Difference between revisions of "Main Page"
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− | {{DISPLAYTITLE:KIproBatt Project Wiki}} | + | {{DISPLAYTITLE:KIproBatt Project Wiki}}{{AccessControl/Public}} |
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Project Wiki and Semantic Dataspace of [[KIproBatt]]. | Project Wiki and Semantic Dataspace of [[KIproBatt]]. | ||
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Git Repos exist both on [https://github.com/KIproBatt Github] and [https://gitlab.cc-asp.fraunhofer.de/KIproBatt FhG Gitlab] | Git Repos exist both on [https://github.com/KIproBatt Github] and [https://gitlab.cc-asp.fraunhofer.de/KIproBatt FhG Gitlab] | ||
− | == About '''KIproBatt''' - ''Intelligent battery cell manufacturing with AI-supported process monitoring based on a generic system architecture'' == | + | ==About '''KIproBatt''' - ''Intelligent battery cell manufacturing with AI-supported process monitoring based on a generic system architecture''== |
Due to its complexity and vast economic as well as ecological impact, the Li-ion battery cell production process is subject to ongoing digitization and optimization in order to increase cell performance while reducing resource consumption and production costs. | Due to its complexity and vast economic as well as ecological impact, the Li-ion battery cell production process is subject to ongoing digitization and optimization in order to increase cell performance while reducing resource consumption and production costs. | ||
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The combination of these two perspectives allows us to detect defects early in the production process, rapidly increase the quality performance and derive flexible adjustments to the process parameters in case of malfunction or defects. Thus, we expect to reduce the total cost of cell production as well as improve its carbon footprint by reductions in resource and energy consumption. Finally, the generic, semantically structured design enables an easy transfer to other research and industrial processes. | The combination of these two perspectives allows us to detect defects early in the production process, rapidly increase the quality performance and derive flexible adjustments to the process parameters in case of malfunction or defects. Thus, we expect to reduce the total cost of cell production as well as improve its carbon footprint by reductions in resource and energy consumption. Finally, the generic, semantically structured design enables an easy transfer to other research and industrial processes. | ||
− | == About the '''KIproBatt Dataspace''' == | + | ==About the '''KIproBatt Dataspace'''== |
Revision as of 11:32, 16 November 2021
Project Wiki and Semantic Dataspace of KIproBatt.
To access the JupyterLab Workflow Environment, visit kiprobatt.de/jupyter
Git Repos exist both on Github and FhG Gitlab
About KIproBatt - Intelligent battery cell manufacturing with AI-supported process monitoring based on a generic system architecture
Due to its complexity and vast economic as well as ecological impact, the Li-ion battery cell production process is subject to ongoing digitization and optimization in order to increase cell performance while reducing resource consumption and production costs.
In this context, artificial intelligence (AI) holds immense potential in leveraging manufacturing data to improve the cell production process. Hence, we aim to enhance cell production with AI-based end-to-end process monitoring, which covers all steps of the process chain. For this purpose, we develop a generic, software-implemented system architecture as reusable structure that allows us to connect the process data acquisition with a carefully constructed ontology-based semantic data space. Based on this system architecture, we attach machine learning approaches from two perspectives: In the first perspective, we apply both data and physics driven models to specific process parameters to detect and evaluate correlations and process anomalies. In the second perspective, we develop an overarching end-to-end process monitoring. For this application, we integrate the previously developed models into a dashboarding system in order to assess their relevance for cell performance and monitor the cells' state in production constantly and as real-time as possible.
The combination of these two perspectives allows us to detect defects early in the production process, rapidly increase the quality performance and derive flexible adjustments to the process parameters in case of malfunction or defects. Thus, we expect to reduce the total cost of cell production as well as improve its carbon footprint by reductions in resource and energy consumption. Finally, the generic, semantically structured design enables an easy transfer to other research and industrial processes.
About the KIproBatt Dataspace
Technically the KIproBatt plattform consists of the following OpenSource components
- Mediawiki: Most important Wiki framework, basis of Wikipedia
- Semantic Media Wiki: Semantic extension for MediaWiki
- JupyterLab: Cloud-based scripting environment, e. g. for Python
Mediawiki provides the basic document-based data structure. Furthermore, extensive interfaces for human (editors) and machine (API) are provided. Templates and forms ensure uniformity and efficiency. The extension Semantic Media Wiki provides the Wiki with numerous possibilities for linking and annotating data. In addition, semantic queries can be sent directly to the Wiki and results can be visualized in a variety of ways. Via JupyterLab users can access data stored in the Semantic Media Wiki, process it and push the results back to the Wiki.
This project is funded by the German Federal Ministry of Education and Research (BMBF), grant no. 03XP0309A-C.