JOGMEC) has estimated the medium to long term R&D strategy toward 2030.
In order to identify the goals to be reached by 2030 in individual prioritized technological fields, "10 Core Projects" were proposed. Those are related to (1) EOR to have 70% oil recovery, (2) Reservoir total visualization for the accuracy of reserves assessment in exploration and development, (3) Offshore oil field development to the depth of 3000m, (4) Well drilling to increase the drilling and completion efficiency, (5) Next-generation advanced resource development to find out technological breakthrough through incorporating leading-edge technologies such as IT, robotics, nanotechnology and biotechnology, (6) National methane hydrate project from exploration to development of methane hydrate, (7) Ultra heavy oil by incorporating upgrading and other technologies into oil-field development upstream technologies, (8) Next-generation Non-conventional Hydrocarbon Exploitation to develop enhanced coal bed methane (ECBM) technology and other next-generation technologies after the SAGD process, (9) GTL using the Japanese GTL process utilizing CO2 effectively, and (10) Next-generation oil and gas effective utilization by establishing new natural-gas transportation technology.
To make the goals of the projects fruitful, JOGMEC-TRC recognizes that training of the participating engineers and geoscientists within the project, cooperation and collaboration with Universities, National Oil Countries, Technological consultants, other R&D institutes, oil companies, and utilizing the field demonstration are very important, and it is committed to the technological advancement in the world of petroleum exploitation.
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| 11392 |
DIRECT SYNTHESIS OF PROPANE/BUTANE FROM SYNGAS |
LP Gas Global Technology Conference 2006
2007/10/19-20 |
Kaoru Fujimoto(Tha University of Kitakyushu) |
Research Project Team on Emerging Gas Technologies |
| [Abstract]DIRECT SYNTHESIS OF PROPANE/BUTANE FROM SYNGAS |
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| 11390 |
Mitigation of Asphaltene Deposition Problems |
SPE Applied Technology Workshop(ATW) "Second Stage Field Development"
2007/10/17 |
Hideharu Yonebayashi(Japan Oil, Gas and Metals National Corporation) |
Research Project Team on Subsurface Technologies for Field Development |
| [Abstract]Mitigation of Asphaltene Deposition Problems |
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| 11389 |
Methane Hydrate Exploration around the eastern Nankai Trough |
The 37th Annual Conference of the Underwater Mining Institute
2007/10/15-17 |
Tatsuo Saeki, Tetsuya Fujii, Masaru Nakamizu, Kenichi Yokoi(Japan Oil, Gas and Metals National Corporation) |
Methane Hydrate Research Project Team |
[Abstract]Methane hydrate, a solid compound formed from methane and water, occurs naturally in permafrost regions on-land and in deep continental slopes offshore and has been examined as future energy resources. The existence of methane hydrate In the eastern Nankai Trough region, offshore Japan, was confirmed by drilling the MITI well “Nankai Trough” in 1999. Aiming commercialization of methane hydrate production, the Research Consortium for Methane Hydrate Resources in Japan (MH21, core associations: JOGMEC[*1], AIST[*2] and ENNA[*3]) under METI [*4] has been executing geological and geophysical surveys around the eastern Nankai Trough since 2001 as a nation project.
*1: Japan Oil, Gas and Metals National Corporation
*2: National Institute of Advanced Industrial Science and Technology
*3: Engineering Advancement Association of Japan
*4: Ministry of Economy, Trade and Industry, originally MITI
Interpretation and analysis studies based on reflection seismic survey (2D:2001, 3D:2002), multi-wells drilling campaign (2004) and other geological surveys revealed existences of methane hydrate high concentrated zones, which are much attractive in the view of resource explorations. The concentrated zones are recognized in geological layers with porous sediments, which are turbidite sand layers in most cases.
The JOGMEC Geology & Geophysics group and partners developed the geological interpretation workflow optimized for methane hydrate resource assessment including delineation of methane hydrate concentrated zones, and evaluated resource potential around the eastern Nankai Trough.
In this presentation, we will introduce the outline of above surveys and interpretations.
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| 11388 |
Multidisciplinary Approach to Solve Borehole Instability Problems in a Shale Formation |
SPE Applied Technology Workshop(ATW) "Second Stage Field Development"
2007/10/15 |
Hirofumi Okano, Daisuke Kuramoto, Koji Yamamoto(Japan Oil, Gas and Metals National Corporation) |
Petroleum Engineering Research Division |
| [Abstract]Wellbore failures occur, when stress on wellbore exceeds the rock strength. Shale is the major source of instability, because it has a complex nature which we cannot describe using linear elastic, isotopic and homogeneous models. In this paper, we clarified the characteristics such as chemical activity, anisotropy and fissured nature. In addition, 3D proelastic models were used to estimate failed regions. The results of the numerical simulations showed that the hole conditions cannot be improved with too much weight of drilling mud.
