Gas to liquid transfer enhancement during hydrate crystallization: Case study of CO2 hydrate for cold storage and transport

Véronique Osswald; Amokrane Boufares; Pascal Clain; Elise Provost; Didier Dalmazzone; Hong Minh Hoang; Laurence Fournaison; Anthony Delahaye

doi:10.18462/iir.icr.2019.1188

Gas to liquid transfer enhancement during hydrate crystallization: Case study of CO₂ hydrate for cold storage and transport

Véronique Osswald, Amokrane Boufares, Pascal Clain, Elise Provost, Didier Dalmazzone, Hong Minh Hoang, Laurence Fournaison, Anthony Delahaye

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Secondary refrigerants, like ice slurries, are already used for industrial application, but their generation requires mechanical processes (scraping or brushing surface exchangers). CO₂ hydrates slurries were classically obtained in a stirred reactor, by gaseous CO₂ dissolution inside liquid water and cooling process. In the present work, an original set up was developed in order to measure in real time and in situ the dissolved CO₂ amount in the liquid phase during crystallization process thanks to the FTIR-ATR measurements. Results on this device allowed to quantify crystallization driving force, related to supersaturation, and to focus on the crystallization limiting step, in particular to determine whether or not it is gas to liquid diffusion. Some parameters were tested as stirrer type (propeller, Rushton turbine with and without hollow shaft) or stirring speeds. The increase of stirring speed or hollow shaft stirrer choice enhanced significatively gas/liquid transfer and thus strongly attenuated or even eliminated under certain conditions the limiting factor at the vapor-liquid interface.

Original language	English
Title of host publication	ICR 2019 - 25th IIR International Congress of Refrigeration
Editors	Vasile Minea
Publisher	International Institute of Refrigeration
Pages	1451-1458
Number of pages	8
ISBN (Electronic)	9782362150357
DOIs	https://doi.org/10.18462/iir.icr.2019.1188
Publication status	Published - 1 Jan 2019
Externally published	Yes
Event	25th IIR International Congress of Refrigeration, ICR 2019 - Montreal, Canada Duration: 24 Aug 2019 → 30 Aug 2019

Publication series

Name	Refrigeration Science and Technology
Volume	2019-August
ISSN (Print)	0151-1637

Conference

Conference	25th IIR International Congress of Refrigeration, ICR 2019
Country/Territory	Canada
City	Montreal
Period	24/08/19 → 30/08/19

Keywords

CO Hydrate
FTIR-ATR
Heat Transfer
Mass
Phase Change Material
Secondary Refrigeration

Access to Document

10.18462/iir.icr.2019.1188

Cite this

Osswald, V., Boufares, A., Clain, P., Provost, E., Dalmazzone, D., Hoang, H. M., Fournaison, L., & Delahaye, A. (2019). Gas to liquid transfer enhancement during hydrate crystallization: Case study of CO₂ hydrate for cold storage and transport. In V. Minea (Ed.), ICR 2019 - 25th IIR International Congress of Refrigeration (pp. 1451-1458). Article 1188 (Refrigeration Science and Technology; Vol. 2019-August). International Institute of Refrigeration. https://doi.org/10.18462/iir.icr.2019.1188

Osswald, Véronique ; Boufares, Amokrane ; Clain, Pascal et al. / Gas to liquid transfer enhancement during hydrate crystallization : Case study of CO₂ hydrate for cold storage and transport. ICR 2019 - 25th IIR International Congress of Refrigeration. editor / Vasile Minea. International Institute of Refrigeration, 2019. pp. 1451-1458 (Refrigeration Science and Technology).

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title = "Gas to liquid transfer enhancement during hydrate crystallization: Case study of CO2 hydrate for cold storage and transport",

abstract = "Secondary refrigerants, like ice slurries, are already used for industrial application, but their generation requires mechanical processes (scraping or brushing surface exchangers). CO2 hydrates slurries were classically obtained in a stirred reactor, by gaseous CO2 dissolution inside liquid water and cooling process. In the present work, an original set up was developed in order to measure in real time and in situ the dissolved CO2 amount in the liquid phase during crystallization process thanks to the FTIR-ATR measurements. Results on this device allowed to quantify crystallization driving force, related to supersaturation, and to focus on the crystallization limiting step, in particular to determine whether or not it is gas to liquid diffusion. Some parameters were tested as stirrer type (propeller, Rushton turbine with and without hollow shaft) or stirring speeds. The increase of stirring speed or hollow shaft stirrer choice enhanced significatively gas/liquid transfer and thus strongly attenuated or even eliminated under certain conditions the limiting factor at the vapor-liquid interface.",

keywords = "CO Hydrate, FTIR-ATR, Heat Transfer, Mass, Phase Change Material, Secondary Refrigeration",

author = "V{\'e}ronique Osswald and Amokrane Boufares and Pascal Clain and Elise Provost and Didier Dalmazzone and Hoang, \{Hong Minh\} and Laurence Fournaison and Anthony Delahaye",

note = "Publisher Copyright: {\textcopyright} 2019 International Institute of Refrigeration. All rights reserved.; 25th IIR International Congress of Refrigeration, ICR 2019 ; Conference date: 24-08-2019 Through 30-08-2019",

