MSC Adams

MSC ADAMS (Automated Dynamic Analysis of Mechanical Systems) is a multibody dynamics simulation software system. It is currenty owned by MSC Software Corporation. The simulation software solver runs mainly on Fortran and more recently C++ as well.[1] According to the publisher, Adams is the most widely used multibody dynamics simulation software.[2] The software package runs on both Windows and Linux.

Capabilities

Adams has a full graphical user interface to model the entire mechanical assembly in a single window. Graphical Computer-aided design tools are used to insert a model of a mechanical system in three-dimensional space or import geometry files such as STEP or IGS. Joints can be added between any two bodies to constrain their motion. Variety of inputs such as velocities, forces, and initial conditions can be added to the system.

Adams simulates the behavior of the system over time and can animate its motion and compute properties such as accelerations, forces, etc. The system can include further complicated dynamic elements like springs, friction, flexible bodies, contact between bodies.[2] The software also provides extra CAE tools such as design exploration and optimization based on selected parameters. The inputs and outputs of the simulation can be interfaced with Simulink for applications such as control.

Applications

The Adams software package is used both in academic research and engineering. The most common usage of the software is analysis of vehicle structure and suspension through the Adams/Car and Adams/Tire modules.[3][4][5] Various types of mechanical systems such as wind turbines,[6] powertrains,[7] and robotic systems.[8]

References

  1. Ortiz, Jose (May 18, 2011). "Introduction to Adams/Solver C++" (PDF). mscsoftware.com. Retrieved June 2, 2020.
  2. "Adams Real Dynamics for Functional Virtual Prototyping" (PDF). MSC Software. September 2013. Retrieved June 2, 2020.
  3. Jadav, Chetan S., and Jignesh R. Gautam. "Multibody Dynamic Analysis of The Suspension System Using Adams." International Journal for Scientific Research & Development 2.03 (2014): pp.
  4. Li, Sheng-qin, and Le He. "Co-simulation study of vehicle ESP system based on ADAMS and MATLAB." Journal of Software 6.5 (2011): 866-872.
  5. Burdzik, R., and B. Łazarz. "Analysis of properties of automotive vehicle suspension arm depending on different materials used in the MSC. Adams environment." Archives of Materials Science and Engineering 58.2 (2012): 171-176.
  6. Zierath, János, Roman Rachholz, and Christoph Woernle. "Field test validation of Flex5, MSC. Adams, alaska/Wind and SIMPACK for load calculations on wind turbines." Wind Energy 19.7 (2016): 1201-1222.
  7. Peicheng, Shi, Chen Wuwei, and Chen Liqing. "Study on Vibration Isolation Characteristics of Automobile Powertrain Mount System Based on Co-simulation." Transactions of the Chinese Society for Agricultural Machinery 41.2 (2010): 29.
  8. Cheraghpour, Farzad, et al. "Dynamic modeling and kinematic simulation of Stäubli© TX40 robot using MATLAB/ADAMS co-simulation." 2011 IEEE International Conference on Mechatronics. IEEE, 2011.
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