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| 11387 |
Gas to Wire System (GTW) for Developing "Small Gas Fields" and Exploiting "Associated Gas" |
SPE Applied Technology Workshop(ATW) "Second Stage Field Development"
2007/10/15 |
Tomoko Watanabe, Hirofumi Okano, Daisuke Kuramoto(Japan Oil, Gas and Metals National Corporation) |
Petroleum Engineering Research Division |
| [Abstract]A Gas to Wire system (GTW) is proposed as a new development concept for marginal gas fields. The aim of this project is to commercialise small stranded gas fields with a reserve between 10 bcf and 1tcf. GTW adopts onsite power generation utilising produced gas and has high efficiency, because there is no need to transport the produced gas. JOGMEC, Hitachi, JGC Corporation, Toyohashi University of Technology, and Arabian Oil Company conducted the research on high efficiency, low cost and low emission GTW by applying Gas Turbine Combined Cycle System (GTCC). The project includes a feasibility study on associated gas from a Middle East offshore oil field.
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| 11386 |
Geochemical Study of Microbial Methanogenesis and Gas Hydrate Formation |
International Conference on Gas Hydrate
2007/10/5 |
Amane Waseda(JAPEX), Tetsuya Fujii(Japan Oil, Gas and Metals National Corporation) |
Methane Hydrate Research Project Team |
| [Abstract]Geochemical Study of Microbial Methanogenesis and Gas Hydrate Formation
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| 11379 |
High pressure air injection into light oil reservoirs: experimental study on artificial ignition |
International Energy Agency Collaborative Project on Enhanced Oil Recovery
2007/9/5 |
Takeshi Onishi(Japan Oil, Gas and Metals National Corporation), Katsumi Katoh(AIST)、Katsumo Takabayashi, Hiroshi Uematsu(Teikoku Oil Co.,Ltd.,), Komei Okatsu(Japan Oil, Gas and Metals National Corporation), Yuji Yada, Yuji Ogata(AIST) |
Petroleum Engineering Research Division |
[Abstract]Recently, High Pressure Air Injection (HPAI) is considered to be an effective EOR method to light oil reservoirs. HPAI has some remarkable merits as follows. (1)Injection gas source can be supplied anywhere for free. (2)Initial cost is relatively inexpensive because the main facility required is only air compressor. (3)The method can be applied even in low permeable reservoirs where water cannot be injected. On the other hand, the evaluation of HPAI is difficult, because the mechanism and the reactions of oxidation and combustion are complicated.
A Japanese domestic oil field has been investigated to apply HPAI as tertiary mode. Experimental and numerical simulation results suggest that it is possible to obtain the incremental oil recovery by HPAI. But they also suggest that the ignition temperature of the oil may be higher than the reservoir temperature. If ignition doesn’t occur in reservoir, thermal effect on recovery mechanism can not be expected and oxygen may be early breakthrough to producer because of low oxygen consumption. So, oxygen consumption is important not only for the efficiency of incremental oil recovery but also for safety operation. Ignition method has to be ensured for the application of HPAI to the oil field.
Accelerating Rate Calorimeter (ARC) Tests are carried out to assess the influence of oxygen slug and linseed oil on ignition temperature. The experimental results suggest that in case of oxygen slug the ignition temperature decreases but doesn’t reach the reservoir temperature even if high concentration of oxygen is applied. They also suggest that the ignition temperature decreases to the reservoir temperature in case of high concentration of linseed oil. |
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| 11378 |
Wettability evaluation by big borehole MRI |
International Energy Agency Collaborative Project on Enhanced Oil Recovery
2007/9/5 |
Yasuyuki Mino, Kazuhito Oseto (Japan Oil, Gas and Metals National Corporation) |
Petroleum Engineering Research Division |
[Abstract]It is difficult to predict fluid flow through heterogeneous reservoir rocks such as carbonates without knowing detail distributions of petrophysical properties of the rocks. Among those properties the wettability is of particular importance, however, any methods currently do not provide its spatial distribution. Magnetic Resonance Imaging (MRI) is expected to provide such a wettability distribution rapidly comparing to the Amott and USBM methods. We use a medical MRI machine with a big borehole that can handle bigger samples and subsequently provides a whole picture of the core sample. However, there have been very few studies conducted to investigate the correlation between the MRI signals and the wettability using such big borehole machines while several researchers have used small borehole machines.