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doi = "10.18462/iir.icr.2019.1188",

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Osswald, V, Boufares, A, Clain, P, Provost, E, Dalmazzone, D, Hoang, HM, Fournaison, L & Delahaye, A 2019, Gas to liquid transfer enhancement during hydrate crystallization: Case study of CO₂ hydrate for cold storage and transport. in V Minea (ed.), ICR 2019 - 25th IIR International Congress of Refrigeration., 1188, Refrigeration Science and Technology, vol. 2019-August, International Institute of Refrigeration, pp. 1451-1458, 25th IIR International Congress of Refrigeration, ICR 2019, Montreal, Canada, 24/08/19. https://doi.org/10.18462/iir.icr.2019.1188

Gas to liquid transfer enhancement during hydrate crystallization: Case study of CO₂ hydrate for cold storage and transport. / Osswald, Véronique; Boufares, Amokrane; Clain, Pascal et al.
ICR 2019 - 25th IIR International Congress of Refrigeration. ed. / Vasile Minea. International Institute of Refrigeration, 2019. p. 1451-1458 1188 (Refrigeration Science and Technology; Vol. 2019-August).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Gas to liquid transfer enhancement during hydrate crystallization

T2 - 25th IIR International Congress of Refrigeration, ICR 2019

AU - Osswald, Véronique

AU - Boufares, Amokrane

AU - Clain, Pascal

AU - Provost, Elise

AU - Dalmazzone, Didier

AU - Hoang, Hong Minh

AU - Fournaison, Laurence

AU - Delahaye, Anthony

PY - 2019/1/1

Y1 - 2019/1/1

N2 - Secondary refrigerants, like ice slurries, are already used for industrial application, but their generation requires mechanical processes (scraping or brushing surface exchangers). CO2 hydrates slurries were classically obtained in a stirred reactor, by gaseous CO2 dissolution inside liquid water and cooling process. In the present work, an original set up was developed in order to measure in real time and in situ the dissolved CO2 amount in the liquid phase during crystallization process thanks to the FTIR-ATR measurements. Results on this device allowed to quantify crystallization driving force, related to supersaturation, and to focus on the crystallization limiting step, in particular to determine whether or not it is gas to liquid diffusion. Some parameters were tested as stirrer type (propeller, Rushton turbine with and without hollow shaft) or stirring speeds. The increase of stirring speed or hollow shaft stirrer choice enhanced significatively gas/liquid transfer and thus strongly attenuated or even eliminated under certain conditions the limiting factor at the vapor-liquid interface.

AB - Secondary refrigerants, like ice slurries, are already used for industrial application, but their generation requires mechanical processes (scraping or brushing surface exchangers). CO2 hydrates slurries were classically obtained in a stirred reactor, by gaseous CO2 dissolution inside liquid water and cooling process. In the present work, an original set up was developed in order to measure in real time and in situ the dissolved CO2 amount in the liquid phase during crystallization process thanks to the FTIR-ATR measurements. Results on this device allowed to quantify crystallization driving force, related to supersaturation, and to focus on the crystallization limiting step, in particular to determine whether or not it is gas to liquid diffusion. Some parameters were tested as stirrer type (propeller, Rushton turbine with and without hollow shaft) or stirring speeds. The increase of stirring speed or hollow shaft stirrer choice enhanced significatively gas/liquid transfer and thus strongly attenuated or even eliminated under certain conditions the limiting factor at the vapor-liquid interface.

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KW - Heat Transfer

KW - Mass

KW - Phase Change Material

KW - Secondary Refrigeration

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DO - 10.18462/iir.icr.2019.1188

M3 - Conference contribution

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A2 - Minea, Vasile

PB - International Institute of Refrigeration

Y2 - 24 August 2019 through 30 August 2019

ER -

Osswald V, Boufares A, Clain P, Provost E, Dalmazzone D, Hoang HM et al. Gas to liquid transfer enhancement during hydrate crystallization: Case study of CO₂ hydrate for cold storage and transport. In Minea V, editor, ICR 2019 - 25th IIR International Congress of Refrigeration. International Institute of Refrigeration. 2019. p. 1451-1458. 1188. (Refrigeration Science and Technology). doi: 10.18462/iir.icr.2019.1188