THERMODYNAMICS MODELING OF HEAT AND VAPOR TRANSFER IN THE SHELL-AND-TUBE MEMBRANE HUMIDIFIER: A GAS-TO-GAS TYPE

Q: How can I download an article?

To download an article from SID, first log in to the site, search for the article title, and click on the 'Download Article' option.

Q: How can I download an ISI article?

To download an ISI article on SID, enter the keyword or article title in the search bar, view the relevant results, click on the desired article, and select the 'Download Article' option.

Q: How can I access the SID database?

To access the SID database, visit SID.ir, create an account, and log in to access scientific resources.

Q: Is downloading articles from SID free?

Some articles on SID are available for free, while others require payment. Details are specified on the article's page.

BAROUTIE ARDESTANIE M.; HASSANZADEH H.; AHMADI BROGANI S.Y.

مرکز اطلاعات علمی Scientific Information Database (SID) - Trusted Source for Research and Academic Resources

Journal Paper

Paper Information

Journal: JOURNAL OF SOLID AND FLUID MECHANICS Year:2015 | Volume:5 | Issue:3 Page(s): 223-236

Download Full-Text

Persian Verion

View:

788

Download:

Cites:

Information Journal Paper

Title

THERMODYNAMICS MODELING OF HEAT AND VAPOR TRANSFER IN THE SHELL-AND-TUBE MEMBRANE HUMIDIFIER: A GAS-TO-GAS TYPE

Author(s)

BAROUTIE ARDESTANIE M. | HASSANZADEH H. | AHMADI BROGANI S.Y. | Issue Writer Certificate

Keywords

MEMBRANE HUMIDIFIERQ2

SHELL AND TUBEQ2

GAS-GASQ2

COUNTERFLOWQ2

HEAT AND VAPOR TRANSFERQ2

Abstract

Water management plays an important role in the performance of polymer fuel cell. Humidifying the reactant gases before entering the fuel cell and adjusting the wet content are among the most important ways for water management. In this study, a MEMBRANE HUMIDIFIER of a GAS-GAS type has been modeled. The governing equations included mass conservation as well as energy and vapor transfer equations solved by numerical method and validated by experimental data available in relevant scientific articles. Then, the effect of operating parameters such as flow rate, temperature and relative humidity of the inlet gases and geometric parameters such as thickness, diameter and number of tubes on performance of humidifier have been studied. The results show that, in the same inlet mass flow rate in both wet and dry side, outlet wet gas temperature, heat transfer rate and vapor transfer rate in the counter flow are greater than the parallel flow, therefore the results for this humidifier are provided. In counter flow humidifier, by increasing inlet dry gas temperature, the rate of heat transfer and vapor transfer rate will decrease and also increasing relative humidity of inlet dry gas will reduces the vapor transfer rate and has negligible impact on outlet wet gas temperature and heat transfer rate. Finally, increasing the thickness, length and number of membrane tubes can have negligible impact on the heat transfer rate as well.

Cites

No record.

References

No record.

Cite

APA: Copy

BAROUTIE ARDESTANIE, M., HASSANZADEH, H., & AHMADI BROGANI, S.Y.. (2015). THERMODYNAMICS MODELING OF HEAT AND VAPOR TRANSFER IN THE SHELL-AND-TUBE MEMBRANE HUMIDIFIER: A GAS-TO-GAS TYPE. JOURNAL OF SOLID AND FLUID MECHANICS, 5(3), 223-236. SID. https://sid.ir/paper/212764/en

Vancouver: Copy

BAROUTIE ARDESTANIE M., HASSANZADEH H., AHMADI BROGANI S.Y.. THERMODYNAMICS MODELING OF HEAT AND VAPOR TRANSFER IN THE SHELL-AND-TUBE MEMBRANE HUMIDIFIER: A GAS-TO-GAS TYPE. JOURNAL OF SOLID AND FLUID MECHANICS[Internet]. 2015;5(3):223-236. Available from: https://sid.ir/paper/212764/en

IEEE: Copy

M. BAROUTIE ARDESTANIE, H. HASSANZADEH, and S.Y. AHMADI BROGANI, “THERMODYNAMICS MODELING OF HEAT AND VAPOR TRANSFER IN THE SHELL-AND-TUBE MEMBRANE HUMIDIFIER: A GAS-TO-GAS TYPE,” JOURNAL OF SOLID AND FLUID MECHANICS, vol. 5, no. 3, pp. 223–236, 2015, [Online]. Available: https://sid.ir/paper/212764/en

Related Journal Papers