Experimental and modeling analyses of scaling criteria for methane hydrate dissociation in sediment by depressurization

Three high pressure reactors with different inner volumes, which are named as the Pilot-scale Hydrate Simulator (PHS), the Cubic Hydrate Simulator (CHS), and the Small Cubic Hydrate Simulator (SCHS), are applied for investigating hydrate dissociation by depressurization method. The volume of the PHS...

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Bibliographic Details
Published in:Applied Energy
Main Authors: Wang, Yi, Feng, Jing-Chun, Li, Xiao-Sen, Zhang, Yu
Format: Article in Journal/Newspaper
Language:English
Published: 2016
Subjects:
Hydrate Dissociation
Scaling Criterion
Depressurization
Different Scales
Experiment
Science & Technology
Technology
Energy & Fuels
Engineering
DUAL HORIZONTAL WELLS
GAS-PRODUCTION
THERMAL-STIMULATION
POROUS-MEDIA
PRODUCTION BEHAVIORS
BEARING SEDIMENTS
HYDROGEN STORAGE
SANDY RESERVOIR
CARBON-DIOXIDE
HEAT-TRANSFER
Chemical
Methane hydrate
Online Access:http://ir.giec.ac.cn/handle/344007/13914
https://doi.org/10.1016/j.apenergy.2016.08.023
id ftchacadsciegiec:oai:ir.giec.ac.cn:344007/13914
record_format openpolar
spelling ftchacadsciegiec:oai:ir.giec.ac.cn:344007/13914 2023-05-15T17:12:11+02:00 Experimental and modeling analyses of scaling criteria for methane hydrate dissociation in sediment by depressurization Wang, Yi Feng, Jing-Chun Li, Xiao-Sen Zhang, Yu 2016-11-01 http://ir.giec.ac.cn/handle/344007/13914 https://doi.org/10.1016/j.apenergy.2016.08.023 英语 eng APPLIED ENERGY http://ir.giec.ac.cn/handle/344007/13914 doi:10.1016/j.apenergy.2016.08.023 Hydrate Dissociation Scaling Criterion Depressurization Different Scales Experiment Science & Technology Technology Energy & Fuels Engineering DUAL HORIZONTAL WELLS GAS-PRODUCTION THERMAL-STIMULATION POROUS-MEDIA PRODUCTION BEHAVIORS BEARING SEDIMENTS HYDROGEN STORAGE SANDY RESERVOIR CARBON-DIOXIDE HEAT-TRANSFER Chemical Article 期刊论文 2016 ftchacadsciegiec https://doi.org/10.1016/j.apenergy.2016.08.023 2022-09-23T14:12:42Z Three high pressure reactors with different inner volumes, which are named as the Pilot-scale Hydrate Simulator (PHS), the Cubic Hydrate Simulator (CHS), and the Small Cubic Hydrate Simulator (SCHS), are applied for investigating hydrate dissociation by depressurization method. The volume of the PHS, the CHS, and the SCHS are 117.80 L, 5.80 L, and 0.73 L, respectively. Meanwhile, the model of scaling criterion for hydrate dissociation by the depressurization method is developed as well. The scaling criteria are verified and modified by the hydrate dissociation experiments with different scales. Finally, the gas production from a field scale hydrate reservoir (FSHR) is predicted by scaling the experimental results using the modified scaling criteria. The results indicate that the ratios of gas production in the depressurizing (DP) stage are similar to the ratios of inner volume, which verify the scaling criteria in the DP stage. However, the scaling criteria for the experiments in the constant-pressure (CP) stages need to be modified by the experimental results. The correction factor is 0.89. By using the modified scaling criteria, the gas production behavior, the hydrate dissociation process, and the heat transfer process in a larger scale hydrate reservoir can be predicted. The maximum deviations between the calculated value and experimental result are less than 16%, which can be accepted. In the FSHR with the diameter of 50 m and the length of 60 m, the predicted results indicate that 3.74 x 10(6) m(3) of gas are produced in 120 h (5 days) during the DP stage, and 1.94 x 10(6) m(3) of gas are produced in 1.86 x 10(5) h (7750 days) during the CP stage. (C) 2016 Elsevier Ltd. All rights reserved. Article in Journal/Newspaper Methane hydrate Guangzhou Institute of Energy Conversion, Chinese Academy of Sciences: GIEC OpenIR Applied Energy 181 299 309
institution Open Polar
collection Guangzhou Institute of Energy Conversion, Chinese Academy of Sciences: GIEC OpenIR
op_collection_id ftchacadsciegiec
language English
topic Hydrate Dissociation
Scaling Criterion
Depressurization
Different Scales
Experiment
Science & Technology
Technology
Energy & Fuels
