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Mechanical Systems | |
![]() ![]() Motion Analysis of Rigid Body Systems!![]() Minimize your rigid body system design time and explore more design options with Mechanical Systems. This powerful package speeds up your prototyping and simulation tasks, helping you develop and modify complex models, plus instantly visualize and analyze your design changes. Using the complete library of over 50 two- and three-dimensional geometric constraints in Mechanical Systems, you can easily model complex mechanical relationships and define custom algebraic constraints to model nongeometric or control relationships. The object-oriented, model-building commands let you assemble constraints into a complete mechanism that can be solved for component position, velocity, and acceleration. By applying loads to the model, you can quickly solve for static reaction forces at mechanism joints or for dynamic forces when inertia properties are defined. Mechanical Systems can also return mathematical components of a model in symbolic form, including equations of motion, algebraic constraints, inertia matrices, and Coriolis forces. To reflect mechanism motion, extensive graphics functions let you locate and animate complex images. FeaturesKinematic Modeling of Fully Constrained Systems
Statics and Dynamics of Fully Constrained Systems
Motion Analysis of Underconstrained Systems
Mechanism Design Tools
Sample ImagesMechanical Systems contains a library of two- and three-dimensional geometric constraints that can be used to model mechanical relationships. And, custom algebraic constraints can be defined to model nongeometric or control relationships. ![]() Mechanical Systems' cam constraints support both analytic and mapped cam profiles. ![]() If mass properties are defined for the bodies in a model, Mechanical Systems can calculate the inertial loads on the model and the resulting reaction forces. ![]() After building a model, the next step is running it. In this particular case, the constraint equations are solved for a certain crank angle, and the coordinants of each of the bodies of the model are returned. ![]() Mechanical Systems uses gear constraints to model nominal gear relationships (i.e., only the nominal rotary motion is modeled, not the tooth-to-tooth interactions of an involute gear set; however, a single pair of involute gear teeth can be modeled as a pair of cam surfaces). ![]() By applying loads to a model, one can solve for static reaction forces at mechanism joints. ![]() Mechanical Systems performs motion analysis of underconstrained systems including static equilibrium analysis as well as velocity equilibrium analysis. ![]() Mechanical Systems also includes advanced methods of kinematic modeling such as multistage mechanisms. ![]() Object-oriented, model-building commands can be used to easily assemble constraints into a complete mechanism that can be solved for component position, velocity, and acceleration. ![]() System Requirements: Search HALLoGRAM || Request More Information CALL TOLL FREE 1-866-340-3404 |
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