Improve heavy equipment operability and productivity, and help your customers reduce operational costs. By combining system simulation tools, 3D analysis software including CFD, and testing solutions and services, our solution can help you during all stages of the development cycle - from selecting a design - to optimizing components and fine-tuning the control strategy, to testing the final product prototype.
Improve heavy equipment operability and productivity, and help your customers reduce operational costs. By combining system simulation tools, 3D analysis software including CFD, and testing solutions and services, our solution can help you during all stages of the development cycle - from selecting a design - to optimizing components and fine-tuning the control strategy, to testing the final product prototype.
Heavy equipment vendors push low operational costs as one of their customer-centric business vision assets. This makes operability and productivity optimization one of the most critical engineering tasks during design.
Evaluating multiple architectures, selecting the right one that does the job as effectively as possible, and assures moreover the cheapest well-balanced design really is the challenge for design engineers in the heavy equipment industry.
Engineers have to make sure to select and refine the right architecture that does the job as effectively as possible. Whether it’s mining equipment that has to displace enormous loads in rugged areas, farming equipment that needs to plow, seed, spray, or harvest, or construction equipment that has to dig, maneuver, or lift.
In order to deal with these challenges, heavy equipment engineers need tools that let them evaluate various system architectures for functional performance from the very beginning of the development cycle, as well as optimize the behavior of a chosen configuration during later stages. Making the right choice from the start will reduce the number of physical prototypes required to deliver a final product.
Analyze the kinematic and dynamic behavior of flexible and articulated mechanisms.
Model interactions of controlled electrical power networks, energy storage systems, machines and power converters with their loads and supplies.
Simulate flow at macro and micro-level.
Seamlessly design hydraulic systems, including networks and components.
Simulate the functional behavior of complex electromechanical actuators.
Design reliable components through optimization of thermal management by keeping the temperature within the optimal operating range, evacuating excess heat, or reusing it to improve performance.
Combine maximum thermal safety with high energy efficiency. Ensure all systems are correctly cooled down thanks to heat interaction optimization.
Increase machine efficiency in the field by producing more with less while keeping a strict eye on operator safety
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