How can failures in vibration tests be avoided?

Source: Alter Technology article

by María Teresa Rodríguez.

Vibration tests are important to check the reliability of the components/assemblies. These tests can be a headache and suppose a great cost if the design of the device and the fixing tool are not properly done. Simulation tools are the key to anticipate the problems reducing costs and lead times and doEEEt gives you access, in just one site, to components and specifications from different systems and space agencies

Introduction to Modal Analysis:

All objects have a natural frequency inherent to each object, at which they vibrate when they are subjected to certain external forces. When a force is applied at the object’s natural frequency, it goes into resonance, and a higher amplitude vibration response is created. This situation can cause a collapse of the object. To avoid resonance, the frequency applied should not be at or near the natural frequency of the device or element under test. If the forcing frequency cannot be changed, natural frequency needs to be modified. This can only be done by altering the mass or its stiffness.

Simulation is used to validate the designs before manufacturing and testing phase in a laboratory. It is really useful to crosscheck the results of this analysis with the results obtained in the validation of the final assembly under the applicable vibration test and avoiding the resonance effect.

Vibration simulation, as others, is based in finite element analysis (FEA). The main goal of a modal analysis is to determinate the natural frequencies and vibration modes of an element during vibration. Usually to develop this type of analysis, Finite Elements Method (FEM) is used.

FEM is a method to solve differential equations and boundary value problems. It involves dividing a whole domain into simpler parts that are called finite elements.

A set of finite elements that make up the model to be simulated is called mesh. The mesh should be as regular and uniform as possible, and the size of the elements will depend on the precision needed to reproduce properly the geometry of the item to simulate. Once the model is ready, simulation tools proceed to the calculation and analysis of the results.

 

 

 

 

Example of a discretization model in finite elements

 

Step of a Correct Simulation:
To develop a correct simulation, it is necessary to follow the steps showed in the diagram below:

The success relies on the simulation of the natural frequencies of the DUT, the fixing tool and the assembly of both parts. The final simulation consists of the analysis of the forced response of the assembly under the conditions of the requirements. If any of the results fails, a re-design of any of the parts (the device, the fixing tool or the assembly) is required.

Requirements for the Simulation:

To perform all the simulations, the following information needs to be provided:

For vibration conditions, Alter Technology frequently tests according to the next specifications:

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