Effect of multiphase flow on natural gas hydrate production in marine sediment

Effect of multiphase flow on natural gas hydrate production in marine sediment

Journal Pre-proof Effect of multiphase flow on natural gas hydrate production in marine sediment Huiru Sun, Bingbing Chen, Mingjun Yang PII: S1875-51...

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Journal Pre-proof Effect of multiphase flow on natural gas hydrate production in marine sediment Huiru Sun, Bingbing Chen, Mingjun Yang PII:

S1875-5100(19)30318-X

DOI:

https://doi.org/10.1016/j.jngse.2019.103066

Reference:

JNGSE 103066

To appear in:

Journal of Natural Gas Science and Engineering

Received Date: 10 May 2019 Revised Date:

30 July 2019

Accepted Date: 9 November 2019

Please cite this article as: Sun, H., Chen, B., Yang, M., Effect of multiphase flow on natural gas hydrate production in marine sediment, Journal of Natural Gas Science & Engineering, https://doi.org/10.1016/ j.jngse.2019.103066. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2019 Published by Elsevier B.V.

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Effect of multiphase flow on natural gas hydrate production in marine sediment

2

Huiru Sun, Bingbing Chen, Mingjun Yang*

3

Key Laboratory of Ocean Energy Utilization and Energy Conservation of Ministry of

4

Education, Dalian University of Technology, Dalian 116024, China

5 6

Abstract Natural gas hydrates (NGHs), regarded as an alternative future energy

7

source. Currently, tests for hydrate exploitation from marine sediment have been

8

performed in the Nankai Trough of Japan and the Shenhu area of the South China Sea.

9

Hydrate exploitation is influenced by water-gas flow in the sediment, and considering

10

the huge seawater reserves in hydrate accumulation areas, an experiment of

11

seawater-gas flow was performed to dissociate hydrate. The effects of seawater-gas

12

flow rates and initial hydrate saturation on methane hydrate (MH) production was

13

analyzed. The results showed that seawater-gas flow efficiently promotes hydrate

14

dissociation and inhibits hydrate reformation. Moreover, there was a faster heat and

15

mass transfer with increasing seawater flow rates and decreasing gas flow rates,

16

which enhanced the average MH dissociation rate. In addition, the variation time of

17

the flow channel increased with higher initial hydrate saturation. Additionally,

18

seawater-gas flow promotes MH dissociation stronger than deionized water-gas flow.

19

Keywords: methane hydrate dissociation; water flow erosion; seawater-gas flow; salt

20

ions; hydrate saturation

1

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1. Introduction

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Natural gas hydrates (NGHs) are typically found in continental permafrost and

23

marine sediment and they form from hydrocarbon gas and water under high pressure

24

and low temperature (Hiratsuka et al., 2015, Gao et al., 2018). The water molecules

25

interconnected through hydrogen bonding form cage structures to encage gas

26

molecules (Zheng et al., 2019, Saman et al., 2010, Liu et al., 2018). There are rich

27

natural gas hydrate reservoirs distributed around the world, in which the estimated

28

energy potential is far greater than the total amount of conventional coal, oil and

29

natural gas (Wang et al., 2017). NGHs are seen as potential sources of natural gas in

30

view of their high energy density, abundant reserves and nonpollution (Zhao et al.,

31

2014, Xu and Li, 2015). Therefore, researching hydrate formation and dissociation

32

kinetics and developing methods for natural gas recovery from hydrate reservoirs are

33

arousing wide concern in countries and among scientists all over the world in recent

34

years (Wang et al., 2016b, Song et al., 2015b).

35

For now, methods for large-scale production of natural gas from NGHs are still

36

evolving, and they are all based on changing reservoir pressure and temperature to

37

deviate from hydrate thermodynamic equilibrium (Ji et al., 2001). There are four

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common methods for gas hydrate exploitation as follows. The depressurization

39

method, in which the reservoir pressure is decreased below the hydrate equilibrium

40

pressure at a specified temperature (Reagan et al., 2015, Li et al., 2012, Yang et al.,

41

2019b). The thermal stimulation method, in which the reservoir temperature is 2

42

increased above the hydrate equilibrium temperature via injecting hot water, hot brine

43

or steam (Song et al., 2015a, Nair et al., 2016, Chong et al., 2016b). The chemical

44

inhibitor stimulation method, in which chemicals are injected into the hydrate

45

reservoir to transform the hydrate pressure-temperature equilibrium and promote

46

hydrate dissociation (Li et al., 2011, Chong et al., 2016a). The CO2 replacement

47

method, in which liquid CO2 is injected into hydrate reservoirs to form CO2 hydrate

48

and replace methane gas (Yu et al., 2015, Brewer et al., 2014). The above methods all

49

have their own merits and demerits. The large heat loss of thermal stimulation, the

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expensive cost and pollution environment of chemical inhibitors, and the low

51

efficiency of CO2 replacement restricts application of those three methods for

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practical hydrate exploitation (Fitzgerald et al., 2014, Lee et al., 2010, Jung et al.,

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2010). However, depressurization needs no external energy supply and energy

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consumption is the least, so that was regarded as the most effective method to recover

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natural gas from NGH reservoirs considering the economic cost (Chong et al., 2017a,

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Zhao et al., 2014).

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The depressurization method was first used for field-scale hydrate production at

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the Mackenzie Delta Mallik site in the Northwest Territories, Canada, and then a

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larger-scale test was conducted at the same site in 2007 and 2008 (Yang et al., 2016).

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However, the hydrate dissociation is an endothermic reaction. When the pressure drop

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is large, the sensible heat of the hydrate and heat transferred from the ambient

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environment was not enough to sustain the faster hydrate dissociation reaction. So, 3

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there may occur the hydrate reformation and ice generation in depressurization

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process, which will obviously influent the gas production rate (Wang et al., 2018,

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Zhao et al., 2015, Chen et al., 2015). Therefore, many experimental studies and

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numerical modeling of hydrate dissociation and gas production using depressurization

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were conducted. Konno et al. (Konno et al., 2014) performed the gas production test

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on methane hydrate sediments using one-step and multistep depressurization. They

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found that a suitable heat for hydrate-bearing sediment is the important factor to drive

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hydrate dissociation. Zhan et al. (Zhan et al., 2018) used different quartz sand particle

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sizes to simulate hydrate reservoirs, form methane hydrate, and dissociate hydrate via

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the depressurization method. They analyzed and compared the effects of sediment

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particle size on gas production rate and dissociation characteristics. Zhao et al. (Zhao

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et al., 2012) conducted numerical simulations to investigate the water phase impact on

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methane hydrate dissociation by depressurization in porous media. Their experimental

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results showed that the movement of water plays a significant role in late stage

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thermal conduction, and the gas production rate increased with higher water saturation

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in late stage dissociation. Based on the available data in the Shenhu Area of the South

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China Sea, Xiong et al. (Xiong et al., 2012) employed a 1D experimental setup to

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study methane hydrate dissociation by depressurization, and they found that lower

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dissociation pressure may lead to higher hydrate dissociation rate and higher

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dissociation heat. Oyama et al. (Oyama et al., 2012) studied the depressurized

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dissociation of natural methane-hydrate-bearing sediment with low permeability, and 4

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they assessed two dissociation models making use of their experimental results. To

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acquire kinetic hydrate dissociation data under different backpressures, depressurized

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dissociation of methane hydrate was studied using magnetic resonance imaging (MRI)

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by Wang et al. (Wang et al., 2015). For the other three hydrate dissociation methods,

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Su et al. (Su et al., 2013) investigated the gas production potential from hydrate

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sediment using thermal stimulation. They found that thermal stimulation was effective

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at promoting gas release from hydrate sediment and enhanced gas production in the

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late stage of hydrate dissociation. Li et al. (Li et al., 2017) injected methanol into

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methane-hydrate-bearing sediment to study dissociation behavior employing a

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one-dimensional experimental device. They proposed new adjustment tactics for

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experimental operation according to the injection rate ratio of methanol and water.

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Jung et al. (Jung and Santamarina, 2010) measured the electrical resistance change

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and relative stiffness in the CH4-CO2 replacement process, and found that the overall

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hydrate remained solid and gas-hydrate-water phases coexisted for long periods of

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time. Yuan et al. (Yuan et al., 2013) used a three-dimensional reactor to study

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CO2-CH4 replacement in hydrate-bearing deposits with liquid CO2, and analyzed the

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influence of different stratum conditions on the replacement process.

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Whatever NGH exploitation methods are adopted, hydrate dissociation is always

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accompanied by production and migration of water and gas. Chen et al. (Chen et al.,

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2019b) proposed a water flow erosion method to promote hydrate dissociation and

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investigated the effects of seawater flow on natural gas hydrate dissociation (Chen et 5

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al., 2019a), whereas the effect of gas migration on hydrate dissociation was ignored.

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In addition, deionized water-gas two-phase flow promotion of MH dissociation has

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been studied, and hydrate reformation may appear under slower water-gas flow rates.

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Therefore, based on those studies and considering the effect of seawater on hydrate

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thermodynamic equilibrium, experiments of seawater-gas two-phase flow were

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performed, and different seawater-gas flow rates effect on MH dissociation were

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analyzed. In addition, the system pressure and temperature are always in the

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thermodynamic stability region of the hydrate-bearing sediment core. Due to the huge

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seawater reserves in hydrate accumulation areas, the method of seawater-gas flow to

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dissociate hydrate is achievable, so the experimental results offer some reference and

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guidance for future NGH exploration in marine environments.

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2. Experiments

117

2.1 Apparatus and materials

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Fig. 1 shows a sketch of the experimental setup designed to investigate MH

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dissociation during seawater-gas two-phase flow. The experimental setup included an

120

MRI system (Varian, Inc., Palo Alto, CA, USA), a high-pressure vessel (polyimide),

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three high-precision injection pumps (260D, Teledyne Isco Inc., Lincoln, NE, USA),

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three thermostat baths (FL300 and FL 25, JULABO, Seelbach, Germany), two pressure

123

transducers (3510CF, Emerson Electric Co., Ltd., St. Louis, USA), a differential

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pressure sensor (Nagano Keiki, Japan), and a data acquisition system. The MRI system

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was used to visualize the change of MH distribution during seawater-gas flow, which 6

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was operated at 400 MHz resonance frequency and 9.4 T magnet field. This MRI

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system adopted a spin echo sequence to obtain two-dimensional proton

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density-weighted images. The parameters of the sequence are as follows, which based

129

on Chen et al. (Chen et al., 2019a). Echo time was 4.39 ms, image data matrix was

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128×128, and the field of view was 30 mm×30 mm (Chen et al., 2019a). Three injection

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pumps were used to inject liquid, CH4 gas and to control the vessel pressure for

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seawater-gas flow. The effective volume of injection pump was 260 ml, the accuracy of

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flow control was ±1 µl·min-1, and accuracy of pressure control was ± 0.5%. The

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temperatures of the pumps and MRI system were strictly controlled by thermostat baths,

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and the stability of the thermostat baths was ±0.1

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differential pressure sensor were used to collect pressure signals in the inlet and outlet

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of the high-pressure vessel. The accuracy of the pressure transducers was ±0.05%, and

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the accuracy of the differential pressure sensor was ±0.01%. The data acquisition

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system included an A/D module (Advantech Co., Ltd., Milpitas, CA, USA) and a

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computer, which was used to collect and dispose the pressure signals. Deionized water

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and CH4 gas were used to form methane hydrate (MH). Seawater (configured by

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deionized water) and CH4 gas were used in the MH dissociation process.

