The consistency of the normalized hydrate dissociation rate in the hydrate simulator with different scales

Recently, in order to perform the gas production test from methane hydrate reservoir in laboratory, the size of the experimental simulator is developing towards a larger scale. The characteristics of the heat transfer and the mass transport in the hydrate-bearing sediments with different scales are...

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Published in:Fuel
Main Authors: Li, Xiao-Yan, Li, Xiao-Sen, Wang, Yi, Zhang, Yu, Wan, Kun, Zeng, Hao-Peng
Format: Report
Language:English
Published: ELSEVIER SCI LTD 2021
Subjects:
Gas hydrate
Hydrate simulator scale
Depressurization
Normalized hydrate dissociation rate
METHANE-HYDRATE
GAS-PRODUCTION
HEAT-TRANSFER
NUMERICAL-SIMULATION
PRODUCTION BEHAVIOR
PUFF METHOD
SEDIMENT
RECOVERY
DEPOSITS
Energy & Fuels
Engineering
Chemical
Methane hydrate
Online Access:http://ir.giec.ac.cn/handle/344007/32477
http://ir.giec.ac.cn/handle/344007/32478
https://doi.org/10.1016/j.fuel.2020.119436
id ftchacadsciegiec:oai:ir.giec.ac.cn:344007/32478
record_format openpolar
spelling ftchacadsciegiec:oai:ir.giec.ac.cn:344007/32478 2023-05-15T17:11:57+02:00 The consistency of the normalized hydrate dissociation rate in the hydrate simulator with different scales Li, Xiao-Yan Li, Xiao-Sen Wang, Yi Zhang, Yu Wan, Kun Zeng, Hao-Peng 2021-03-01 http://ir.giec.ac.cn/handle/344007/32477 http://ir.giec.ac.cn/handle/344007/32478 https://doi.org/10.1016/j.fuel.2020.119436 英语 eng ELSEVIER SCI LTD FUEL http://ir.giec.ac.cn/handle/344007/32477 http://ir.giec.ac.cn/handle/344007/32478 doi:10.1016/j.fuel.2020.119436 Gas hydrate Hydrate simulator scale Depressurization Normalized hydrate dissociation rate METHANE-HYDRATE GAS-PRODUCTION HEAT-TRANSFER NUMERICAL-SIMULATION PRODUCTION BEHAVIOR PUFF METHOD SEDIMENT RECOVERY DEPOSITS Energy & Fuels Engineering Chemical 期刊论文 2021 ftchacadsciegiec https://doi.org/10.1016/j.fuel.2020.119436 2022-09-23T14:17:46Z Recently, in order to perform the gas production test from methane hydrate reservoir in laboratory, the size of the experimental simulator is developing towards a larger scale. The characteristics of the heat transfer and the mass transport in the hydrate-bearing sediments with different scales are varied, thereby resulting in the different hydrate dissociation behaviors. In this study, the SCHS (Small Cubic Hydrate Simulator, 0.729 L), the CHS (Cubic Hydrate Simulator, 5.832 L), and the PHS (Pilot-scale Hydrate Simulator, 117.8 L) in our laboratory were applied to study the hydrate dissociation by depressurization. The experimental results showed that, in the depressurization stage, the volume of the hydrate dissociation was determined by the sensible heat of the sediments and the heat transferred from the surroundings. During the constant pressure stage, the normalized hydrate dissociation rates (v(norm)) was first proposed to define the average rate of the hydrate dissociation per temperature and per shape factor. The v(norm) excluded the influence of the driving force of the heat transfer and the scale of the hydrate simulator on the hydrate dissociation. Therefore, for the hydrate simulator with different scales, the value of the v(norm) for different production pressures were similar. The calculated value of the v(norm) for different runs were not completely be same due to the experimental error. However, the average value of the v(norm) for different runs could be used to predicate the average hydrate dissociation rate in the hydrate simulator with other scales. For example, during the gas production from a hydrate reservoir with the same shape and double length/radius of the PHS, the average hydrate dissociation rate can be calculated as 12.44 ml/min, and the total duration time of the hydrate dissociation can be calculated as 8.58 days. Report Methane hydrate Guangzhou Institute of Energy Conversion, Chinese Academy of Sciences: GIEC OpenIR Fuel 287 119436
institution Open Polar
collection Guangzhou Institute of Energy Conversion, Chinese Academy of Sciences: GIEC OpenIR
op_collection_id ftchacadsciegiec
language English
topic Gas hydrate
Hydrate simulator scale
Depressurization
