Engineering
Research & Development
System Integration
Manufacturing
Click on the icons to explore the battery domains
With advanced 3D chemistry modeling and simulation, battery innovators are able to:
Efficient Modeling and Simulation
Predict material properties faster and more accurately
Explore battery cell materials more
cost-effectively
Understand battery performance and the underlying mechanism of material behaviors
Identify chemical interactions for enhanced property design and prediction
Efficient Modeling and Simulation
With the 3DEXPERIENCE® platform, engineers can test battery performance in a powerful virtual environment more efficiently compared to traditional “trial and error” approaches. The platform enables them to:
Effective Testing and Analytics
Integrate data for fast access and easy traceability
Simplify workflows for effective collaboration
Conduct advanced analysis for
decision-making
Leverage machine learning models effectively
Effective Testing and Analytics
Battery innovators can identify optimal components and processes in battery formulations by combining virtual twin models with Dassault Systèmes’ proprietary prediction methods to:
Optimal Formulation and Lab Management
Optimal Formulation and Lab Management
Improve understanding of chemical drivers by more than
Accelerate screening of broader formulation space by
Boost success rate from focused experiments by
Increase lab productivity by
With the rapid pace of battery innovation, battery developers must set up the best in class collaborative innovation platform to:
Foster Collaborative Innovation
Foster Collaborative Innovation
Effectively integrate engineering and manufacturing
Facilitate compliance with customer requirements
Meet global safety and quality standards
Accelerate design iterations with fact-based decisions
Battery innovators can leverage virtual twins to:
Manage Multiphysics Complexity
Predict charge and discharge cycles under various operating conditions
Optimize cell behavior (electrochemical, mechanical and thermal)
Understand swelling, dendrite growth, degradation and aging conditions
Validate manufacturability of cells with process modeling
Manage Multiphysics Complexity
Battery engineers can virtually optimize designs and select best design options by:
Make Informed Design Choices
Running what-if scenario analysis to study multiple battery designs
Running lifecycle assessments with multiple environmental criteria
Dealing with multidisciplinary trade-offs to make informed decisions
Make Informed Design Choices
Boost Battery Cell Production
Optimal battery cell production requires battery innovators to improve workforce management,
processes, resources and workflows. Communicating resource decisions downstream from the
start will help:
Boost Battery Cell Production
Improve processes, cut manufacturing costs and reduce cell production scrap rate by
Synchronize material flows to production in real time for maximum flexibility and scalability
Provide global manufacturing visibility and control to cut planning time by 60% and increase forecast precision by 10%
Eliminate paper tracking and manual data entry to reduce quality claims by
To deliver improved operational efficiency, battery innovators can leverage virtual models developed in design and engineering to provide detailed work instructions to:
Deliver Improved Efficiency
Assemble production lines for optimal physical space
Improve processes and minimize cost and stock levels
Boost production and maintain high levels of throughput
Manage constraints and disruptions to deliver at scale and on time
Deliver Improved Efficiency
Through virtual manufacturing processes and operations, battery innovators can implement scalable and future-proof planning while proactively mitigating risks with improved:
Scalable and Future-Proof Planning
Quicken line commissioning by up to 75% with virtual commissioning
Reorganize existing lines with minimum downtime
Speed
Get to market quicker by up to 30%
Uptime
Reduce manufacturing line failures by 15%
Mirror and monitor production systems to achieve and maintain peak process efficiency
Reduce fault rate and rework with robust virtual line testing
Leverage performance insights to improve machine capability and maximize user life
Monitor machines and collect data on the actual versus expected work performance
Performance Visibility
Output
Scalable and Future-Proof Planning
End-to-End Collaboration
Designing customized batteries for different devices is an increasingly complex challenge that combines scientific knowledge with technical expertise. System integration must be planned and optimized before the final assembly, by bringing together multidisciplinary teams to work towards a common end goal.