7

. Pressure transducers and a

143 144 145

Fig. 1 Schematic of the experimental system 2.2 Hydrate formation

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A high-pressure vessel with inner diameter of 15 mm and length of 200 mm was

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washed, dried, and filled with BZ-02 glass beads (As-One Co., Ltd., Japan). The

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porosity of BZ-02 glass beads was 35.4%, the particle diameter was 0.177-0.250 mm

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and the density of BZ-02 was 2.6 g·cm-3. After the leakage test, the vessel was

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mounted in the center of the MRI magnetic body and vacuumed to expel free gas.

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Next, the vessel was pressurized to 6000 kPa using water injection pump with a

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constant injection rate of 20 ml·min-1 to fully saturate the porous media. After

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maintaining the pressure stable for 1 h, the outlet valve was opened, and the vessel

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pressure equaled to atmospheric pressure. Then, CH4 gas (Dalian Special Gases Co.,

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Ltd., China, 99.99%) with 4000 kPa pressure was injected into the vessel to displace

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the deionized water and obtain partly water-saturated porous media. Then, the vessel

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was pressurized to 6000 kPa by CH4 gas injection with a constant injection rate of 20

8

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ml·min-1 and maintained stable to form MH. During the whole process of hydrate

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formation, the thermostat bath temperature was kept at 274.15 K. Moreover, the

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images were obtained continuously via MRI for each experiment.

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2.3 Seawater-gas two-phase flow process

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The experimental parameters and results of twelve experimental cases are shown

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in Table 1. Take Case 1 as an example to illustrate the seawater-gas two-phase flow

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process. The seawater solution (NaCl solution with a mass fraction of 3.5%) was

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prepared before the experiment. After hydrate formation finished, the outlet valve was

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opened to interconnect backpressure pump to the vessel. Then, the pressure of

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backpressure pump was decreased to 3200 kPa form 6000 kPa using backpressure

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pump with a constant rate of -20 ml·min-1, and maintained that pressure for a while to

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ensure that no MH dissociation appeared in the pressure adjustment process. When

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the temperature is 274.15 K, the MH phase equilibrium pressure is 2850 kPa (Jr and

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Koh, 2007). Therefore, the hydrate was always thermodynamically stable during the

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backpressure adjustment process. Next, seawater (1ml·min-1) and CH4 (1ml·min-1)

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were simultaneously injected into the vessel from the bottom to the top by seawater

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injection pump and gas injection pump. The temperature of the flowing seawater and

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CH4 gas was controlled at 273.95 K by thermostat bath to prevent hydrate dissociation

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caused by temperature variation. Images of seawater-gas flow were recorded in

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succession using an MRI system. In addition, after the seawater-gas flow process,

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deionized water was used to wash the whole experimental system (pipelines, seawater 9

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injection pump and high-pressure vessel) approximately 5~6 times till the

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conductivity was lower than 0.69 µS·cm-1, which avoided residual seawater inhibiting

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hydrate formation. The conductivities of seawater and deionized water were 2.85*104

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µS·cm-1 and 0.69 µS·cm-1, respectively(Chen et al., 2019a).

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Table 1. Experimental parameters and results Case 1 2 3 4 5 6 7 8 9 10 11 12

184 185 186 187 188 189 190

vw (ml/min) 1 2 3 3 4 10 5 5 5 5 5 5

vg (ml/min) 1 2 3 1 1 1 1 1 1 1 1 1

Pi (kPa) 6010 6015 6020 6010 6000 6005 6020 6011 6040 6060 6030 6050

Shi (%) 24.33 23.03 22.42 23.83 23.77 22.56 15.48 22.50 28.19 31.08 36.23 41.48

tapp (min) 80 46 38 24 14 10 8 12 14 14 20 26

tdis (min) 986 532 290 136 88 42 50 68 100 108 112 132

RV (%/min) 0.0269 0.0474 0.0890 0.2128 0.3212 0.7050 0.3686 0.4018 0.3278 0.3306 0.3938 0.3913

a

The symbols in this table are defined as follows: tapp is the flow channel appearance time; tdis is the flow channel disappearance time; Vw is the seawater flow rate during seawater-gas two-phase flow; Vg is the gas flow rate during seawater-gas two-phase flow; Shi is the initial MH saturation before hydrate dissociation (volume fraction); Pi is the MH formation pressure; and Rv is the average MH dissociation rate. All experiments were carried out at 274.15 K, the temperature of flowing seawater and gas was kept at 273.95 K, and the designed backpressure was 3200 kPa for all cases during the seawater-gas flow process.

191

In this study, the average MH dissociation rate was calculated by the flowing

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equation (Wang et al., 2018), which can reflect the average water and gas production

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rates.

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Ri =

S hi − S h (i + ∆t )

(1)

∆t

10

195

where

196

and

197

the two changes of hydrate saturation.

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3. Results and Discussion

S

Ri

is the MH dissociation rate at i min,

h  i + ∆ t 

S hi

is the hydrate saturation at i min

are the hydrate saturation at i + ∆t min. ∆t is the time interval between

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Twelve experimental cases were performed to study the effects of different

200

seawater-gas flow rates and different initial hydrate saturations on MH dissociation.

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The seawater-gas flow rate was expressed as the seawater flow rate-gas flow rate in

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this study. In Cases 1~6, the MH saturation was controlled approximately the same

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(22.5%~23.5%), and the seawater-gas flow rate of that was set to 1-1, 2-2, 3-3, 3-1,

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4-1, and 10-1 ml·min-1, respectively. In Cases 7~12, the seawater-gas flow rates were

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all set to 5-1 ml·min-1, and the MH saturation was controlled to approximately 15%,

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23%, 28%, 31%, 36%, and 41%, respectively. The backpressure was controlled at

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3200 kPa for all cases, and the temperature of flowing seawater and gas was set to

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273.95

209

thermodynamically stable. The distribution of water and MH was recorded by the

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MRI system.

211

3.1 Methane hydrate formation

K,

which

ensured

that

the

hydrate-bearing

sediment

core

was

212

The pressure and temperature were set to 6000 kPa and 274.15 K, and were kept

213

constant for the whole MH formation process for Cases 1~12. MH saturation,

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expressed as the volume fraction of pore space occupied by hydrate, was computed by

215

mean intensity (MI) data acquired form MRI images (Chen et al., 2019a). Because 1 11

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m3 of hydrate releases 0.8 m3 of liquid water when it is dissociated, and 1 volume of

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liquid water forms 1.25 volumes of hydrate under standard temperature and pressure

218

(STP) (Jr and Koh, 2007). Hence, the MH saturation at the “i” minute can be

219

computed with the following equation (Chen et al., 2019b):

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S hi = 1.25 ×

221

where

222

values in the images at t = 0 and t = i minutes, respectively. The details of hydrate

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saturation for each case are shown in Table 1.

(I 0 − I i )× S w0 × 100 %

S w0

(2)

I0

represents the initial water saturation, and

I0

and

Ii

represent the MI

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Because of a similar phenomenon, take Case 2 as an example to illustrate the

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MH formation process. Fig. 2 shows the MI variation during MH formation process,

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which reflected the amount of free water in porous media. Moreover, three MRI

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images were used to visually show the liquid water distribution during different stages

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of MH formation. Bright red and dark purple represent the brightest (more water) and

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darkest (more hydrate) signals, respectively. As shown in Fig. 2, the MI was stable at

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stage I and liquid water distribution in the MRI image was uniform, indicating there

231

was no hydrate formation and water saturation remained invariant. At stage II, the MI

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first appeared to rapidly decline (points A~B) and then the downtrend became a slight

233

slowdown (points B~C). Meanwhile, the MRI image was darker than stage I. This

234

was because that when the MH starts to form, the rapid hydrate formation obviously

235

consumes the amount of liquid water and decreases the MI value. Then, MH

236

formation influences the contact between the gas phase and liquid water, so hydrate 12

237

formation rate slows down. When the hydrate formation is completed, the MI

238

gradually comes to stability at stage III and the image becomes the darkest. From the

239

MRI images, it can be observed that MH formation is nonuniform in porous media

240

because there is always migration of water and gas in the MH formation process.

241

Moreover, MI was nonzero after MH formation completion, indicating that residual

242

water still exists in porous media.

243 244 245

Fig. 2 Variations of MI and water distribution during MH formation process 3.2 Effects of different seawater-gas flow rates on MH dissociation

246

In our previous study (Yang et al., 2019a), when the deionized water-gas flow

247

rate was 1-1 ml·min-1, MH did not dissociate and even the hydrate reformation

248

phenomenon appeared during the deionized water-gas flow. However, MH always

249

dissociates during the seawater-gas flow process even if the seawater-gas flow rate is

250

slower, which suggests the seawater-gas flow obviously promotes MH dissociation 13

251

and inhibits MH reformation. There are two reasons explaining this phenomenon. The

252

first is the seawater solution ion effect that forms an electric field between positive

253

and negative ions to destroy the cluster structure of water molecules. When the water

254

molecules form a lattice, they overcome the electric field and further shift the hydrate

255

phase equilibrium curve to the left (Yang et al., 2012, Chong et al., 2017b), as shown

256

in Fig. 3 the MH hydrate phase equilibrium curve under the seawater and deionized

257

water experimental condition. Therefore, compared to deionized water-gas flow

258

process, hydrate stability decreases and easily dissociates in the seawater-gas flow

259

process. The second is that the bonds between water and ions are Coulombic that

260

stronger than hydrogen bonding or van der Waals forces (Yang et al., 2012),

261

resulting in water molecules were attracted by ions and further reduce the water

262

molecular activity (Atik et al., 2006). Moreover, the accumulation of Cl- decreases gas

263

molecule solubility in seawater. The phenomenon of salting-out appeared (Chen et al.,

264

2017, Kim et al., 2008) with a negative effect on hydrate reformation. Based on the

265

above discussion, recycling seawater-gas flow was effective for gas hydrate

266

production.

