How Efficient Energy Management Systems (EMS) Power Up eVTOLs
Energy-Efficient Engineering Designs
Parametric modeling and simulation foster faster prototyping and robust engineering designs for optimal energy consumption, enabling:
Aerodynamic advancements:
Optimize eVTOL body design for airflow, energy flow, noise control, insulation material performance, vibration and thermal management to enhance fuel efficiency and carbon savings.
Structural improvements:
Streamlined design keeps structural integrity and reduces eVTOL weight by as much as 35%, surpassing any aircraft weight standards for energy efficiency.
Multidiscipline Multiscale Performance Optimization
Simulation incorporates EMS right from the start to ensure proper monitoring and optimization of overall energy distribution, including:
Trajectory optimization:
Trajectory planning in an eVTOL can reduce energy consumption while securing the right energy reserves to land safely.
Risk reduction:
Risk factors such as density altitude, airspeed and collision avoidance algorithms are calculated to assess energy consumption risk for emergency reserves and regulatory compliance.
Model-Based Certification
Leverage the virtual twin to ensure the safety of innovative products and accelerate certification through:
Full envelope virtual testing:
Seamlessly integrate real-world and virtual testing and improve regulatory measures, compliance and certification plans through platform-driven visibility and traceability throughout the certification process.
Robust governance:
Foster better collaboration and accelerate the assessment and validation of EMS in eVTOLs to guarantee the safety of the final product while keeping certification time and cost under control.
How Efficient Energy Management Systems (EMS) Power Up eVTOLs
Multidiscipline Multiscale Performance Optimization
Simulation incorporates EMS right from the start to ensure proper monitoring and optimization of overall energy distribution, including:
Trajectory optimization:
Trajectory planning in an eVTOL can reduce energy consumption while securing the right energy reserves to land safely.
Risk reduction:
Risk factors such as density altitude, airspeed and collision avoidance algorithms are calculated to assess energy consumption risk for emergency reserves and regulatory compliance.
Model-Based Certification
Leverage the virtual twin to ensure the safety of innovative products and accelerate certification through:
Full envelope virtual testing:
Seamlessly integrate real-world and virtual testing and improve regulatory measures, compliance and certification plans through platform-driven visibility and traceability throughout the certification process.
Robust governance:
Foster better collaboration and accelerate the assessment and validation of EMS in eVTOLs to guarantee the safety of the final product while keeping certification time and cost under control.
How Efficient Energy Management Systems (EMS) Power Up eVTOLs
Energy-Efficient Engineering Designs
Parametric modeling and simulation foster faster prototyping and robust engineering designs for optimal energy consumption, enabling:
Aerodynamic advancements:
Optimize eVTOL body design for airflow, energy flow, noise control, insulation material performance, vibration and thermal management to enhance fuel efficiency and carbon savings.
Structural improvements:
Streamlined design keeps structural integrity and reduces eVTOL weight by as much as 35%, surpassing any aircraft weight standards for energy efficiency.
Model-Based Certification
Leverage the virtual twin to ensure the safety of innovative products and accelerate certification through:
Full envelope virtual testing:
Seamlessly integrate real-world and virtual testing and improve regulatory measures, compliance and certification plans through platform-driven visibility and traceability throughout the certification process.
Robust governance:
Foster better collaboration and accelerate the assessment and validation of EMS in eVTOLs to guarantee the safety of the final product while keeping certification time and cost under control.
How Efficient Energy Management Systems (EMS) Power Up eVTOLs
Energy-Efficient Engineering Designs
Parametric modeling and simulation foster faster prototyping and robust engineering designs for optimal energy consumption, enabling:
Aerodynamic advancements:
Optimize eVTOL body design for airflow, energy flow, noise control, insulation material performance, vibration and thermal management to enhance fuel efficiency and carbon savings.
Structural improvements:
Streamlined design keeps structural integrity and reduces eVTOL weight by as much as 35%, surpassing any aircraft weight standards for energy efficiency.
Multidiscipline Multiscale Performance Optimization
Simulation incorporates EMS right from the start to ensure proper monitoring and optimization of overall energy distribution, including:
Trajectory optimization:
Trajectory planning in an eVTOL can reduce energy consumption while securing the right energy reserves to land safely.
Risk reduction:
Risk factors such as density altitude, airspeed and collision avoidance algorithms are calculated to assess energy consumption risk for emergency reserves and regulatory compliance.