In our study, the correlation between the T1 relaxation time and the wettability was investigated although further studies are necessary to obtain the wettability index in detail. |
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| 11377 |
Recent Activities of R&D Program on Methane Hydrates in Japan |
First International Energy Week & Exhibition and Symposium
2007/9/4-8 |
Koichi Sugiyama, Kenji Ohno(Japan Oil, Gas and Metals National Corporation) |
Methane Hydrate Research Project Team |
[Abstract]The exploratory test well "Nankai Trough" drilled in 2000 by MITI (Ministry of International Trade and Industry) offshore Japan confirmed, for the first time, methane hydrates in pore space of turbiditic reservoir sand like conventional gas resources. Japan's Methane Hydrate Exploration Program was issued on July 2001 envisaging a promotion of technical development for economical drilling, production and recovery of gas from methane hydrates, and a facilitation of its utilization for the long-term stable energy supply to Japan.
The program shall define whether methane hydrates presumed to develop offshore Japan become the future energy resources for the country in accordance with the following framework of 16 years.
Phase 1 (FY2001 to FY2008) Seismic survey, logging and coring. Onshore production tests in Canada.
Phase 2 (FY2009 to FY2011) Offshore production tests.
Phase 3 (FY2012 to FY2016) Study of economic feasibility,
arrangements for commercial production and evaluation
of environmental issues.
Final report of the program will be submitted in the end of FY 2016.
Research Consortium for Methane Hydrate Resources in Japan (MH21 Resources Consortium) has been established in March 2002. The consortium comprises of three leading organizations namely; Technology Research Center-Japan Oil, Gas and Metals National Corporation (JOGMEC-TRC), National Institute of Advanced Industrial Science and Technology (AIST) and Engineering Advancement Association of Japan (ENAA). The numbers of participants under the said Consortium are about 300 persons and about 30 organizations. The three leading organizations mentioned above represent the following working groups respectively to perform effectively R&D program in collaboration with MH21 Research Consortium Secretariat;
1. Research group of assessment of methane hydrates resources
2. Research group of production method and modeling
3. Research group of assessment of environment impact |
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| 11376 |
Pore-scale analysis of carbonates using 3D micro-CT imaging: effects of inclusion of microporosity |
IEA Collaborative Project on Enhanced Oil Recovery, 28th Annual Workshop and Symposium
2007/9/4-7 |
Hiroshi Okabe(Japan Oil, Gas and Metals National Corporation/Waseda Univ.), R. M.Sok, C.H.Arns(Australian National Univ.), M.A.Knackstedt(Australian Univ./University of New South Wales), T.J.Senden, A.P.Sheppard, H.Averdunk(Australian National Univ.), W.V.Pinczewski(Australian Univ./University of New South Wales) |
Research Project Team on Subsurface Technologies for Field Development |
[Abstract]Carbonate reservoirs increasingly become important as they contain more than 50% of the world’s hydrocarbon reserves. Carbonate rocks are diverse and their pore space complex, therefore, they require detailed studies at the different level from micro to macro scale. Large variations in petrophysical properties of carbonates are caused by wide variations in pore type, shape and interconnectivity. Petrophysical properties are directly related to the amount and type of porosity, the dominant feature size and the interconnectivity of different porosity groups. While the properties strongly depend on pore-scale physics, accurately measuring these attributes requires the detail analysis of pore structure in 3D.
We describe the imaging of carbonate core samples in 3D and calculate some of petrophysical properties such as drainage capillary pressure and resistivity directly on the images. Then we correlate the resultant petrophysical properties to the pore structure of the rock. Connectivities of pores are studied as the bioclastic core samples have significant proportions of both connected and disconnected (separate) macropores. It is shown that inclusion of larger pores associated with the smaller pores results in complete connectivity of the macroporous phase and the inclusion of microporosity has a dramatic effect on the petrophysical properties for the bioclastic sample.