14

267 268

Fig. 3 MH phase equilibrium curves under the seawater and deionized water

269

experimental condition

270

Fig. 4 shows the variation of water distribution during MH dissociation with

271

continuous seawater-gas flow, in which the seawater-gas flow rates were 1-1 (Case 1),

272

2-2 (Case 2), 3-3 (Case 3), 3-1 (Case 4), 4-1 (Case 5), 5-1 (Case 8), and 10-1

273

ml·min-1(Case 6), respectively. Moreover, bright green signals represent liquid water,

274

and dark blue signals are MH and a small quantity of methane gas. As shown in Fig. 4,

275

MH dissociated gradually with the seawater-gas flow process. At 2 min, the

276

hydrate-bearing sediment core was saturated by seawater, and the dark blue image

277

suggested there was no hydrate dissociation. With continuous seawater-gas flow, the

278

images showed a partial bright green area, illustrating hydrate dissociated and water

279

saturation increased. Then, the bright area gradually enlarged along the

280

seawater-gas-hydrate three phase interface until the whole image became bright.

15

281

When the whole image became bright (corresponding to the last image), the MH

282

dissociation was finished and the water saturation in porous media reached maximum.

283

Fig. 4 also showed that when the seawater-gas flow rate was 1-1, 2-2 and 3-3

284

ml·min-1 (Cases 1-3), the duration of hydrate dissociation was relatively long. When

285

the flow rate was 10-1 ml·min-1 (Case 6), the duration was the shortest for

286

dissociating hydrate. That is, the higher seawater flow rate and lower gas flow rate

287

will accelerate MH dissociation process. The reasons are addressed below. The first

288

was that seawater salt invades the hydrate-dissociated water due to the concentration

289

difference, and the salt contamination resulted in a better heat conduction (Sun and

290

Mohanty, 2006, Chong et al., 2015). The second was the faster heat transfer during

291

seawater-gas flow process. Because the hydrate dissociation is an endothermic

292

reaction process, a lot of heat can be absorbed when the hydrate suddenly dissociated

293

and caused a rapid decline of hydrate-bearing sediment temperature, even caused the

294

hydrate reformation and ice generation. During the continuous seawater-gas flow

295

process, the temperature of flowing seawater and gas (273.95 K) was constant, which

296

can provide continuous heat transfer and keep the stability of sediment temperature.

297

Therefore, the plummeting temperature of hydrate-bearing sediment cores was not

298

appeared, which is benefit for the hydrate dissociation process, and further preventing

299

the hydrate reformation and ice generation. The third was that increasing the seawater

300

flow rate and decreasing the gas flow rate will increase the chemical potential

16

301

difference, accelerate the seawater phase mass transfer and further provide higher

302

driving force for dissociating hydrate.

303 304

Fig. 4 Variations of water distribution during MH dissociation process with different

305

seawater-gas flow rates

306

Fig. 5 shows the variations of MI during MH dissociation with different

307

seawater-gas flow rates, which reflected the amount variations of free water in porous

308

media. As shown in Fig. 5, the MI increased to approximately 1200 within a few

309

minutes at points A~B. This was because that after hydrate formation process, little

310

amount free water distributed in sediment, the large amount of free gas, sand and

311

hydrate caused the lowest value of MI. Then, when the seawater phase flow into the

312

sediment, the increase of the amount of free water caused the sharp increase of MI

313

Next, the MI appeared a sharp change under the seven flow rates, in which the MI 17

314

suddenly decrease and then gradually increase. The reasons for the phenomenon are

315

as follows. Firstly, due to the Jamin effect (Wang et al., 2016a, Yang et al., 2019a),

316

some parts of free gas still distributed under the area of field view (FOV), these parts

317

of free gas will be further displaced into the FOV by seawater. Because the MRI

318

system can only identify the 1H containing in liquid, so the gas gathered in FOV

319

caused the MI decrease. Secondly, with the continuous seawater flow, the hydrate will

320

gradually dissociate and the free water will gradually obtain the released pore space,

321

and ultimately caused the MI gradually increase. In Fig. 5 (a), when the seawater-gas

322

flow rate was 1-1 ml·min-1, the upward tendency of MI was the slowest at points B~

323

C1. In Fig. 5 (b), there has a rapidly increase of MI at points B~C (C4, C5), which

324

indicated the MH dissociation under the seawater-gas flow rates of 3-1 and 4-1

325

ml·min-1 was significantly faster than the results of in Fig. 5(a). Moreover, with the

326

flow rate further increased (5-1 and 10-1 ml·min-1), the variation of MI transforms

327

into the tension trend at points B~C (C6, C7) because of the quickening MH

328

dissociation. Finally, when the hydrate was dissociated completely, the amount of

329

water in the pore space was invariable and the MI was stable. In addition, the higher

330

seawater flow rate and the lower gas flow rate, the faster for MI reached stability.

331

Combined Figs. 4 and 5, jointly proves that seawater-gas flow can effectively promote

332

MH dissociation.

18

333 334

Fig. 5 Variations of MI during MH dissociation process with different seawater-gas

335

flow rates

336

The average MH dissociation rate is a main parameter reflecting the average gas

337

and water production rates. Fig. 6 shows comparisons of average MH dissociation rate

338

with different seawater-gas flow rates. As shown in Fig. 6, the average MH

339

dissociation rate is a function of the seawater-gas flow rate ratio and pour seawater

340

flow rate, which increased with the increase of flow rate ratio and pore seawater flow

341

rate. When the seawater-gas flow rate was 1-1, 2-2 and 3-3 ml·min-1, the MH

342

dissociation rate increased slowly. Moreover, there was a fast-increasing trend for the

343

MH dissociation rate with increasing seawater flow rate and decreasing gas flow rate.

344

When the flow rate was highest (10-1 ml·min-1), it induced the largest average MH

345

dissociation rate of 0.705 %/min. According to the trend of average MH dissociation

346

rate, the seawater flow rate was the main factor promoting hydrate dissociation, and

347

increasing the gas flow rate retards the dissociation process. That is, MH dissociation

348

from seawater-gas flow increased with higher flow rate ratio and seawater flow rate.

19

349

The reason is faster heat and mass transfer in hydrate-bearing sediment cores with

350

increasing seawater-gas flow rate ratio and seawater flow rate, providing greater

351

driving force to promote hydrate dissociation. So, it can be inferred that the

352

seawater-gas flow rate of 10-1 ml·min-1 in Case 6 effectively promotes MH

353

dissociation.

354 355

Fig. 6 Comparisons of average MH dissociation rates with different seawater-gas flow

356

rates

357

3.3 MH flow process dissociation behavior with different initial MH saturation

358

To investigate MH dissociation with different initial hydrate saturation, six

359

experiments were carried out with initial MH saturations of 15% (Case 7), 23% (Case

360

8), 28% (Case 9), 31% (Case 10), 36% (Case 11), and 41% (Case 12). Fig. 7 shows

361

the variations of water distribution and MI during MH dissociation induced by

20

362

seawater-gas flow with different initial hydrate saturation, in which the seawater-gas

363

flow rate was 5-1 ml·min-1. As shown in Fig. 7 (a), with the same seawater-gas flow

364

rate, the time to dissociate MH (corresponding to the second image) and the time to

365

dissociate MH completely (corresponding to the last image) all increased with

366

increasing initial hydrate saturation. Combined with the MI variation during MH

367

dissociation in Fig. 7 (b) a sharp MI change first appeared, and the reason have been

368

discussed in section 3.2. Then, it increased gradually with hydrate dissociation, and

369

took more time for the MI to reach stability with higher initial hydrate saturation. In

370

addition, when the hydrate dissociated completely, the MI remains stable and the

371

maximum MI value decreases slightly with increasing initial hydrate saturation. This

372

is because that there was a relatively slow hydrate dissociation process under higher

373

initial saturation that caused more gas dissolving in liquid water and further decreased

374

the maximum value of the MI. Fig. 7 suggest that the duration of hydrate dissociation

375

was longest under higher initial hydrate saturation. There are three reasons for this

376

phenomenon. The first is hydrate imperviousness (Liu et al., 2016), higher initial

377

hydrate saturation maintains hydrate-bearing sediment core stability better. The

378

second was that MH occupies more pore space in porous media under higher initial

379

hydrate saturation, which decreases the fluid flow space and water phase relative

380

permeability, further influencing the heat and mass transfer. The third was that there

381

has a higher chemical potential difference between the seawater and hydrate phases

382

when the initial hydrate saturation is lower. As reported (Sean et al., 2007), the 21

383

chemical potential difference was the main reason for hydrate dissociation in marine

384

environment above hydrate phase equilibrium, which was defined as the methane

385

concentration dissolved in the aqueous. During seawater-gas flow process, though

386

little methane gas dissolved in flowing seawater, the chemical potential difference still

387

enough for inducing hydrate dissociation. And the seawater-gas flow erosion was a

388

long-time and continuous process, thereby, the residual free water and gas will be

389

displaced at last. When the hydrate saturation is lower, the blocking effect of hydrate

390

on seawater flow was relatively small, so the displace process of free water will be

391

faster, which caused the chemical potential difference increase and accelerated the

392

hydrate dissociation.

393 394

Fig. 7 Variations of water distribution (a) and MI (b) during MH dissociation induced

395

by seawater-gas flow with different initial hydrate saturation

396

The average dissociation rate is an important parameter in hydrate exploitation

397

and it is the ratio of hydrate saturation to dissociation duration (Wang et al., 2018).

398

Fig. 8 shows the comparisons of average MH dissociation rate induced by 22

399

seawater-gas flow with different initial hydrate saturation. As shown in Fig. 8, the

400

MH dissociation rate has no obvious linear relationship with initial hydrate saturation,

401

and the initial hydrate saturation has a mild effect under the same seawater-gas flow

402

rate. This is because the MH dissociation rate is controlled by hydrate saturation and

403

dissociation duration. Even though hydrate dissociates quickly, the average

404

dissociation rate will not increase significantly due to lower hydrate saturation. In

405

contrast, when hydrate saturation is higher, there also is no high MH dissociation rate

406

because of the relatively long dissociation duration. Furthermore, the occurrence

407

structure of hydrate may influence the dissociation behavior. Because the pore-filling

408

hydrate has more surface area to retard fluid flow, there was a smaller water phase

409

permeability than grain-coating hydrate (Dai and Seol, 2014), which may influence

410

the MH dissociation rate, but this phenomenon was less evident in this study.