How Efficient Energy Management Systems (EMS) Power Up eVTOLs
Energy-Efficient
Engineering Designs
Parametric modeling and simulation foster faster prototyping and robust engineering designs for optimal energy consumption, enabling:
Aerodynamic advancements:
Optimize eVTOL body design for airflow, energy flow, noise control, insulation material performance, vibration and thermal management to enhance fuel efficiency and carbon savings.
Structural improvements:
Streamlined design keeps structural integrity and reduces eVTOL weight by as much as 35%, surpassing any aircraft weight standards for energy efficiency.
Multidiscipline Multiscale
Performance Optimization
Simulation incorporates EMS right from the start to ensure proper monitoring and optimization of overall energy distribution, including:
Risk reduction:
Risk factors such as density altitude, airspeed and collision avoidance algorithms are calculated to assess energy consumption risk for emergency reserves and regulatory compliance.
Trajectory optimization:
Trajectory planning in an eVTOL can reduce energy consumption while securing the right energy reserves to land safely.
Model-Based Certification
Leverage the virtual twin to ensure the safety of innovative products and accelerate certification through:
Robust governance:
Foster better collaboration and accelerate the assessment and validation of EMS in eVTOLs to guarantee the safety of the final product while keeping certification time and cost under control.
Full envelope virtual testing:
Seamlessly integrate real-world and virtual testing and improve regulatory measures, compliance and certification plans through platform-driven visibility and traceability throughout the certification process.
How Efficient Energy Management Systems (EMS) Power Up eVTOLs
Multidiscipline Multiscale
Performance Optimization
Simulation incorporates EMS right from the start to ensure proper monitoring and optimization of overall energy distribution, including:
Risk reduction:
Risk factors such as density altitude, airspeed and collision avoidance algorithms are calculated to assess energy consumption risk for emergency reserves and regulatory compliance.
Trajectory optimization:
Trajectory planning in an eVTOL can reduce energy consumption while securing the right energy reserves to land safely.
Model-Based Certification
Leverage the virtual twin to ensure the safety of innovative products and accelerate certification through:
Robust governance:
Foster better collaboration and accelerate the assessment and validation of EMS in eVTOLs to guarantee the safety of the final product while keeping certification time and cost under control.
Full envelope virtual testing:
Seamlessly integrate real-world and virtual testing and improve regulatory measures, compliance and certification plans through platform-driven visibility and traceability throughout the certification process.
How Efficient Energy Management Systems (EMS) Power Up eVTOLs
Energy-Efficient
Engineering Designs
Parametric modeling and simulation foster faster prototyping and robust engineering designs for optimal energy consumption, enabling:
Aerodynamic advancements:
Optimize eVTOL body design for airflow, energy flow, noise control, insulation material performance, vibration and thermal management to enhance fuel efficiency and carbon savings.
Structural improvements:
Streamlined design keeps structural integrity and reduces eVTOL weight by as much as 35%, surpassing any aircraft weight standards for energy efficiency.
Model-Based Certification
Leverage the virtual twin to ensure the safety of innovative products and accelerate certification through:
Robust governance:
Foster better collaboration and accelerate the assessment and validation of EMS in eVTOLs to guarantee the safety of the final product while keeping certification time and cost under control.
Full envelope virtual testing:
Seamlessly integrate real-world and virtual testing and improve regulatory measures, compliance and certification plans through platform-driven visibility and traceability throughout the certification process.
How Efficient Energy Management Systems (EMS) Power Up eVTOLs
Energy-Efficient
Engineering Designs
Parametric modeling and simulation foster faster prototyping and robust engineering designs for optimal energy consumption, enabling:
Aerodynamic advancements:
Optimize eVTOL body design for airflow, energy flow, noise control, insulation material performance, vibration and thermal management to enhance fuel efficiency and carbon savings.
Structural improvements:
Streamlined design keeps structural integrity and reduces eVTOL weight by as much as 35%, surpassing any aircraft weight standards for energy efficiency.
Multidiscipline Multiscale
Performance Optimization
Simulation incorporates EMS right from the start to ensure proper monitoring and optimization of overall energy distribution, including:
Risk reduction: Risk factors such as density altitude, airspeed and collision avoidance algorithms are calculated to assess energy consumption risk for emergency reserves and regulatory compliance.
Trajectory optimization:
Trajectory planning in an eVTOL can reduce energy consumption while securing the right energy reserves to land safely.
