Numerical and experimental determinations of contact heat transfer coefficients in nonisothermal glass molding

Vu, Anh Tuan; Helmig, Thorsten; Vu, Ngoc Anh; Frekers, Yona; Grunwald, Tim; Kneer, Reinhold; Bergs, Thomas

doi:10.1111/jace.16756

Cited by 15 publications

(9 citation statements)

References 20 publications

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“…It is, however, emphasized that imperfections of the molded components such as form deviation, chill ripples, or glass cracks are primarily driven by the molding step [17][18][19][20]. Those are the common defects observed in the nonisothermal molding process, mainly resulted from the high heat exchanges at the glass-mold interface [21,22] as well as the complex thermo-viscoelastic material behaviors of glass at elevated molding temperatures [23][24][25]. In serial production, if the defects are not detected during the molding step, it commonly results in a large number of glass rejects and high energy cost vain to anneal the glass failures [26].…”

Section: Fig 1 Process Chain Of Thin Glass Formingmentioning

confidence: 99%

Real-Time Quality Control in Thin Glass Forming Using Infrared Thermography and Deep Learning

Vogel

Subramanian

et al. 2022

KEM

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Towards the growing trends in lightweight, flexible, and optical advantages, thin glasses become key components in numerous applications such as consumer electronics like foldable smartphones, or automotive interiors. Nonisothermal glass molding promises a viable technology for the cost-efficient production of precision glass components. In the existing production, the quality of the glass products can only be accessed at the end of the hot forming process. Due to high rates of product failures often appeared in the precision glass molding processes, the current quality control of the produced optical products suffers low process efficiency. This work introduces an enabling approach for monitoring the product quality in real-time using thermography and machine learning. Specifically, the acquisition of the temperature fields of the glass components during the hot forming stage enabled by an infrared thermographic camera allows machine learning to predict the final shape of the molded components at the end of the forming process. Several transfer learning models have been investigated to demonstrate the proposed method. To further enhance the prediction performance, self-built convolutional neural network models were developed using different types of image data. By incorporating the time-series image data as an input to the learning models, the prediction performance was achieved. The model built in the present work demonstrates an excellent prediction accuracy where the difference between the measured and predicted shapes of the glass products can be kept at low double-digit micrometers. Such accuracy achieved by our self-developed machine learning model promisingly satisfy the quality control in serial productions of numerous precision optical glass components in automotive and consumer electronics sectors.

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Section: Fig 1 Process Chain Of Thin Glass Formingmentioning

confidence: 99%

Real-Time Quality Control in Thin Glass Forming Using Infrared Thermography and Deep Learning

Vogel

Subramanian

et al. 2022

KEM

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“…The latter is influenced both by process parameters, e.g. temperature and molding force (e.g., Maxwell [15,16] or Burgers' models [17,18]), the heat transfers at the glassmold interface [19][20][21] and by system variables such as the geometry of the blank and that of the mold, as well as the surface properties [22]. Another challenge is the control of shrinkage, which is also significantly influenced by thermal and system parameters [23].…”

Section: Fig 4 Process Chain Of the Wafer Scale Processmentioning

confidence: 99%

Enabling Sustainability in Glass Optics Manufacturing by Wafer Scale Molding

Strobl

Vogel

et al. 2022

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Numerous optical applications have rising demands for ever increasing quantities from lighting and projection optics for modern vehicles to home or street lighting using LED technology. Glass is the material of choice for most of those application fields. It has several advantages over polymers, including heat and scratch resistance as well as longevity and recyclability. Non-isothermal glass molding has become a viable hot forming technology for mass production of optics. The major challenge is enabling a scalable replication process allowing the optical glass elements to be manufactured with high form accuracy and at low-cost production with low reject rates. This work introduces recent developments in glass optics manufacturing that allow the fulfilment of seemingly contradicting criteria: the economic growth and the need for less consumption of resources and energy. While single cavity non-isothermal molding is state-of-the-art, a manufacturing innovation through wafer-scale molding enables an exponentially increasing number of optics to be produced per production shift, allowing a significant reduction of unit costs. In parallel, as multiple optics are produced in one manufacturing cycle, the energy consumption and the consequent CO2 emission can be reduced. In contrast, the technological development arises several challenges that will be discussed in this work. Besides the selection of suitable mold concepts and materials, the challenges also include the temperature control of the mold and the blank up to the optimization of flow and shrinking mechanisms of the glass during rapid forming. Another difficulty in the non-isothermal glass molding is to maintain the low form deviation required for precision optics, repeatability, and low failure rates through process optimization. Finally, detail calculations of cost, energy and CO2 consumption, in comparison with conventional fabrication of glass components using grinding and polishing as well as single cavity molding, will be demonstrated. The non-isothermal wafer-level glass molding is a new technological solution for the sustainable manufacturing of optics at large-scaled production.

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“…They can be categorized in three groups: the properties of the contacting materials, surface textures, and interfacial conditions such as temperature, pressure, and interlayers e.g., coating thickness. The scope of this study is to investigate the predictive performance of machine learning-based models and to compare with a theoretical approach such as Cooper-Mikic-Yovanovich model [9] or with a numerical simulation method [18]. For this study, we selected a glass type, the Borosilicate glass (SUPRAX ® 8488), and a temperature-resistant stainless steel (AISI 431) as the materials of the contact pair.…”

Section: Datasetsmentioning

confidence: 99%

“…To overcome this deficit, recent modeling focuses rely on numerical techniques where the actual three-dimensional (3D) surface topographies of the contact pair were incorporated in the simulation models, enabled by Finite Element Method (FEM) [15,16] or half-space procedure [17]. It is emphasized that the prediction accuracy of the numerical models strongly requires adequate material models that are able to describe the deformation behaviors of the contact pair [18]. In addition, high computation effort is typically the major drawback held by the numerical method.…”

Section: Introductionmentioning

confidence: 99%