411

23

412

Fig. 8 Comparisons of average MH dissociation rate with different initial hydrate

413

saturation

414

3.4 Comparisons of seawater/deionized water-gas flow effects on MH dissociation

415

The flow channel appearance and disappearance time represents the time at

416

which the MH begins to dissociate and the end of MH dissociation. The flow channel

417

appearance time was defined as the moment that a small bright area appeared, as

418

shown in the second images in Fig. 4 and Fig 7 (a). The flow channel disappearance

419

time is defined as the moment that the whole image became bright, as shown the last

420

images in Fig. 4 and Fig 7 (a). The shorter the appearance and disappearance times,

421

the faster the hydrate dissociation. Fig. 9 shows comparisons of flow channel

422

appearance and disappearance times between seawater-gas and deionized water-gas

423

flow. As shown in Fig. 9, the flow channel appearance and disappearance time

424

obviously decreased with increasing water flow rate both in seawater-gas and

425

deionized water-gas flow condition. Moreover, the flow channel appearance and

426

disappearance time in deionized water-gas flow was longer than that of in

427

seawater-gas flow under the same flow rate, especially in the deionized water-gas

428

flow rate of 2-2 ml·min-1. The reasons for the above phenomenon are as follows.

429

Firstly, under the same temperature, Na+ and Cl- can obviously improve the methane

430

hydrate phase equilibrium pressure (as shown in Fig. 3), which induced a stronger

431

promotion effect in seawater-gas flow on hydrate dissociation than the deionized

432

water-gas flow. Secondly, due to the existence of ions, the CH4 gas solubility in 24

433

seawater than that of in deionized water (Chen et al., 2017, Kim et al., 2008), which

434

caused the larger chemical potential difference between seawater-hydrate phase and

435

further provided the stronger driving force for MH dissociation. Thirdly, in our

436

previous work (Chen et al., 2019b, Chen et al., 2019a, Yang et al., 2019a), we found

437

that the water flow rate was the main reason for hydrate dissociation above the

438

hydrate phase equilibrium. The higher water flow rate will accelerate hydrate

439

dissociation rate by increasing the chemical potential difference and enhancing heat

440

and mass transfer process. So, compared to others flow rate (3-3, 3-1, 4-1, 5-1

441

ml·min-1), the lower water flow rate in the deionized water-gas flow rate of 2-2

442

ml·min-1 provided a smaller driving force for hydrate dissociation and induced a huge

443

number of disappearance time.

444 445

Fig. 9 Comparisons of flow channel appearance and disappearance time of between

446

seawater-gas and deionized water-gas flow

25

447

Fig. 10 shows comparisons of average MH dissociation rates between the

448

seawater-gas and deionized water-gas flow processes. The experimental result and

449

details of deionized water-gas flow process can be found in published article (Yang et

450

al., 2019a). As shown in Fig. 10, the average MH dissociation rates with five flow

451

rates were compared, including 2-2, 3-3, 3-1, 4-1, and 5-1 ml·min-1. In two

452

experimental conditions (seawater/deionized water-gas flow), the MH dissociation

453

rate increased with the increase of water flow rate and the decrease of gas flow rate,

454

and the MH dissociation rate in the seawater-gas flow process was far greater than

455

that in deionized water-gas flow under the same flow rate. This phenomenon

456

indicated that the seawater-gas flow experimental conditions promote MH

457

dissociation more significantly than deionized water-gas flow. The reason was that the

458

Cl- implants into the water cage and attracts H+ from water molecules, which breaks

459

the hydrogen bonding structure of the water cage and accelerates hydrate dissociation

460

(Chong et al., 2015).In addition, because salt reduces methane gas solubility (Yang

461

and Xu, 2007), the injection and hydrate-dissociated gases form bubbles in seawater

462

(Chong et al., 2015). In contrast, the methane gas dissolved more uniformly in

463

deionized water. Therefore, there was larger methane concentration between the

464

seawater and hydrate phases during the seawater-gas flow process, which obviously

465

increased the chemical potential difference, and provided a crucial driving force for

466

hydrate dissociation.

26

467 468

Fig. 10 Comparisons of average MH dissociation rate between seawater-gas and

469

deionized water-gas flow

470

3.5 The application and shortage of seawater-gas flow inducing MH dissociation

471

This study verified the promotion effect of seawater-gas flow on hydrate

472

dissociation. The seawater-gas flow can increase the chemical potential difference,

473

accelerate the heat and mas transfer process, and inhibit hydrate reformation, which

474

have great application potential in actual hydrate production tests. In nature, four main

475

classes (Class 1, Class 2, Class 3, Class 4) of methane hydrate deposits are found

476

(Moridis et al., 2004). For Class 1 deposits (upper hydrate layer and under free gas

477

layer), the gas phase ratio was much higher than that of water phase during hydrate

478

production process. For Class 2 deposits (upper hydrate layer and under free water

479

layer), the water phase ratio was much higher than that of gas phase during hydrate

480

production process. For Class 3 and Class 4 deposits (no free water and gas layer), the 27

481

hydrate production process will always companied company with the huge production

482

of water and gas. It is surely that the issue of water production is a sticky point in the

483

hydrate production tests. Therefore, in the actual hydrate exploitation tests, we can

484

utilize the hydrate dissociated-water and can extra inject some seawater into the

485

hydrate deposits to induce hydrate dissociation. The seawater flow rate can be

486

controlled by adjusting the pressure difference between the production wells, and the

487

gas recovery rate also can be adjusted to achieve the seawater-gas two-phase flow. In

488

addition, considering to the hydrate production efficiency, the seawater-gas two-phase

489

flow can be used to combine with other production methods (depressurization) for

490

real applications, and which will be investigated in our follow-up work.

491

However, there are also exist some limitations by using seawater to dissociate

492

hydrate in real applications. Firstly, there will be need huge seawater injection amount

493

if the water flow erosion method was performed to recovery natural gas in the field

494

hydrate production test. Secondly, in order to avoid the reservoir collapse caused by

495

fast hydrate dissociation, the suitable seawater flow rate and flow direction of

496

seawater flow should be verified in the real hydrate production test. Thirdly, seawater

497

flow may induce outflow sand and influent the continuous gas production, this issue

498

also needs solve. Therefore, the results obtained from our test section translatable to

499

the real case still exist some difference. The current study was a fundamental study,

500

we will further investigate the effect of water-gas two-phase flow on hydrate

501

dissociation by increasing the experimental scale. 28

502

4. Conclusion

503

A seawater-gas flow experiment was carried out and the effect of seawater-gas

504

flow rate and initial hydrate saturation on MH dissociation was analyzed. The

505

experimental conclusions are as follows:

506

(1) When the flow rate was 1-1 ml·min-1, the seawater-gas flow process promotes

507

MH dissociation because of the ion and salting-out effects, whereas MH was not

508

dissociated and hydrate reformation even appeared in the deionized water-gas flow

509

process. It was shown that seawater-gas flow achieves gas production from hydrate

510

reservoirs and effectively inhibits hydrate reformation under slower flow rates.

511

(2) With the same initial hydrate saturation, the seawater-gas flow rate ratio and

512

pour seawater flow rate were the crucial factor for MH dissociation. The higher

513

seawater flow rate and lower gas flow rate cause higher average MH dissociation

514

rates due to the acceleration of heat and mass transfer. In addition, salt ions reduce gas

515

solubility and water activity further promoting hydrate dissociation.

516

(3) With the same seawater-gas flow rate, the time to induce MH to dissociate

517

and the total time for completing MH dissociation all increased with increasing initial

518

hydrate saturation. According to the trend of the average MH dissociation rate under

519

different initial hydrate saturation, hydrate saturation has a mild effect on the average

520

MH dissociation rate.

521

(4) Seawater-gas flow promotes MH dissociation stronger than deionized

522

water-gas flow. During seawater-gas flow, the duration of hydrate dissociation 29

523

decreased and the average MH dissociation rate increased with higher seawater-gas

524

flow rate ratio and higher seawater flow rate. Moreover, the average MH dissociation

525

rate in seawater-gas flow was higher than in deionized water-gas flow.

526

Acknowledgments

527

This study was financially supported by grants from the National Natural

528

Science Foundation of China (51436003, 51822603 and 51576025), the National Key

529

Research and Development Plan of China (2017YFC0307303 and 2016YFC0304001),

530

the Fok Ying-Tong Education Foundation for Young Teachers in Higher Education

531

Institutions of China (161050) and the Fundamental Research Funds for the Central

532

Universities of China (DUT18ZD403).

533

Conflict of interest

534

None declared

535

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methane hydrate formation and dissociation in porous medium with different

696

particle sizes using depressurization. Fuel, 230, 37-44.

697

ZHAO, J. F., LIU, D., YANG, M. J. & SONG, Y. C. 2014. Analysis of heat transfer

698

effects on gas production from methane hydrate by depressurization.

699

International Journal of Heat and Mass Transfer, 77, 529-541.

700

ZHAO, J. F., YE, C. C., SONG, Y. C., LIU, W. G., CHENG, C. X., LIU, Y., ZHANG,

701

Y., WANG, D. Y. & RUAN, X. K. 2012. Numerical simulation and analysis

702

of water phase effect on methane hydrate dissociation by depressurization.

703

Industrial & Engineering Chemistry Research, 51, 3108-3118.

704

ZHAO, J. F., ZHU, Z. H., SONG, Y. C., LIU, W. G., ZHANG, Y. & WANG, D. Y.

705

2015. Analyzing the process of gas production for natural gas hydrate using

706

depressurization. Applied Energy, 142, 125-134.

707

ZHENG, J. N., CHENG, F. B., LI, Y. P., LV, X. & YANG, M. J. 2019. Progress and

708

trends in hydrate based desalination (HBD) technology: A review. Chinese

709

Journal of Chemical Engineering.

710 711 36

712

37

713

Effect of multiphase flow on natural gas hydrate production in marine sediment

714

Huiru Sun, Bingbing Chen, Mingjun Yang*

715

Key Laboratory of Ocean Energy Utilization and Energy Conservation of Ministry of

716

Education, Dalian University of Technology, Dalian 116024, China

717 718

Abstract Natural gas hydrates (NGHs), regarded as an alternative future energy

719

source. Currently, tests for hydrate exploitation from marine sediment have been

720

performed in the Nankai Trough of Japan and the Shenhu area of the South China Sea.

