Author(s)

Gregor Berger^1*, Zlatko Raonic¹, Daniel Forthuber¹, Harald Raupenstrauch¹, Robert Hermann²

¹Chair of Thermal Processing Technology, Montanuniversitaet Leoben, Leoben, Austria.
²TüV SüD Landesgesellschaft Österreich GmbH, Bruck/Mur, Austria.

Glass manufacturing is an energy-intensive process with high demands on product quality. The wide usage of glass products results in a high end-product diversity. In the past, many models have been developed to optimize specific process steps, such as glass melting or glass forming. This approach presents a tool for the modeling of the entire glass manufacturing process for container glass, flat glass, and glass fibers. The tool considers detailed bottom-up energy and material balance in each step of the processing route with the corresponding costs and CO₂ emissions. Subsequently, it provides the possibility to quantify optimization scenarios in the entire glass manufacturing process in terms of energy, material and cost flow efficiency.

Energy Efficiency, Glass Industry, Energy Balance, Container Glass, Flat Glass, Glass Fiber

Berger, G. , Raonic, Z. , Forthuber, D. , Raupenstrauch, H. and Hermann, R. (2022) Energy and Material Flow Evaluation with CO2 Emissions in the Glass Production Process. Advances in Materials Physics and Chemistry, 12, 82-105. doi: 10.4236/ampc.2022.125007.