Normalized hydrate dissociation rate
METHANE-HYDRATE
GAS-PRODUCTION
HEAT-TRANSFER
NUMERICAL-SIMULATION
PRODUCTION BEHAVIOR
PUFF METHOD
SEDIMENT
RECOVERY
DEPOSITS
Energy & Fuels
Engineering
Chemical
spellingShingle Gas hydrate
Hydrate simulator scale
Depressurization
Normalized hydrate dissociation rate
METHANE-HYDRATE
GAS-PRODUCTION
HEAT-TRANSFER
NUMERICAL-SIMULATION
PRODUCTION BEHAVIOR
PUFF METHOD
SEDIMENT
RECOVERY
DEPOSITS
Energy & Fuels
Engineering
Chemical
Li, Xiao-Yan
Li, Xiao-Sen
Wang, Yi
Zhang, Yu
Wan, Kun
Zeng, Hao-Peng
The consistency of the normalized hydrate dissociation rate in the hydrate simulator with different scales
topic_facet Gas hydrate
Hydrate simulator scale
Depressurization
Normalized hydrate dissociation rate
METHANE-HYDRATE
GAS-PRODUCTION
HEAT-TRANSFER
NUMERICAL-SIMULATION
PRODUCTION BEHAVIOR
PUFF METHOD
SEDIMENT
RECOVERY
DEPOSITS
Energy & Fuels
Engineering
Chemical
description Recently, in order to perform the gas production test from methane hydrate reservoir in laboratory, the size of the experimental simulator is developing towards a larger scale. The characteristics of the heat transfer and the mass transport in the hydrate-bearing sediments with different scales are varied, thereby resulting in the different hydrate dissociation behaviors. In this study, the SCHS (Small Cubic Hydrate Simulator, 0.729 L), the CHS (Cubic Hydrate Simulator, 5.832 L), and the PHS (Pilot-scale Hydrate Simulator, 117.8 L) in our laboratory were applied to study the hydrate dissociation by depressurization. The experimental results showed that, in the depressurization stage, the volume of the hydrate dissociation was determined by the sensible heat of the sediments and the heat transferred from the surroundings. During the constant pressure stage, the normalized hydrate dissociation rates (v(norm)) was first proposed to define the average rate of the hydrate dissociation per temperature and per shape factor. The v(norm) excluded the influence of the driving force of the heat transfer and the scale of the hydrate simulator on the hydrate dissociation. Therefore, for the hydrate simulator with different scales, the value of the v(norm) for different production pressures were similar. The calculated value of the v(norm) for different runs were not completely be same due to the experimental error. However, the average value of the v(norm) for different runs could be used to predicate the average hydrate dissociation rate in the hydrate simulator with other scales. For example, during the gas production from a hydrate reservoir with the same shape and double length/radius of the PHS, the average hydrate dissociation rate can be calculated as 12.44 ml/min, and the total duration time of the hydrate dissociation can be calculated as 8.58 days.
format Report
author Li, Xiao-Yan
Li, Xiao-Sen
Wang, Yi
Zhang, Yu
Wan, Kun
Zeng, Hao-Peng
author_facet Li, Xiao-Yan
Li, Xiao-Sen
Wang, Yi
Zhang, Yu
Wan, Kun
Zeng, Hao-Peng
author_sort Li, Xiao-Yan
title The consistency of the normalized hydrate dissociation rate in the hydrate simulator with different scales
title_short The consistency of the normalized hydrate dissociation rate in the hydrate simulator with different scales
title_full The consistency of the normalized hydrate dissociation rate in the hydrate simulator with different scales
title_fullStr The consistency of the normalized hydrate dissociation rate in the hydrate simulator with different scales
title_full_unstemmed The consistency of the normalized hydrate dissociation rate in the hydrate simulator with different scales
title_sort consistency of the normalized hydrate dissociation rate in the hydrate simulator with different scales
publisher ELSEVIER SCI LTD
publishDate 2021
url http://ir.giec.ac.cn/handle/344007/32477
http://ir.giec.ac.cn/handle/344007/32478
https://doi.org/10.1016/j.fuel.2020.119436
genre Methane hydrate
genre_facet Methane hydrate
op_relation FUEL
http://ir.giec.ac.cn/handle/344007/32477
http://ir.giec.ac.cn/handle/344007/32478
doi:10.1016/j.fuel.2020.119436
op_doi https://doi.org/10.1016/j.fuel.2020.119436
container_title Fuel
container_volume 287
container_start_page 119436
_version_ 1766068699078328320

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