721

Hydrate exploitation is influenced by water-gas flow, and considering the huge

722

seawater reserves in hydrate accumulation areas, an experiment of seawater-gas flow

723

was performed to dissociate hydrate. The effects of seawater-gas flow rates and initial

724

hydrate saturation on methane hydrate (MH) production was analyzed. The results

725

showed that seawater-gas flow efficiently promotes hydrate dissociation and inhibits

726

hydrate reformation. Moreover, there was a faster heat and mass transfer with

727

increasing seawater flow rates and decreasing gas flow rates, which enhanced the

728

average MH dissociation rate. In addition, the variation time of the flow channel

729

increased with higher initial hydrate saturation. Additionally, seawater-gas flow

730

promotes MH dissociation stronger than deionized water-gas flow.

731

Keywords: methane hydrate dissociation; water flow erosion; seawater-gas flow; salt

732

ions; hydrate saturation

38

733

1. Introduction

734

Natural gas hydrates (NGHs) are typically found in continental permafrost and

735

marine sediment and they form from hydrocarbon gas and water under high pressure

736

and low temperature (Hiratsuka et al., 2015, Gao et al., 2018). The water molecules

737

interconnected through hydrogen bonding form cage structures to encage gas

738

molecules (Zheng et al., 2019, Saman et al., 2010, Liu et al., 2018). There are rich

739

natural gas hydrate reservoirs distributed around the world, in which the estimated

740

energy potential is far greater than the total amount of conventional coal, oil and

741

natural gas (Wang et al., 2017). NGHs are seen as potential sources of natural gas in

742

view of their high energy density, abundant reserves and nonpollution (Zhao et al.,

743

2014, Xu and Li, 2015). Therefore, researching hydrate formation and dissociation

744

kinetics and developing methods for natural gas recovery from hydrate reservoirs are

745

arousing wide concern in countries and among scientists all over the world in recent

746

years (Wang et al., 2016b, Song et al., 2015b).

747

For now, methods for large-scale production of natural gas from NGHs are still

748

evolving, and they are all based on changing reservoir pressure and temperature to

749

deviate from hydrate thermodynamic equilibrium (Ji et al., 2001). There are four

750

common methods for gas hydrate exploitation as follows. The depressurization

751

method, in which the reservoir pressure is decreased below the hydrate equilibrium

752

pressure at a specified temperature (Reagan et al., 2015, Li et al., 2012, Yang et al.,

753

2019b). The thermal stimulation method, in which the reservoir temperature is 39

754

increased above the hydrate equilibrium temperature via injecting hot water, hot brine

755

or steam (Song et al., 2015a, Nair et al., 2016, Chong et al., 2016b). The chemical

756

inhibitor stimulation method, in which chemicals are injected into the hydrate

757

reservoir to transform the hydrate pressure-temperature equilibrium and promote

758

hydrate dissociation (Li et al., 2011, Chong et al., 2016a). The CO2 replacement

759

method, in which liquid CO2 is injected into hydrate reservoirs to form CO2 hydrate

760

and replace methane gas (Yu et al., 2015, Brewer et al., 2014). The above methods all

761

have their own merits and demerits. The large heat loss of thermal stimulation, the

762

expensive cost and pollution environment of chemical inhibitors, and the low

763

efficiency of CO2 replacement restricts application of those three methods for

764

practical hydrate exploitation (Fitzgerald et al., 2014, Lee et al., 2010, Jung et al.,

765

2010). However, depressurization needs no external energy supply and energy

766

consumption is the least, so that was regarded as the most effective method to recover

767

natural gas from NGH reservoirs considering the economic cost (Chong et al., 2017a,

768

Zhao et al., 2014).

769

The depressurization method was first used for field-scale hydrate production at

770

the Mackenzie Delta Mallik site in the Northwest Territories, Canada, and then a

771

larger-scale test was conducted at the same site in 2007 and 2008 (Yang et al., 2016).

772

However, the hydrate dissociation is an endothermic reaction. When the pressure drop

773

is large, the sensible heat of the hydrate and heat transferred from the ambient

774

environment was not enough to sustain the faster hydrate dissociation reaction. So, 40

775

there may occur the hydrate reformation and ice generation in depressurization

776

process, which will obviously influent the gas production rate (Wang et al., 2018,

777

Zhao et al., 2015, Chen et al., 2015). Therefore, many experimental studies and

778

numerical modeling of hydrate dissociation and gas production using depressurization

779

were conducted. Konno et al. (Konno et al., 2014) performed the gas production test

780

on methane hydrate sediments using one-step and multistep depressurization. They

781

found that a suitable heat for hydrate-bearing sediment is the important factor to drive

782

hydrate dissociation. Zhan et al. (Zhan et al., 2018) used different quartz sand particle

783

sizes to simulate hydrate reservoirs, form methane hydrate, and dissociate hydrate via

784

the depressurization method. They analyzed and compared the effects of sediment

785

particle size on gas production rate and dissociation characteristics. Zhao et al. (Zhao

786

et al., 2012) conducted numerical simulations to investigate the water phase impact on

787

methane hydrate dissociation by depressurization in porous media. Their experimental

788

results showed that the movement of water plays a significant role in late stage

789

thermal conduction, and the gas production rate increased with higher water saturation

790

in late stage dissociation. Based on the available data in the Shenhu Area of the South

791

China Sea, Xiong et al. (Xiong et al., 2012) employed a 1D experimental setup to

792

study methane hydrate dissociation by depressurization, and they found that lower

793

dissociation pressure may lead to higher hydrate dissociation rate and higher

794

dissociation heat. Oyama et al. (Oyama et al., 2012) studied the depressurized

795

dissociation of natural methane-hydrate-bearing sediment with low permeability, and 41

796

they assessed two dissociation models making use of their experimental results. To

797

acquire kinetic hydrate dissociation data under different backpressures, depressurized

798

dissociation of methane hydrate was studied using magnetic resonance imaging (MRI)

799

by Wang et al. (Wang et al., 2015). For the other three hydrate dissociation methods,

800

Su et al. (Su et al., 2013) investigated the gas production potential from hydrate

801

sediment using thermal stimulation. They found that thermal stimulation was effective

802

at promoting gas release from hydrate sediment and enhanced gas production in the

803

late stage of hydrate dissociation. Li et al. (Li et al., 2017) injected methanol into

804

methane-hydrate-bearing sediment to study dissociation behavior employing a

805

one-dimensional experimental device. They proposed new adjustment tactics for

806

experimental operation according to the injection rate ratio of methanol and water.

807

Jung et al. (Jung and Santamarina, 2010) measured the electrical resistance change

808

and relative stiffness in the CH4-CO2 replacement process, and found that the overall

809

hydrate remained solid and gas-hydrate-water phases coexisted for long periods of

810

time. Yuan et al. (Yuan et al., 2013) used a three-dimensional reactor to study

811

CO2-CH4 replacement in hydrate-bearing deposits with liquid CO2, and analyzed the

812

influence of different stratum conditions on the replacement process.

813

Whatever NGH exploitation methods are adopted, hydrate dissociation is always

814

accompanied by production and migration of water and gas. Chen et al. (Chen et al.,

815

2019b) proposed a water flow erosion method to promote hydrate dissociation and

816

investigated the effects of seawater flow on natural gas hydrate dissociation (Chen et 42

817

al., 2019a), whereas the effect of gas migration on hydrate dissociation was ignored.

818

In addition, deionized water-gas two-phase flow promotion of MH dissociation has

819

been studied, and hydrate reformation may appear under slower water-gas flow rates.

820

Therefore, based on those studies and considering the effect of seawater on hydrate

821

thermodynamic equilibrium, experiments of seawater-gas two-phase flow were

822

performed, and different seawater-gas flow rates effect on MH dissociation were

823

analyzed. In addition, the system pressure and temperature are always in the

824

thermodynamic stability region of the hydrate-bearing sediment core. Due to the huge

825

seawater reserves in hydrate accumulation areas, the method of seawater-gas flow to

826

dissociate hydrate is achievable, so the experimental results offer some reference and

827

guidance for future NGH exploration in marine environments.

828

2. Experiments

829

2.1 Apparatus and materials

830

Fig. 1 shows a sketch of the experimental setup designed to investigate MH

831

dissociation during seawater-gas two-phase flow. The experimental setup included an

832

MRI system (Varian, Inc., Palo Alto, CA, USA), a high-pressure vessel (polyimide),

833

three high-precision injection pumps (260D, Teledyne Isco Inc., Lincoln, NE, USA),

834

three thermostat baths (FL300 and FL 25, JULABO, Seelbach, Germany), two pressure

835

transducers (3510CF, Emerson Electric Co., Ltd., St. Louis, USA), a differential

836

pressure sensor (Nagano Keiki, Japan), and a data acquisition system. The MRI system

837

was used to visualize the change of MH distribution during seawater-gas flow, which 43

838

was operated at 400 MHz resonance frequency and 9.4 T magnet field. This MRI

839

system adopted a spin echo sequence to obtain two-dimensional proton

840

density-weighted images. The parameters of the sequence are as follows, which based

841

on Chen et al. (Chen et al., 2019a). Echo time was 4.39 ms, image data matrix was

842

128×128, and the field of view was 30 mm×30 mm (Chen et al., 2019a). Three injection

843

pumps were used to inject liquid, CH4 gas and to control the vessel pressure for

844

seawater-gas flow. The effective volume of injection pump was 260 ml, the accuracy of

845

flow control was ±1 µl·min-1, and accuracy of pressure control was ± 0.5%. The

846

temperatures of the pumps and MRI system were strictly controlled by thermostat baths,

847

and the stability of the thermostat baths was ±0.1

848

differential pressure sensor were used to collect pressure signals in the inlet and outlet

849

of the high-pressure vessel. The accuracy of the pressure transducers was ±0.05%, and

850

the accuracy of the differential pressure sensor was ±0.01%. The data acquisition

851

system included an A/D module (Advantech Co., Ltd., Milpitas, CA, USA) and a

852

computer, which was used to collect and dispose the pressure signals. Deionized water

853

and CH4 gas were used to form methane hydrate (MH). Seawater (configured by

854

deionized water) and CH4 gas were used in the MH dissociation process.

44

. Pressure transducers and a

855 856 857

Fig. 1 Schematic of the experimental system 2.2 Hydrate formation

858

A high-pressure vessel with inner diameter of 15 mm and length of 200 mm was

859

washed, dried, and filled with BZ-02 glass beads (As-One Co., Ltd., Japan). The

860

porosity of BZ-02 glass beads was 35.4%, the particle diameter was 0.177-0.250 mm

861

and the density of BZ-02 was 2.6 g·cm-3. After the leakage test, the vessel was

862

mounted in the center of the MRI magnetic body and vacuumed to expel free gas.

