Optimization of solid and radiation thermal conductivity of polymeric foams using response surface method based on a novel theoretical model

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.

HASANZADEH R.; AZDAST T.; DONIAVI A.; Eungkee Lee R.

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

Journal Paper

Paper Information

Journal: Modares Mechanical Engineering Year:2019 | Volume:19 | Issue:9 Page(s): 2165-2173

Download Full-Text

Persian Verion

View:

343

Download:

Cites:

Information Journal Paper

Title

Optimization of solid and radiation thermal conductivity of polymeric foams using response surface method based on a novel theoretical model

Author(s)

HASANZADEH R. | AZDAST T. | DONIAVI A. | Eungkee Lee R. | Issue Writer Certificate

Keywords

Theoretical ModelQ1

Foam DensityQ1

Cell SizeQ1

Thermal ConductivityQ1

Response Surface MethodQ1

Abstract

Polymeric foams are one of the best candidates for thermal insulation. Accordingly, to investigate the thermal insulation properties of polymeric foams has attracted the attention of scientific communities in recent years. In this study, optimization of thermal insulation properties of polymeric foams is performed from solid and radiation thermal conductivities points of view. In this regard, a Theoretical Model based on Cell Size and Foam Density is developed. The results of the developed Theoretical Model are verified in comparison to various experimental results. Based on the results, the error of the Theoretical Model is lesser than 5%. Decreasing the Foam Density increases and decreases the solid and radiation Thermal Conductivity, respectively. Also, the radiation Thermal Conductivity is decreased by reducing the Cell Size. Response Surface Method (RSM) is applied in order to optimize the solid and radiation thermal conductivities. The results illuminate that the Foam Density of 23. 5 kg. m-3 and Cell Size of 53 μ m are the optimum conditions. At the optimum conditions, both of the solid and radiation thermal conductivities are lesser than 3 mW/mK. According to the results, the data obtained from developed Theoretical Model and RSM are in a good agreement. The total Thermal Conductivity is 30 mW/mK at optimum conditions which is a desirable value at aforementioned Cell Size range.

Cites

No record.

References

No record.

Cite

APA: Copy

HASANZADEH, R., AZDAST, T., DONIAVI, A., & Eungkee Lee, R.. (2019). Optimization of solid and radiation thermal conductivity of polymeric foams using response surface method based on a novel theoretical model. MODARES MECHANICAL ENGINEERING, 19(9 ), 2165-2173. SID. https://sid.ir/paper/179950/en

Vancouver: Copy

HASANZADEH R., AZDAST T., DONIAVI A., Eungkee Lee R.. Optimization of solid and radiation thermal conductivity of polymeric foams using response surface method based on a novel theoretical model. MODARES MECHANICAL ENGINEERING[Internet]. 2019;19(9 ):2165-2173. Available from: https://sid.ir/paper/179950/en

IEEE: Copy

R. HASANZADEH, T. AZDAST, A. DONIAVI, and R. Eungkee Lee, “Optimization of solid and radiation thermal conductivity of polymeric foams using response surface method based on a novel theoretical model,” MODARES MECHANICAL ENGINEERING, vol. 19, no. 9 , pp. 2165–2173, 2019, [Online]. Available: https://sid.ir/paper/179950/en

Related Journal Papers