End-to-End Collaboration
End-to-end modeling and simulation on the 3DEXPERIENCE platform enable battery innovators to improve and optimize processes across all domains by:
Get System Integration Right the First Time
Reducing inefficiencies at every stage
Virtually integrating multiple elements like BMS, electrical and cooling systems
Engaging in proactive failure remediation right from the start
Get System Integration Right the First Time
Dassault Systèmes’ portfolio of world-class applications runs on the 3DEXPERIENCE platform and supports model-based systems engineering by leveraging virtual twin technology. Battery innovators can use these brand applications for multi-disciplinary, multi-scale modeling and simulation:
End-to-End Solutions
Discover and validate materials for safe, high performance battery on a molecular level
Predict the behavior of battery at the system level from the cell to the entire device
Understand the battery’s electrochemical, thermal and structural behaviors with accurate simulations and optimize design with trade-off analysis
Create realistic test conditions to model the pack as part of a device’s complete system architecture
End-to-End Solutions
Engineering
Research & Development
System Integration
Manufacturing
Click on the icons to explore the battery domains
With advanced 3D chemistry modeling and simulation, battery innovators are able to:
Efficient Modeling and Simulation
Predict material properties faster and more accurately
Explore battery cell materials more
cost-effectively
Understand battery performance and the underlying mechanism of material behaviors
Identify chemical interactions for enhanced property design and prediction
Efficient Modeling and Simulation
With the 3DEXPERIENCE® platform, engineers can test battery performance in a powerful virtual environment more efficiently compared to traditional “trial and error” approaches. The platform enables them to:
Effective Testing and Analytics
Integrate data for fast access and easy traceability
Simplify workflows for effective collaboration
Conduct advanced analysis for
decision-making
Leverage machine learning models effectively
Effective Testing and Analytics
Battery innovators can identify optimal components and processes in battery formulations by combining virtual twin models with Dassault Systèmes’ proprietary prediction methods to:
Optimal Formulation and Lab Management
Optimal Formulation and Lab Management
Improve understanding of chemical drivers by more than
Accelerate screening of broader formulation space by
Boost success rate from focused experiments by
Increase lab productivity by
With the rapid pace of battery innovation, battery developers must set up the best in class collaborative innovation platform to:
Foster Collaborative Innovation
Foster Collaborative Innovation
Effectively integrate engineering and manufacturing
Facilitate compliance with customer requirements
Meet global safety and quality standards
Accelerate design iterations with fact-based decisions
Battery innovators can leverage virtual twins to:
Manage Multiphysics Complexity
Predict charge and discharge cycles under various operating conditions
Optimize cell behavior (electrochemical, mechanical and thermal)
Understand swelling, dendrite growth, degradation and aging conditions
Validate manufacturability of cells with process modeling
Manage Multiphysics Complexity
Battery engineers can virtually optimize designs and select best design options by:
Make Informed Design Choices
Running what-if scenario analysis to study multiple battery designs
Running lifecycle assessments with multiple environmental criteria
Dealing with multidisciplinary trade-offs to make informed decisions
Make Informed Design Choices
Boost Battery Cell Production
Optimal battery cell production requires battery innovators to improve workforce management, processes, resources and workflows. Communicating resource decisions downstream from the start will help:
Boost Battery Cell Production
Improve processes, cut manufacturing costs and reduce cell production scrap rate by
Synchronize material flows to production in real time for maximum flexibility and scalability
Provide global manufacturing visibility and control to cut planning time by 60% and increase forecast precision by 10%
Eliminate paper tracking and manual data entry to reduce quality claims by
To deliver improved operational efficiency, battery innovators can leverage virtual models developed in design and engineering to provide detailed work instructions to:
Deliver Improved Efficiency
Assemble production lines for optimal physical space
Improve processes and minimize cost and stock levels
Boost production and maintain high levels of throughput
Manage constraints and disruptions to deliver at scale and on time
Deliver Improved Efficiency
Through virtual manufacturing processes and operations, battery innovators can implement scalable and future-proof planning while proactively mitigating risks with improved:
Scalable and Future-Proof Planning
Quicken line commissioning by up to 75% with virtual commissioning
Reorganize existing lines with minimum downtime
Speed
Get to market quicker by up to 30%
Uptime
Reduce manufacturing line failures by 15%
Mirror and monitor production systems to achieve and maintain peak process efficiency
Reduce fault rate and rework with robust virtual line testing
Leverage performance insights to improve machine capability and maximize user life
Monitor machines and collect data on the actual versus expected work performance
Performance Visibility
Output
Scalable and Future-Proof Planning
End-to-End Collaboration
Designing customized batteries for different devices is an increasingly complex challenge that combines scientific knowledge with technical expertise. System integration must be planned and optimized before the final assembly, by bringing together multidisciplinary teams to work towards a common end goal.
End-to-End Collaboration
End-to-end modeling and simulation on the 3DEXPERIENCE platform enable battery innovators to improve and optimize processes across all domains by:
Get System Integration Right the First Time
Reducing inefficiencies at every stage
Virtually integrating multiple elements like BMS, electrical and cooling systems
Engaging in proactive failure remediation right from the start
Get System Integration Right the First Time
Dassault Systèmes’ portfolio of world-class applications runs on the 3DEXPERIENCE platform and supports model-based systems engineering by leveraging virtual twin technology. Battery innovators can use these brand applications for multi-disciplinary, multi-scale modeling and simulation:
End-to-End Solutions
Discover and validate materials for safe, high performance battery on a molecular level
Predict the behavior of battery at the system level from the cell to the entire device
Understand the battery’s electrochemical, thermal and structural behaviors with accurate simulations and optimize design with trade-off analysis
Create realistic test conditions to model the pack as part of a device’s complete system architecture
End-to-End Solutions