863

Next, the vessel was pressurized to 6000 kPa using water injection pump with a

864

constant injection rate of 20 ml·min-1 to fully saturate the porous media. After

865

maintaining the pressure stable for 1 h, the outlet valve was opened, and the vessel

866

pressure equaled to atmospheric pressure. Then, CH4 gas (Dalian Special Gases Co.,

867

Ltd., China, 99.99%) with 4000 kPa pressure was injected into the vessel to displace

868

the deionized water and obtain partly water-saturated porous media. Then, the vessel

869

was pressurized to 6000 kPa by CH4 gas injection with a constant injection rate of 20

45

870

ml·min-1 and maintained stable to form MH. During the whole process of hydrate

871

formation, the thermostat bath temperature was kept at 274.15 K. Moreover, the

872

images were obtained continuously via MRI for each experiment.

873

2.3 Seawater-gas two-phase flow process

874

The experimental parameters and results of twelve experimental cases are shown

875

in Table 1. Take Case 1 as an example to illustrate the seawater-gas two-phase flow

876

process. The seawater solution (NaCl solution with a mass fraction of 3.5%) was

877

prepared before the experiment. After hydrate formation finished, the outlet valve was

878

opened to interconnect backpressure pump to the vessel. Then, the pressure of

879

backpressure pump was decreased to 3200 kPa form 6000 kPa using backpressure

880

pump with a constant rate of -20 ml·min-1, and maintained that pressure for a while to

881

ensure that no MH dissociation appeared in the pressure adjustment process. When

882

the temperature is 274.15 K, the MH phase equilibrium pressure is 2850 kPa (Jr and

883

Koh, 2007). Therefore, the hydrate was always thermodynamically stable during the

884

backpressure adjustment process. Next, seawater (1ml·min-1) and CH4 (1ml·min-1)

885

were simultaneously injected into the vessel from the bottom to the top by seawater

886

injection pump and gas injection pump. The temperature of the flowing seawater and

887

CH4 gas was controlled at 273.95 K by thermostat bath to prevent hydrate dissociation

888

caused by temperature variation. Images of seawater-gas flow were recorded in

889

succession using an MRI system. In addition, after the seawater-gas flow process,

890

deionized water was used to wash the whole experimental system (pipelines, seawater 46

891

injection pump and high-pressure vessel) approximately 5~6 times till the

892

conductivity was lower than 0.69 µS·cm-1, which avoided residual seawater inhibiting

893

hydrate formation. The conductivities of seawater and deionized water were 2.85*104

894

µS·cm-1 and 0.69 µS·cm-1, respectively(Chen et al., 2019a).

895

Table 1. Experimental parameters and results Case 1 2 3 4 5 6 7 8 9 10 11 12

896 897 898 899 900 901 902

vw (ml/min) 1 2 3 3 4 10 5 5 5 5 5 5

vg (ml/min) 1 2 3 1 1 1 1 1 1 1 1 1

Pi (kPa) 6010 6015 6020 6010 6000 6005 6020 6011 6040 6060 6030 6050

Shi (%) 24.33 23.03 22.42 23.83 23.77 22.56 15.48 22.50 28.19 31.08 36.23 41.48

tapp (min) 80 46 38 24 14 10 8 12 14 14 20 26

tdis (min) 986 532 290 136 88 42 50 68 100 108 112 132

RV (%/min) 0.0269 0.0474 0.0890 0.2128 0.3212 0.7050 0.3686 0.4018 0.3278 0.3306 0.3938 0.3913

a

The symbols in this table are defined as follows: tapp is the flow channel appearance time; tdis is the flow channel disappearance time; Vw is the seawater flow rate during seawater-gas two-phase flow; Vg is the gas flow rate during seawater-gas two-phase flow; Shi is the initial MH saturation before hydrate dissociation (volume fraction); Pi is the MH formation pressure; and Rv is the average MH dissociation rate. All experiments were carried out at 274.15 K, the temperature of flowing seawater and gas was kept at 273.95 K, and the designed backpressure was 3200 kPa for all cases during the seawater-gas flow process.

903

In this study, the average MH dissociation rate was calculated by the flowing

904

equation (Wang et al., 2018), which can reflect the average water and gas production

905

rates.

906

Ri =

S hi − S h (i + ∆t )

(1)

∆t

47

907

where

908

and

909

the two changes of hydrate saturation.

910

3. Results and Discussion

S

Ri

is the MH dissociation rate at i min,

h  i + ∆ t 

S hi

is the hydrate saturation at i min

are the hydrate saturation at i + ∆t min. ∆t is the time interval between

911

Twelve experimental cases were performed to study the effects of different

912

seawater-gas flow rates and different initial hydrate saturations on MH dissociation.

913

The seawater-gas flow rate was expressed as the seawater flow rate-gas flow rate in

914

this study. In Cases 1~6, the MH saturation was controlled approximately the same

915

(22.5%~23.5%), and the seawater-gas flow rate of that was set to 1-1, 2-2, 3-3, 3-1,

916

4-1, and 10-1 ml·min-1, respectively. In Cases 7~12, the seawater-gas flow rates were

917

all set to 5-1 ml·min-1, and the MH saturation was controlled to approximately 15%,

918

23%, 28%, 31%, 36%, and 41%, respectively. The backpressure was controlled at

919

3200 kPa for all cases, and the temperature of flowing seawater and gas was set to

920

273.95

921

thermodynamically stable. The distribution of water and MH was recorded by the

922

MRI system.

923

3.1 Methane hydrate formation

K,

which

ensured

that

the

hydrate-bearing

sediment

core

was

924

The pressure and temperature were set to 6000 kPa and 274.15 K, and were kept

925

constant for the whole MH formation process for Cases 1~12. MH saturation,

926

expressed as the volume fraction of pore space occupied by hydrate, was computed by

927

mean intensity (MI) data acquired form MRI images (Chen et al., 2019a). Because 1 48

928

m3 of hydrate releases 0.8 m3 of liquid water when it is dissociated, and 1 volume of

929

liquid water forms 1.25 volumes of hydrate under standard temperature and pressure

930

(STP) (Jr and Koh, 2007). Hence, the MH saturation at the “i” minute can be

931

computed with the following equation (Chen et al., 2019b):

932

S hi = 1.25 ×

933

where

934

values in the images at t = 0 and t = i minutes, respectively. The details of hydrate

935

saturation for each case are shown in Table 1.

(I 0 − I i )× S w0 × 100 %

S w0

(2)

I0

represents the initial water saturation, and

I0

and

Ii

represent the MI

936

Because of a similar phenomenon, take Case 2 as an example to illustrate the

937

MH formation process. Fig. 2 shows the MI variation during MH formation process,

938

which reflected the amount of free water in porous media. Moreover, three MRI

939

images were used to visually show the liquid water distribution during different stages

940

of MH formation. Bright red and dark purple represent the brightest (more water) and

941

darkest (more hydrate) signals, respectively. As shown in Fig. 2, the MI was stable at

942

stage I and liquid water distribution in the MRI image was uniform, indicating there

943

was no hydrate formation and water saturation remained invariant. At stage II, the MI

944

first appeared to rapidly decline (points A~B) and then the downtrend became a slight

945

slowdown (points B~C). Meanwhile, the MRI image was darker than stage I. This

946

was because that when the MH starts to form, the rapid hydrate formation obviously

947

consumes the amount of liquid water and decreases the MI value. Then, MH

948

formation influences the contact between the gas phase and liquid water, so hydrate 49

949

formation rate slows down. When the hydrate formation is completed, the MI

950

gradually comes to stability at stage III and the image becomes the darkest. From the

951

MRI images, it can be observed that MH formation is nonuniform in porous media

952

because there is always migration of water and gas in the MH formation process.

953

Moreover, MI was nonzero after MH formation completion, indicating that residual

954

water still exists in porous media.

955 956 957

Fig. 2 Variations of MI and water distribution during MH formation process 3.2 Effects of different seawater-gas flow rates on MH dissociation

958

In our previous study (Yang et al., 2019a), when the deionized water-gas flow

959

rate was 1-1 ml·min-1, MH did not dissociate and even the hydrate reformation

960

phenomenon appeared during the deionized water-gas flow. However, MH always

961

dissociates during the seawater-gas flow process even if the seawater-gas flow rate is

962

slower, which suggests the seawater-gas flow obviously promotes MH dissociation 50

963

and inhibits MH reformation. There are two reasons explaining this phenomenon. The

964

first was the seawater solution ion effect that forms an electric field between positive

965

and negative ions to destroy the cluster structure of water molecules. When the water

966

molecules form a lattice, they overcome the electric field and further shift the hydrate

967

phase equilibrium curve to the left (Yang et al., 2012, Chong et al., 2017b), as shown

968

in Fig. 3 the MH hydrate phase equilibrium curve under the seawater and deionized

969

water experimental condition. Therefore, compared to deionized water-gas flow

970

process, hydrate stability decreases and easily dissociates in the seawater-gas flow

971

process. The second is that the bonds between water and ions are Coulombic that

972

stronger than hydrogen bonding or van der Waals forces (Yang et al., 2012),

973

resulting in water molecules were attracted by ions and further reduce the water

974

molecular activity (Atik et al., 2006). Moreover, the accumulation of Cl- decreases gas

975

molecule solubility in seawater. The phenomenon of salting-out appeared (Chen et al.,

976

2017, Kim et al., 2008) with a negative effect on hydrate reformation. Based on the

977

above discussion, recycling seawater-gas flow was effective for gas hydrate

978

production.

51

979 980

Fig. 3 MH phase equilibrium curves under the seawater and deionized water

981

experimental condition

982

Fig. 4 shows the variation of water distribution during MH dissociation with

983

continuous seawater-gas flow, in which the seawater-gas flow rates were 1-1 (Case 1),

984

2-2 (Case 2), 3-3 (Case 3), 3-1 (Case 4), 4-1 (Case 5), 5-1 (Case 8), and 10-1

985

ml·min-1(Case 6), respectively. Moreover, bright green signals represent liquid water,

986

and dark blue signals are MH and a small quantity of methane gas. As shown in Fig. 4,

987

MH dissociated gradually with the seawater-gas flow process. At 2 min, the

988

hydrate-bearing sediment core was saturated by seawater, and the dark blue image

989

suggested there was no hydrate dissociation. With continuous seawater-gas flow, the

990

images showed a partial bright green area, illustrating hydrate dissociated and water

991

saturation increased. Then, the bright area gradually enlarged along the

992

seawater-gas-hydrate three phase interface until the whole image became bright.

