Numerical and experimental study of blow and blow for perfume bottles to predict glass thickness and blank mold influence

Adrià Biosca; Salvador Borrós; Vicenç Pedret Clemente; Matthew R. Hyre; Andrés Amador García Granada

doi:10.1111/ijag.13208

Numerical and experimental study of blow and blow for perfume bottles to predict glass thickness and blank mold influence

Adrià Biosca, Salvador Borrós, Vicenç Pedret Clemente, Matthew R. Hyre, Andrés Amador García Granada^*

^*Corresponding author for this work

Research output: Indexed journal article › Article › peer-review

7 Citations (Scopus)

Abstract

Glass forming to produce perfume bottles with specific thickness distribution profiles is based on trial and error and requires several tests in production line. These tests are expensive and time-consuming, which increases time to market. The use of a numerical model aims to reduce the number of prototypes by performing virtual tests of the mold equipment and the process conditions. This article presents results of numerical simulations of the blow and blow forming process to predict glass thickness distribution. Correlation of the simulation results of the glass temperature with experimental infrared measurements on the glass skin and experimental validation of glass forming simulations and influence of the blank mold cavity in the thickness distributions of perfume bottles are provided. Finally validation of the results of axisymmetrical and three-dimensional models for axisymmetric bottles defining a useful technique to use the right blank mold for desired thickness distribution while reducing the trial and error testing.

Original language	English
Pages (from-to)	569-583
Number of pages	15
Journal	International Journal of Applied Glass Science
Volume	10
Issue number	4
DOIs	https://doi.org/10.1111/ijag.13208
Publication status	Published - 1 Oct 2019

Keywords

axisymmetrical and 3D models
blow and blow forming process
glass thickness prediction
numerical and experimental study
perfume bottle

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10.1111/ijag.13208

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title = "Numerical and experimental study of blow and blow for perfume bottles to predict glass thickness and blank mold influence",

abstract = "Glass forming to produce perfume bottles with specific thickness distribution profiles is based on trial and error and requires several tests in production line. These tests are expensive and time-consuming, which increases time to market. The use of a numerical model aims to reduce the number of prototypes by performing virtual tests of the mold equipment and the process conditions. This article presents results of numerical simulations of the blow and blow forming process to predict glass thickness distribution. Correlation of the simulation results of the glass temperature with experimental infrared measurements on the glass skin and experimental validation of glass forming simulations and influence of the blank mold cavity in the thickness distributions of perfume bottles are provided. Finally validation of the results of axisymmetrical and three-dimensional models for axisymmetric bottles defining a useful technique to use the right blank mold for desired thickness distribution while reducing the trial and error testing.",

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note = "Funding Information: The authors gratefully acknowledge Matthew Hyre and Emhart Glass that provided useful experimental data and guidance on ANSYS Polyflow and glass forming simulations; Fundaci{\'o} LaCaixa for its financial support and ACCI{\'O} to partially fund this project with European Regional Development Funds under the Nuclis project RD16-1-0015. Publisher Copyright: {\textcopyright} 2019 The American Ceramic Society and Wiley Periodicals, Inc",

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AU - Biosca, Adrià

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AU - Pedret Clemente, Vicenç

AU - Hyre, Matthew R.

AU - García Granada, Andrés Amador

N1 - Funding Information: The authors gratefully acknowledge Matthew Hyre and Emhart Glass that provided useful experimental data and guidance on ANSYS Polyflow and glass forming simulations; Fundació LaCaixa for its financial support and ACCIÓ to partially fund this project with European Regional Development Funds under the Nuclis project RD16-1-0015. Publisher Copyright: © 2019 The American Ceramic Society and Wiley Periodicals, Inc

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N2 - Glass forming to produce perfume bottles with specific thickness distribution profiles is based on trial and error and requires several tests in production line. These tests are expensive and time-consuming, which increases time to market. The use of a numerical model aims to reduce the number of prototypes by performing virtual tests of the mold equipment and the process conditions. This article presents results of numerical simulations of the blow and blow forming process to predict glass thickness distribution. Correlation of the simulation results of the glass temperature with experimental infrared measurements on the glass skin and experimental validation of glass forming simulations and influence of the blank mold cavity in the thickness distributions of perfume bottles are provided. Finally validation of the results of axisymmetrical and three-dimensional models for axisymmetric bottles defining a useful technique to use the right blank mold for desired thickness distribution while reducing the trial and error testing.

AB - Glass forming to produce perfume bottles with specific thickness distribution profiles is based on trial and error and requires several tests in production line. These tests are expensive and time-consuming, which increases time to market. The use of a numerical model aims to reduce the number of prototypes by performing virtual tests of the mold equipment and the process conditions. This article presents results of numerical simulations of the blow and blow forming process to predict glass thickness distribution. Correlation of the simulation results of the glass temperature with experimental infrared measurements on the glass skin and experimental validation of glass forming simulations and influence of the blank mold cavity in the thickness distributions of perfume bottles are provided. Finally validation of the results of axisymmetrical and three-dimensional models for axisymmetric bottles defining a useful technique to use the right blank mold for desired thickness distribution while reducing the trial and error testing.

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Numerical and experimental study of blow and blow for perfume bottles to predict glass thickness and blank mold influence

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