Engineering
DUAL HORIZONTAL WELLS
GAS-PRODUCTION
THERMAL-STIMULATION
POROUS-MEDIA
PRODUCTION BEHAVIORS
BEARING SEDIMENTS
HYDROGEN STORAGE
SANDY RESERVOIR
CARBON-DIOXIDE
HEAT-TRANSFER
Chemical
spellingShingle Hydrate Dissociation
Scaling Criterion
Depressurization
Different Scales
Experiment
Science & Technology
Technology
Energy & Fuels
Engineering
DUAL HORIZONTAL WELLS
GAS-PRODUCTION
THERMAL-STIMULATION
POROUS-MEDIA
PRODUCTION BEHAVIORS
BEARING SEDIMENTS
HYDROGEN STORAGE
SANDY RESERVOIR
CARBON-DIOXIDE
HEAT-TRANSFER
Chemical
Wang, Yi
Feng, Jing-Chun
Li, Xiao-Sen
Zhang, Yu
Experimental and modeling analyses of scaling criteria for methane hydrate dissociation in sediment by depressurization
topic_facet Hydrate Dissociation
Scaling Criterion
Depressurization
Different Scales
Experiment
Science & Technology
Technology
Energy & Fuels
Engineering
DUAL HORIZONTAL WELLS
GAS-PRODUCTION
THERMAL-STIMULATION
POROUS-MEDIA
PRODUCTION BEHAVIORS
BEARING SEDIMENTS
HYDROGEN STORAGE
SANDY RESERVOIR
CARBON-DIOXIDE
HEAT-TRANSFER
Chemical
description Three high pressure reactors with different inner volumes, which are named as the Pilot-scale Hydrate Simulator (PHS), the Cubic Hydrate Simulator (CHS), and the Small Cubic Hydrate Simulator (SCHS), are applied for investigating hydrate dissociation by depressurization method. The volume of the PHS, the CHS, and the SCHS are 117.80 L, 5.80 L, and 0.73 L, respectively. Meanwhile, the model of scaling criterion for hydrate dissociation by the depressurization method is developed as well. The scaling criteria are verified and modified by the hydrate dissociation experiments with different scales. Finally, the gas production from a field scale hydrate reservoir (FSHR) is predicted by scaling the experimental results using the modified scaling criteria. The results indicate that the ratios of gas production in the depressurizing (DP) stage are similar to the ratios of inner volume, which verify the scaling criteria in the DP stage. However, the scaling criteria for the experiments in the constant-pressure (CP) stages need to be modified by the experimental results. The correction factor is 0.89. By using the modified scaling criteria, the gas production behavior, the hydrate dissociation process, and the heat transfer process in a larger scale hydrate reservoir can be predicted. The maximum deviations between the calculated value and experimental result are less than 16%, which can be accepted. In the FSHR with the diameter of 50 m and the length of 60 m, the predicted results indicate that 3.74 x 10(6) m(3) of gas are produced in 120 h (5 days) during the DP stage, and 1.94 x 10(6) m(3) of gas are produced in 1.86 x 10(5) h (7750 days) during the CP stage. (C) 2016 Elsevier Ltd. All rights reserved.
format Article in Journal/Newspaper
author Wang, Yi
Feng, Jing-Chun
Li, Xiao-Sen
Zhang, Yu
author_facet Wang, Yi
Feng, Jing-Chun
Li, Xiao-Sen
Zhang, Yu
author_sort Wang, Yi
title Experimental and modeling analyses of scaling criteria for methane hydrate dissociation in sediment by depressurization
title_short Experimental and modeling analyses of scaling criteria for methane hydrate dissociation in sediment by depressurization
title_full Experimental and modeling analyses of scaling criteria for methane hydrate dissociation in sediment by depressurization
title_fullStr Experimental and modeling analyses of scaling criteria for methane hydrate dissociation in sediment by depressurization
title_full_unstemmed Experimental and modeling analyses of scaling criteria for methane hydrate dissociation in sediment by depressurization
title_sort experimental and modeling analyses of scaling criteria for methane hydrate dissociation in sediment by depressurization
publishDate 2016
url http://ir.giec.ac.cn/handle/344007/13914
https://doi.org/10.1016/j.apenergy.2016.08.023
genre Methane hydrate
genre_facet Methane hydrate
op_relation APPLIED ENERGY
http://ir.giec.ac.cn/handle/344007/13914
doi:10.1016/j.apenergy.2016.08.023
op_doi https://doi.org/10.1016/j.apenergy.2016.08.023
container_title Applied Energy
container_volume 181
container_start_page 299
op_container_end_page 309
_version_ 1766068974892613632

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