52

993

When the whole image became bright (corresponding to the last image), the MH

994

dissociation was finished and the water saturation in porous media reached maximum.

995

Fig. 4 also showed that when the seawater-gas flow rate were 1-1, 2-2 and 3-3

996

ml·min-1 (Cases 1-3), the duration of hydrate dissociation was

997

the flow rate was 10-1 ml·min-1 (Case 6), the duration was the shortest for

998

dissociating hydrate. That is, the higher seawater flow rate and lower gas flow rate

999

will accelerate MH dissociation process. The reasons are addressed below. The first is

1000

that seawater salt invades the hydrate-dissociated water due to the concentration

1001

difference, and the salt contamination resulted in a better heat conduction (Sun and

1002

Mohanty, 2006, Chong et al., 2015). The second was the faster heat transfer during

1003

seawater-gas flow process. Because the hydrate dissociation is an endothermic

1004

reaction process, a lot of heat can be absorbed when the hydrate suddenly dissociated

1005

and caused a rapid decline of hydrate-bearing sediment temperature, even caused the

1006

hydrate reformation and ice generation. During the continuous seawater-gas flow

1007

process, the temperature of flowing seawater and gas (273.95 K) was constant, which

1008

can provide continuous heat transfer and keep the stability of sediment temperature.

1009

Therefore, the plummeting temperature of hydrate-bearing sediment cores was not

1010

appeared, which is benefit for the hydrate dissociation process, and further preventing

1011

the hydrate reformation and ice generation. The third was that increasing the seawater

1012

flow rate and decreasing the gas flow rate will increase the chemical potential

53

relatively long. When

1013

difference, accelerate the seawater phase mass transfer and further provide higher

1014

driving force for dissociating hydrate.

1015 1016

Fig. 4 Variations of water distribution during MH dissociation process with different

1017

seawater-gas flow rates

1018

Fig. 5 shows the variations of MI during MH dissociation with different

1019

seawater-gas flow rates, which reflected the amount variations of free water in porous

1020

media. As shown in Fig. 5, the MI increased to approximately 1200 within a few

1021

minutes at points A~B. This was because that after hydrate formation process, little

1022

amount free water distributed in sediment, the large amount of free gas, sand and

1023

hydrate caused the lowest value of MI. Then, when the seawater phase flow into the

1024

sediment, the increase of the amount of free water caused the sharp increase of MI

1025

Next, the MI appeared a sharp change under the seven flow rates, in which the MI 54

1026

suddenly decrease and then gradually increase. The reasons for the phenomenon are

1027

as follows. Firstly, due to the Jamin effect (Wang et al., 2016a, Yang et al., 2019a),

1028

some parts of free gas still distributed under the area of field view (FOV), these parts

1029

of free gas will be further displaced into the FOV by seawater. Because the MRI

1030

system can only identify the 1H containing in liquid, so the gas gathered in FOV

1031

caused the MI decrease. Secondly, with the continuous seawater flow, the hydrate will

1032

gradually dissociate and the free water will gradually obtain the released pore space,

1033

and ultimately caused the MI gradually increase. In Fig. 5 (a), when the seawater-gas

1034

flow rate was 1-1 ml·min-1, the upward tendency of MI was the slowest at points B~

1035

C1. In Fig. 5 (b), there has a rapidly increase of MI at points B~C (C4, C5), which

1036

indicated the MH dissociation under the seawater-gas flow rates of 3-1 and 4-1

1037

ml·min-1 was significantly faster than the results of in Fig. 5(a). Moreover, with the

1038

flow rate further increased (5-1 and 10-1 ml·min-1), the variation of MI transforms

1039

into the tension trend at points B~C (C6, C7) because of the quickening MH

1040

dissociation. Finally, when the hydrate was dissociated completely, the amount of

1041

water in the pore space was invariable and the MI was stable. In addition, the higher

1042

seawater flow rate and the lower gas flow rate, the faster for MI reached stability.

1043

Combined Figs. 4 and 5, jointly proves that seawater-gas flow can effectively

1044

promote MH dissociation.

55

1045 1046

Fig. 5 Variations of MI during MH dissociation process with different seawater-gas

1047

flow rates

1048

The average MH dissociation rate is a main parameter reflecting the average gas

1049

and water production rates. Fig. 6 shows comparisons of average MH dissociation rate

1050

with different seawater-gas flow rates. As shown in Fig. 6, the average MH

1051

dissociation rate is a function of the seawater-gas flow rate ratio and pour seawater

1052

flow rate, which increased with the increase of flow rate ratio and pore seawater flow

1053

rate. When the seawater-gas flow rate were 1-1, 2-2 and 3-3 ml·min-1, the MH

1054

dissociation rate increased slowly. Moreover, there was a fast-increasing trend for the

1055

MH dissociation rate with increasing seawater flow rate and decreasing gas flow rate.

1056

When the flow rate was highest (10-1 ml·min-1), it induced the largest average MH

1057

dissociation rate of 0.705 %/min. According to the trend of average MH dissociation

1058

rate, the seawater flow rate was the main factor promoting hydrate dissociation, and

1059

increasing the gas flow rate retards the dissociation process. That is, MH dissociation

1060

from seawater-gas flow increased with higher flow rate ratio and seawater flow rate.

56

1061

The reason is faster heat and mass transfer in hydrate-bearing sediment cores with

1062

increasing seawater-gas flow rate ratio and seawater flow rate, providing greater

1063

driving force to promote hydrate dissociation. So, it can be inferred that the

1064

seawater-gas flow rate of 10-1 ml·min-1 in Case 6 effectively promotes MH

1065

dissociation.

1066 1067

Fig. 6 Comparisons of average MH dissociation rates with different seawater-gas flow

1068

rates

1069

3.3 MH flow process dissociation behavior with different initial MH saturation

1070

To investigate MH dissociation with different initial hydrate saturation, six

1071

experiments were carried out with initial MH saturations of 15% (Case 7), 23% (Case

1072

8), 28% (Case 9), 31% (Case 10), 36% (Case 11), and 41% (Case 12). Fig. 7 shows

1073

the variations of water distribution and MI during MH dissociation induced by

57

1074

seawater-gas flow with different initial hydrate saturation, in which the seawater-gas

1075

flow rate was 5-1 ml·min-1. As shown in Fig. 7 (a), with the same seawater-gas flow

1076

rate, the time to dissociate MH (corresponding to the second image) and the time to

1077

dissociate MH completely (corresponding to the last image) all increased with

1078

increasing initial hydrate saturation. Combined with the MI variation during MH

1079

dissociation in Fig. 7 (b) a sharp MI change first appeared, and the reason have been

1080

discussed in section 3.2.. Then, it increased gradually with hydrate dissociation, and

1081

took more time for the MI to reach stability with higher initial hydrate saturation. In

1082

addition, when the hydrate dissociated completely, the MI remains stable and the

1083

maximum MI value decreases slightly with increasing initial hydrate saturation. This

1084

is because that there was a relatively slow hydrate dissociation process under higher

1085

initial saturation that caused more gas dissolving in liquid water and further decreased

1086

the maximum value of the MI. Fig. 7 suggest that the duration of hydrate dissociation

1087

was longest

1088

phenomenon. The first is hydrate imperviousness (Liu et al., 2016), higher initial

1089

hydrate saturation maintains hydrate-bearing sediment core stability better. The

1090

second was that MH occupies more pore space in porous media under higher initial

1091

hydrate saturation, which decreases the fluid flow space and water phase relative

1092

permeability, further influencing the heat and mass transfer. The third was that there

1093

has a higher chemical potential difference between the seawater and hydrate phases

1094

when the initial hydrate saturation is lower. As reported (Sean et al., 2007), the

under higher initial hydrate saturation. There are three reasons for this

58

1095

chemical potential difference was the main reason for hydrate dissociation in marine

1096

environment above hydrate phase equilibrium, which was defined as the methane

1097

concentration dissolved in the aqueous. During seawater-gas flow process, though

1098

little methane gas dissolved in flowing seawater, the chemical potential difference still

1099

enough for inducing hydrate dissociation. And the seawater-gas flow erosion was a

1100

long-time and continuous process, thereby, the residual free water and gas will be

1101

displaced at last. When the hydrate saturation is lower, the blocking effect of hydrate

1102

on seawater flow was relatively small, so the displace process of free water will be

1103

faster, which caused the chemical potential difference increase and accelerated the

1104

hydrate dissociation. .

1105 1106

Fig. 7 Variations of water distribution (a) and MI (b) during MH dissociation induced

1107

by seawater-gas flow with different initial hydrate saturation

1108

The average dissociation rate is an important parameter in hydrate exploitation

1109

and it is the ratio of hydrate saturation to dissociation duration (Wang et al., 2018).

1110

Fig. 8 shows the comparisons of average MH dissociation rate induced by 59

1111

seawater-gas flow with different initial hydrate saturation. As shown in Fig. 8, the

1112

MH dissociation rate has no obvious linear relationship with initial hydrate saturation,

1113

and the initial hydrate saturation has a mild effect under the same seawater-gas flow

1114

rate. This is because the MH dissociation rate is controlled by hydrate saturation and

1115

dissociation duration. Even though hydrate dissociates quickly, the average

1116

dissociation rate will not increase significantly due to lower hydrate saturation. In

1117

contrast, when hydrate saturation is higher, there also is no high MH dissociation rate

1118

because of the relatively long dissociation duration. Furthermore, the occurrence

1119

structure of hydrate may influence the dissociation behavior. Because the pore-filling

1120

hydrate has more surface area to retard fluid flow, there was a smaller water phase

1121

permeability than grain-coating hydrate (Dai and Seol, 2014), which may influence

1122

the MH dissociation rate, but this phenomenon was less evident in this study.

1123

60

1124

Fig. 8 Comparisons of average MH dissociation rate with different initial hydrate

1125

saturation

1126

3.4 Comparisons of seawater/deionized water-gas flow effects on MH dissociation

1127

The flow channel appearance and disappearance time represents the time at

1128

which the MH begins to dissociate and the end of MH dissociation. The flow channel

1129

appearance time was defined as the moment that a small bright area appeared, as

1130

shown in the second images in Fig. 4 and Fig 7 (a). The flow channel disappearance

1131

time is defined as the moment that the whole image became bright, as shown the last

1132

images in Fig. 4 and Fig 7 (a). The shorter the appearance and disappearance times,

1133

the faster the hydrate dissociation. Fig. 9 shows comparisons of flow channel

1134

appearance and disappearance times between seawater-gas and deionized water-gas

1135

flow. As shown in Fig. 9, the flow channel appearance and disappearance time

1136

obviously decreased with increasing water flow rate both in seawater-gas and

1137

deionized water-gas flow condition. Moreover, the flow channel appearance and

1138

disappearance time in deionized water-gas flow was longer than that of in

1139

seawater-gas flow under the same flow rate, especially in the deionized water-gas

1140

flow rate of 2-2 ml·min-1. The reasons for the above phenomenon are as follows.

