Title
Computational Intelligence for Sustainable Glass Manufacturing: A Data-Driven Approach for Energy Efficient ConditioningVersion
PostprintDocument type
Journal ArticleLanguage
EnglishRights
© 2026 The American Ceramic SocietyAccess
Open accessPublisher’s version
https://doi.org/10.1111/ijag.70045xmlui.dri2xhtml.METS-1.0.item-identifier
https://ceramics.onlinelibrary.wiley.com/doi/10.1111/ijag.70045Published at
International Journal of Applied Glass Science Vol. 17 (3). N. art. e70045Publisher
John Wiley and Sons LtdKeywords
energy optimization
glass conditioning
glass container
sustainable manufacturing ... [+]
glass conditioning
glass container
sustainable manufacturing ... [+]
energy optimization
glass conditioning
glass container
sustainable manufacturing
ODS 9 Industria, innovación e infraestructura [-]
glass conditioning
glass container
sustainable manufacturing
ODS 9 Industria, innovación e infraestructura [-]
Subject (UNESCO Thesaurus)
Data analysisData protection
UNESCO Classification
Data analysisAbstract
In the glass container manufacturing process, conditioning is a key stage that contributes to energy consumption. The main objective of conditioning is to cool the glass exiting the furnace to a suita ... [+]
In the glass container manufacturing process, conditioning is a key stage that contributes to energy consumption. The main objective of conditioning is to cool the glass exiting the furnace to a suitable temperature for container forming. Currently, this stage is managed based on the experience of operators, which is functional but not optimized for energy efficiency. While several approaches to minimizing energy consumption based on process control using physical modeling have been proposed in the literature, they do not completely account for all the involved variables. Moreover, none of these studies leverage the power of data to predict energy consumption patterns. In this paper, we introduce a data-driven method to minimize energy consumption during the glass conditioning stage. We applied this methodology to a specific production line and tested it under various scenarios, achieving potential savings of 5% to 45% in energy consumption. Operational validations in two additional real forehearths showed energy reductions of 26.3–89.3 kWh per operating hour, corresponding to relative savings of 8.2%–22.1%, including a same-production A/B test. The implementation of this method has the potential to significantly contribute to the decarbonization goals of the glass manufacturing industry. [-]
Funder
Gobierno VascoGobierno Vasco
Program
Ikertalde Convocatoria 2022-2025Programa Bikaintek 2023
Number
IT1676-22019-B2-2023
Project
Grupo de sistemas inteligentes para sistemas industrialesCollections
- Articles - Engineering [930]



