Three dimensional imaging and analysis of carbonate core material at the pore scale can provide a basis for more accurate petrophysical models, narrow the range of uncertainty in estimates of petrophysical properties and improve the quantification of the resource within carbonate reservoirs. |
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| 11374 |
Hydrogen production from dimethyl ether by steam reforming over copper alumina catalysts prepared by the sol-gel method |
EUROPACAT VIII
2007/8/30 |
Kaoru Takeishi(Shizuoka Univ.) |
Research Project Team on Emerging Gas Technologies |
| [Abstract]New catalysts for hydrogen production from dimethyl ether (DME) have been developed. Cu-Zn/Al2O3 catalysts prepared by a sol-gel method produced large quantities of H2 and CO2 with DME steam reforming at 300 ℃. The catalysts are more useful for hydrogen production than general DME steam reforming catalysts (mixed catalysts of DME hydrolysis catalysts and methanol steam reforming catalysts). γ-alumina sites for DME hydrolysis into methanol, and copper sites for methanol steam into H2 and CO2 coexist on the surfaces of the sol-gel catalysts, and the two reaction occur systematically, and the catalysts produce H2 effectively from DME. |
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| 11373 |
Time-lapse 3D Seismic monitoring in the JACOS oil sands development field in Canada |
SEG Development & Production Forum "Heavy Oils"
2007/8/1 |
Toru Nakayama, Akihisa Takahashi(JAPEX), Ray Nasen(JACOS), Ayato Kato(Japan Oil, Gas and Metals National Corporation) |
Petroleum Engineering Research Division |
| [Abstract]Time-lapse 3D seismic study was conducted in the Japan Canada Oil Sands Limited (JACOS) Hangingstone steam-assisted gravity drainage (SAGD) operation area, Alberta, Canada. The time-lapse surveys were acquired in February, 2002 and in March, 2006. The two seismic volumes show distinct seismic response changes around the SAGD well pairs. From our time-lapse data analysis, these differences of the seismic responses were interpreted as phenomena caused by P-wave velocity decrease of the oil sands layers due to the steam-injection. |
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| 11372 |
Core velocity measurements of oil sands for quantitative interpretation of time-lapse 3D seismic steam front monitoring |
SEG Development & Production Forum "Heavy Oils"
2007/7/31 |
Shigenobu Onozuka, Ayato Kato(Japan Oil, Gas and Metals
National Corporation), Toru Nakayama(JAPEX), Ray Nasen(JACOS) |
Petroleum Engineering Research Division |
| [Abstract] The time-lapse seismic survey was conducted in the JACOS Hangingstone SAGD operation area. The preliminary result of the survey shows significant difference of seismic response between the baseline and repeat surveys. The difference is interpreted as effect of steam injection. It is, however, not well understood how the seismic amplitude and velocity changes of the oil sands due to the variations of reservoir pressure, temperature and fluid saturation expected during the steam injection in this field. JOGMEC hence developed a novel apparatus for measuring ultrasonic core velocities of unconsolidated sample like the oil sands. We measured and analyzed P-and S-velocities of plug samples of the oil sands acquired from the field, as well as bitumen itself. We showed that behavior of bitumen strongly depends on temperature. In the temperature less than around 40C, bitumen works as like pseudo-solid, which cause several phenomena including high viscosity, low elasticity, substantial shear modulus, high attenuation and strong velocity dispersion. The core velocity measurements showed that natural logarithm function can be applied as a fitting curve for the relationship between the velocity and effective pressure, while two linear lines can be applied as a fitting curve for the relationship between velocity and temperature. In higher temperature than 80C, Gassmann equation can be applied for predicting velocity changes. From the velocity measurements and Gassmann equation analysis, we finally proposed the velocity model which can predict velocity changes of the oil sands caused by any variations of the reservoir conditions. Based on the velocity model, synthetic seismic traces at several reservoir conditions were calculated and compared to the actual seismic trace data at the well location. Seismic attenuation of the oil sands strongly depends on temperature, as well as bitumen. The attenuation information (Q value) may be able to be utilized for distinguishing area where oil sands reservoir is moderately heated (40<T<120C). We are working on quantitative interpretation integrating this study's results with the surface seismic data analysis. |
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| 11371 |
Direct Synthesis of Dimethyl Ether from Synthesis Gas Containing Oxygen |
9th International Symposium on Biotechnology Metal Complexes and Catalysis
2007/7/28 |
Kaoru Takeishi(Shizuoka Univ.) |
Research Project Team on Emerging Gas Technologies |
| [Abstract] I have developed the appropriate and excellent catalyst for DME direct synthesis. The catalysts, Cu-Zn/Al2O3 catalysts prepared by the sol-gel method, produce DME with high activity and high selectivity under the mild reaction temperature and pressure, even if the reaction gases contain some oxygen. |
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| 11365 |
Hydrogen Production from Dimethyl Ether by Copper Alumina Catalysts Prepared by Sol-Gel Method |
The 2nd International Conference on Advances in Petrochemicals and Polymers (ICAPP2007)
2007/6/26 |
Kaoru Takeishi(Shizuoka Univ.) |
Research Project Team on Emerging Gas Technologies |
Dimethyl ether (DME) is expected as a clean
fuel of the next generation. I have developed new catalysts
for hydrogen production by steam reforming of DME. Cu-Zn/Al2O3
catalysts prepared by a sol-gel method produce large quantities
of H2 and CO2 by DME steam reforming under lower reaction
temperature. H2 production by steam reforming of DME consists
of two reaction steps. The first reaction is hydrolysis
of DME into methanol. The second reaction is steam reforming
of methanol that produces H2 and CO2. For this reason,
the mixed catalysts of DME hydrolysis catalysts and methanol
steam reforming catalysts are used for hydrogen production
by DME steam reforming. However, the copper alumina catalysts
prepared by the sol-gel method in single use are more
excellent for H2 production by DME steam reforming than
the mixed catalysts. The reason is that  -Al2O3
sites for DME hydrolysis and Cu sites for methanol steam
reforming are co-existing closely on the catalyst surface.