1141

Firstly, under the same temperature, Na+ and Cl- can obviously improve the methane

1142

hydrate phase equilibrium pressure (as shown in Fig. 3), which induced a stronger

1143

promotion effect in seawater-gas flow on hydrate dissociation than the deionized

1144

water-gas flow. Secondly, due to the existence of ions, the CH4 gas solubility in 61

1145

seawater than that of in deionized water (Chen et al., 2017, Kim et al., 2008), which

1146

caused the larger chemical potential difference between seawater-hydrate phase and

1147

further provided the stronger driving force for MH dissociation. Thirdly, in our

1148

previous work (Chen et al., 2019b, Chen et al., 2019a, Yang et al., 2019a), we found

1149

that the water flow rate was the main reason for hydrate dissociation above the

1150

hydrate phase equilibrium. The higher water flow rate will accelerate hydrate

1151

dissociation rate by increasing the chemical potential difference and enhancing heat

1152

and mass transfer process. So, compared to others flow rate (3-3, 3-1, 4-1, 5-1

1153

ml·min-1), the lower water flow rate in the deionized water-gas flow rate of 2-2

1154

ml·min-1 provided a smaller driving force for hydrate dissociation and induced a huge

1155

number of disappearance time.

1156 1157

Fig. 9 Comparisons of flow channel appearance and disappearance time of between

1158

seawater-gas and deionized water-gas flow

62

1159

Fig. 10 shows comparisons of average MH dissociation rates between the

1160

seawater-gas and deionized water-gas flow processes. The experimental result and

1161

details of deionized water-gas flow process can be found in published article (Yang et

1162

al., 2019a). As shown in Fig. 10, the average MH dissociation rates with five flow

1163

rates were compared, including 2-2, 3-3, 3-1, 4-1, and 5-1 ml·min-1. In two

1164

experimental conditions (seawater/deionized water-gas flow), the MH dissociation

1165

rate increased with the increase of water flow rate and the decrease of gas flow rate,

1166

and the MH dissociation rate in the seawater-gas flow process was far greater than

1167

that in deionized water-gas flow under the same flow rate. This phenomenon

1168

indicated that the seawater-gas flow experimental conditions promote MH

1169

dissociation more significantly than deionized water-gas flow. The reason was that the

1170

Cl- implants into the water cage and attracts H+ from water molecules, which breaks

1171

the hydrogen bonding structure of the water cage and accelerates hydrate dissociation

1172

(Chong et al., 2015).In addition, because salt reduces methane gas solubility (Yang

1173

and Xu, 2007), the injection and hydrate-dissociated gases form bubbles in seawater

1174

(Chong et al., 2015). In contrast, the methane gas dissolved more uniformly in

1175

deionized water. Therefore, there was larger methane concentration between the

1176

seawater and hydrate phases during the seawater-gas flow process, which obviously

1177

increased the chemical potential difference, and provided a crucial driving force for

1178

hydrate dissociation.

63

1179 1180

Fig. 10 Comparisons of average MH dissociation rate between seawater-gas and

1181

deionized water-gas flow

1182

3.5 The application and shortage of seawater-gas flow inducing MH dissociation

1183

This study verified the promotion effect of seawater-gas flow on hydrate

1184

dissociation. The seawater-gas flow can increase the chemical potential difference,

1185

accelerate the heat and mas transfer process, and inhibit hydrate reformation, which

1186

have great application potential in actual hydrate production tests. In nature, four main

1187

classes (Class 1, Class 2, Class 3, Class 4) of methane hydrate deposits are found

1188

(Moridis et al., 2004). For Class 1 deposits (upper hydrate layer and under free gas

1189

layer), the gas phase ratio was much higher than that of water phase during hydrate

1190

production process. For Class 2 deposits (upper hydrate layer and under free water

1191

layer), the water phase ratio was much higher than that of gas phase during hydrate

1192

production process. For Class 3 and Class 4 deposits (no free water and gas layer), the 64

1193

hydrate production process will always companied company with the huge production

1194

of water and gas. It is surely that the issue of water production is a sticky point in the

1195

hydrate production tests. Therefore, in the actual hydrate exploitation tests, we can

1196

utilize the hydrate dissociated-water and can extra inject some seawater into the

1197

hydrate deposits to induce hydrate dissociation. The seawater flow rate can be

1198

controlled by adjusting the pressure difference between the production wells, and the

1199

gas recovery rate also can be adjusted to achieve the seawater-gas two-phase flow. In

1200

addition, considering to the hydrate production efficiency, the seawater-gas two-phase

1201

flow can be used to combine with other production methods (depressurization) for

1202

real applications, and which will be investigated in our follow-up work.

1203

However, there are also exist some limitations by using seawater to dissociate

1204

hydrate in real applications. Firstly, there will be need huge seawater injection amount

1205

if the water flow erosion method was performed to recovery natural gas in the field

1206

hydrate production test. Secondly, in order to avoid the reservoir collapse caused by

1207

fast hydrate dissociation, the suitable seawater flow rate and flow direction of

1208

seawater flow should be verified in the real hydrate production test. Thirdly, seawater

1209

flow may induce outflow sand and influent the continuous gas production, this issue

1210

also needs solve. Therefore, the results obtained from our test section translatable to

1211

the real case still exist some difference. The current study was a fundamental study,

1212

we will further investigate the effect of water-gas two-phase flow on hydrate

1213

dissociation by increasing the experimental scale. 65

1214

4. Conclusion

1215

A seawater-gas flow experiment was carried out and the effect of seawater-gas

1216

flow rate and initial hydrate saturation on MH dissociation was analyzed. The

1217

experimental conclusions are as follows:

1218

(1) When the flow rate was 1-1 ml·min-1, the seawater-gas flow process promotes

1219

MH dissociation because of the ion and salting-out effects, whereas MH was not

1220

dissociated and hydrate reformation even appeared in the deionized water-gas flow

1221

process. It was shown that seawater-gas flow achieves gas production from hydrate

1222

reservoirs and effectively inhibits hydrate reformation under slower flow rates.

1223

(2) With the same initial hydrate saturation, the seawater-gas flow rate ratio and

1224

pour seawater flow rate were the crucial factor for MH dissociation. The higher

1225

seawater flow rate and lower gas flow rate cause higher average MH dissociation

1226

rates due to the acceleration of heat and mass transfer. In addition, salt ions reduce gas

1227

solubility and water activity further promoting hydrate dissociation.

1228

(3) With the same seawater-gas flow rate, the time to induce MH to dissociate

1229

and the total time for completing MH dissociation all increased with increasing initial

1230

hydrate saturation. According to the trend of the average MH dissociation rate under

1231

different initial hydrate saturation, hydrate saturation has a mild effect on the average

1232

MH dissociation rate.

1233

(4) Seawater-gas flow promotes MH dissociation stronger than deionized

1234

water-gas flow. During seawater-gas flow, the duration of hydrate dissociation 66

1235

decreased and the average MH dissociation rate increased with higher seawater-gas

1236

flow rate ratio and higher seawater flow rate. Moreover, the average MH dissociation

1237

rate in seawater-gas flow was higher than in deionized water-gas flow.

1238

Acknowledgments

1239

This study was financially supported by grants from the National Natural

1240

Science Foundation of China (51436003, 51822603 and 51576025), the National Key

1241

Research and Development Plan of China (2017YFC0307303 and 2016YFC0304001),

1242

the Fok Ying-Tong Education Foundation for Young Teachers in Higher Education

1243

Institutions of China (161050) and the Fundamental Research Funds for the Central

1244

Universities of China (DUT18ZD403).

1245

Conflict of interest

1246

None declared

1247

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1248

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Highlights • MH dissociation characteristics during seawater-gas flow process were visually studied. • Seawater-gas two-phase flow has a significant promotion effect on MH dissociation. • The MH dissociation rate increased with increasing seawater-gas flow rate ratio. • Initial saturation has mild effect on MH dissociation rate with the same flow rate.

Dear editor: We would like to submit the enclosed manuscript entitled " Effects of multiphase flow on natural gas hydrate production in marine sediment ". It is submitted to be considered for publication as a “Research paper" in your journal. The promotion effects of deionized water-gas flow on gas hydrate dissociation has been studied. Therefore, in consideration of the effect of seawater on hydrate thermodynamic equilibrium, the experiment of seawater-gas flow was performed to dissociate hydrate. In this paper, the effects of different seawater-gas flow rates and different initial hydrate saturation on methane hydrate (MH) production characteristics was analyzed and compared. Due to the huge seawater reserves in hydrate accumulation area, the method of seawater-gas flow to dissociate hydrate is easy to achieve, so the experimental results will offer some reference and guidance for future NGHs exploration in marine environment. Neither the entire paper nor any part of its content has been published or has been accepted elsewhere. It is not being submitted to any other journal. We have consulted the Guide for Authors in preparing the submitted manuscript and compliance with the Ethics in Publishing Policy as described in the Guide for Authors. The study is novel and article is well written. We believe the paper may be of particular interest to the readers of your journal. Correspondence and phone calls about the paper should be directed to Mingjun Yang at the following address, phone and fax number, and e-mail address: Name: Mingjun Yang Institute: Key Laboratory of Ocean Energy Utilization and Energy Conservation of Ministry of Education, Dalian University of Technology. Address: No.2 Linggong Road, Ganjingzi District, Dalian City, Liaoning Province, P.

R. China., 116024 Telephone: +86-411-84709093. Fax: +86-411-84708015. E-mail: [email protected]. Thank you very much for your considering our manuscript for potential publication. Sincerely yours, Minhjun Yang

Suggested Reviewers: Considering their contributions on hydrate based technology, the following professors are proposed as potential reviewers: (1) Amir H. Mohammadi, MINES ParisTech, CEP/TEP, Fontainebleau, France, E-mail: [email protected] (2) Praveen Linga, National University of Singapore, Singapore, E-mail: [email protected] (3) Xiaosen Li, Research Center of Gas Hydrate, Chinese Academy of Sciences, E-mail: [email protected]