Ensuring efficient vessel performance requires integration and optimization of multiple complex systems. Our solutions allow designers to check system architecture impacts on the complete vessel performance before any physical development takes place. Simulate and validate components early in the design cycle, and accurately predict the performance of systems including propulsion system architectures, hydraulic systems, and environmental control systems.
Ensuring efficient vessel performance requires integration and optimization of multiple complex systems. Our solutions allow designers to check system architecture impacts on the complete vessel performance before any physical development takes place. Simulate and validate components early in the design cycle, and accurately predict the performance of systems including propulsion system architectures, hydraulic systems, and environmental control systems.
Reducing fuel consumption and emissions to meet environmental regulations requires optimal system performance and controls to design efficient, eco-friendly powertrain systems, including traditional, electric and hybrid. Marine system designers also need to improve overall performance, energy flow, NVH comfort and cargo capacity to differentiate from the competition.
Our system simulation solutions are designed for mechatronic system performance engineering from early design stage through to validation and controls calibration. Develop hybrid marine powertrains faster by selecting efficient architectures, component sizing and related control system strategy. Optimize engine efficiency and energy recovery systems with the early design of new system architectures reducing energy consumption and test costs while improving safety and durability. Our portfolio allows connected system simulation to perform full ship system performance analysis and find optimal fuel consumption for different scenarios.
Our system performance and controls solutions enable:
Explore the key areas of this solution.
Assess and optimize fluid systems’ performance from the beginning of the design cycle. Study energy consumption of pneumatic and hydraulic systems when they interact with their environment, and integrate complex controls from the early development phases.
Address the growing complexity of propulsion systems for the marine industry. Model a wide range of propulsion technologies, from standard fuel systems to novel hybrid or electrified designs. Assess system performance and integration within the vessel.
Address vessel system complexity and integration from the early design phase with our system simulation solutions.
船舶设计的数字孪生是否已成为现实?它将如何影响船舶设计?
了解 Veth Propulsion 如何使用 CFD 优化船舶推进器,确保设计符合质量和舒适度级别要求。
仿真驱动型船舶设计方法可以降低成本并加快设计时间。了解如何自信地实现目标。 为了提高船舶效率和减少排放,船舶行业承受着持续的压力。对于船厂和船东而言,确保实现目标的方式就是设计并建造高效的船舶。船舶设计阶段就已决定能否提高效率并降低建造成本。 在本白皮书中,我们将介绍仿真驱动型船舶设计流程,这...
Predicting the behavior of any component or system early in the design process