The consecutive reactions smoothly occur, and hydrogen
is produced more effectively over the sol-gel Cu/Al2O3
catalyst in single use than over the mixed catalysts.
Addition of Zn, Mn, or Fe into Cu/Al2O3 catalyst activates
steam reforming of DME. The Cu-Zn(29-1wt.%)/Al2O3 catalyst
showed the excellent activity of DME steam reforming;
the DME conversion was 95%, H2 yield was 95%, and CO concentration
was 0.8 mol.%. I have developed new catalysts for H2 production
from DME, and the catalysts give us a great potential
for H2 supply from DME. |
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| 11347 |
Geomechanics Issues of the Methane Hydrate Production and Related Material Properties |
18th ASCE Engineering Mechanics Conference
2007/6/4 |
Koji Yamamoto(Japan Oil, Gas and Metals National Corporation) |
Methane Hydrate Research Project Team |
| [Abstract]This paper describes the importance of the mechanical properties of the methane hydrate bearing sediments for gas production from the solid form of the hydrocarbon. The dissociation and association processes of the gas hydrate in granular material are coupled phenomena of the thermodynamic condition change, fluid (gas and water) flow, and also the mechanical deformation and failure. Hydrate dissociation and association change the mechanical properties, and deformation and failure make thermal and flow conditions of the material different. This process may cause several issues on the field development for gas production, such as borehole instability, instability of the reservoir formation and surface, near wellbore phenomena and so on |
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| 11346 |
MECHANICAL PROPERTIES OF POST-DISSOCIATION METHANE HYDRATE BEARING SEDIMENTS AND SOLID PRODUCTION MECHANISM |
18th ASCE Engineering Mechanics Conference
2007/6/4 |
Koji Yamamoto(Japan Oil, Gas and Metals National Corporation) |
Methane Hydrate Research Project Team |
| Reported in this paper is a laboratory experimental study on mechanical properties of the core materials and solid production behaviour in post-dissociation methane hydrate-bearing formations. The compressive triaxial and direct tensile strength properties were evaluated on re-constituted core materials at room temperature. A number of laboratory solid production experiments were carried out on the same core materials to examine simulated perforation tunnel stability and solid production behaviour. It was found that at a low water saturation (〜30%), a cone shaped cavity could be formed on the sand face and remain stable for an injection pressure of 1MPa if the flowing fluid was gas. However, this injection was reduced to 0.1 to 0.2 MPa if the injection fluid was brine water. At a higher water saturation (〜70%), a stable cavity was not observed. Sand production was induced at an injection pressure of 0.1-0.2 MPa for both gas and water injection. Sand production behavior appeared not to be affected by the hole size on the sand face.
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| 11343 |
Catalysts for direct synthesis of dimethyl ether from synthesis gas |
The 11th Korea-Japan Symposium on Catalysis
2007/5/22 |
Kaoru Takeishi(Shizuoka Univ.) |
Research Project Team on Emerging Gas Technologies |
| [Abstract]Copper alumina catalysts prepared by a sol-gel method that is appropriate
for DME steam reforming are applied for the DME direct synthesis (3H2 + 3CO → CH3OCH3 + 2CO2) that is
similar reaction of DME steam reforming (CH3OCH3 + 3H2O → 3H2 + 2CO2).
Much amount of DME was produced over Cu-Zn/Al2O3 catalyst prepared by the sol-gel method,
at the lower reaction temperature of 250ºC. The less amount of DME was produced over the
mixed catalyst of the methanol synthesis catalyst (N211) and the methanol dehydration catalyst (BK-105),
at the higher reaction temperature of 310ºC. The single type catalyst that has copper sites for methanol synthesis and alumina sites for methanol dehydration on the surface is more appropriate and more excellent for DME direct synthesis than the mixed catalyst that is one of the patent catalysts for DME direct synthesis. |
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