arrow_back_ios

Main Menu

See All Acoustic End-of-Line Test Systems See All DAQ and instruments See All Electroacoustics See All Software See All Transducers See All Vibration Testing Equipment See All Academy See All Resource Center See All Applications See All Industries See All Insights See All Services See All Support See All Our Business See All Our History See All Our Sustainability Commitment See All Global Presence
arrow_back_ios

Main Menu

See All Actuators See All Combustion Engines See All Durability See All eDrive See All Production Testing Sensors See All Transmission & Gearboxes See All Turbo Charger See All DAQ Systems See All High Precision and Calibration Systems See All Industrial electronics See All Power Analyser See All S&V Hand-held devices See All S&V Signal conditioner See All Test Solutions See All DAQ Software See All Drivers & API See All nCode - Durability and Fatigue Analysis See All ReliaSoft - Reliability Analysis and Management See All Test Data Management See All Utility See All Vibration Control See All Acoustic See All Current / voltage See All Displacement See All Load Cells See All Pressure See All Strain Gauges See All Torque See All Vibration See All LDS Shaker Systems See All Power Amplifiers See All Vibration Controllers See All Accessories for Vibration Testing Equipment See All Training Courses See All Whitepapers See All Acoustics See All Asset & Process Monitoring See All Custom Sensors See All Data Acquisition & Analysis See All Durability & Fatigue See All Electric Power Testing See All NVH See All Reliability See All Smart Sensors See All Vibration See All Weighing See All Automotive & Ground Transportation See All Calibration See All Installation, Maintenance & Repair See All Support Brüel & Kjær See All Release Notes See All Compliance See All Our People
arrow_back_ios

Main Menu

See All CANHEAD See All GenHS See All LAN-XI See All MGCplus See All Optical Interrogators See All QuantumX See All SomatXR See All Accessories See All Accessories See All BK Connect / Pulse See All API See All Microphone Sets See All Microphone Cartridges See All Acoustic Calibrators See All Special Microphones See All Microphone Pre-amplifiers See All Sound Sources See All Accessories for acoustic transducers See All Experimental testing See All Transducer Manufacturing (OEM) See All Accessories See All Non-rotating (calibration) See All Rotating See All CCLD (IEPE) accelerometers See All Charge Accelerometers See All Impulse hammers / impedance heads See All Cables See All Accessories See All Electroacoustics See All Noise Source Identification See All Environmental Noise See All Sound Power and Sound Pressure See All Noise Certification See All Industrial Process Control See All Structural Health Monitoring See All Electrical Devices Testing See All Electrical Systems Testing See All Grid Testing See All High-Voltage Testing See All Vibration Testing with Electrodynamic Shakers See All Structural Dynamics See All Machine Analysis and Diagnostics See All Calibration Services for Transducers See All Calibration Services for Handheld Instruments See All Calibration Services for Instruments & DAQ See All On-Site Calibration See All Resources See All Software License Management

Vibration Control Strategies for Shaker Systems


This article covers some of the basic ideas and concepts relating to vibration control strategies for shaker vibration testing. It explains the need for control accelerometers and gives guidance on where to place them.

Nearly all vibration tests cover a frequency range where mechanical resonances occur in a system consisting of payload, fixture and armature. In this context, the test is controlled by acceleration, based on the following basic equation at constant mass:

force = mass × acceleration (f = ma)

However, under resonance conditions, the effective mass does not remain constant. Therefore, poor vibration control can lead to underloading or overloading of the payload and damage due to overdriving of the armature. Choosing where to place the control accelerometers is one of the most critical parts of any vibration test.

There are no universally suitable active vibration control positions. Nevertheless, the wrong positions can damage the vibration equipment or affect the accelerations applied to the payload. The following principles should therefore be observed:

  • All mechanical structures have resonances
  • The larger a structure, the lower the resonant frequency
  • For increased mass without increased stiffness, the resonant frequency will reduce
  • For increased stiffness without increased mass, the resonant frequency will increase
  • In a free system, when a purely axial resonance occurs, the liveliest points will always be the ends

 

Choosing the Control Position

The most obvious reason for control accelerometers is to limit the acceleration into the payload. If the payload is large and/or the frequency range is high, at some point one or more resonances will occur. This can be seen as the difference in acceleration levels over the fixture. 

If only one accelerometer position is used in a test, the control loop ensures control of acceleration at that position only. If this position coincides with a resonance node where there is little or no motion, the rest of the structure can be accelerated by more than a hundred times the control value. 

To determine if a control accelerometer is attached to a node, a look at the drive signal, showing the dynamics of the system, provides clarity. A decrease in the drive indicates resonance, and an increase in the drive indicates anti-resonance. In case of anti-resonance, the control positions should be changed. Examples of good and bad drive plots are shown in the figure below.

Graph showing vibration control strategies

As the location of nodes changes with frequency, finding a point where they will not occur is difficult. It is for this reason that several accelerometer positions should be used. The best area to place accelerometers, with least risk of finding a node, is at the end of the system. If this is not possible, the monitors should be adjusted with notching levels so that the vibrator is not damaged.

 

Random vs Sine Testing

There is a difference between the control system of a shaker in sine and random testing. 

Sine Testing

The amplifier monitors the voltage and current supplied to the shaker, stopping the test if either exceeds the preset trip levels. In case of a high-level test, and if the control position is at a node, the drive power may increase above the trip level, causing the system to shut down.

Random Testing

The amplifier monitors RMS voltage and current in a similar manner. If the control position is at a node, the amplifier will not shut down if the total voltage and current remain below the trip level. This remains true even though the shaker may be producing more force than required. 

A further complication is that, at the resonant frequency of the armature itself, there is a large amount of ‘free energy’. Little voltage and current is required to drive the armature at this frequency. It is possible to damage the armature by overdriving the shaker without causing amplifier shutdown. Placing a control accelerometer at the end of the system protects against this danger, since it moves in a similar way to the armature at the other end.

 

The Best Practice for Your Control Strategy

Following good practice as described below will maximize the life of the equipment:

  1. Always attach an accelerometer to the end of the system to either control or monitor it. Set the limits to the maximum theoretical acceleration using the calculation f = ma.
  2. Large slip tables may require several control accelerometers positioned at the end. The corner of the plate will be vibrating at a different level to the centre, and at higher frequencies.
  3. Run low-level sine sweeps over the entire testing frequency range to characterize the fixture and payload. This could be low-level random if sine is prohibited. Low level means approximately –12 dB of the full test level.
  4. Review the drive to ensure there are no rises past the nominal drive level.
  5. Use the results to modify the control strategy if required.
  6. Pay attention to the energy outside the frequency band during random operation. The bandwidth should be at least 1.5 times the highest control frequency.
  7. If this energy is large or at the same level as the controlled energy, an investigation should be made before proceeding.
  8. If problems occur, look at the real-time acceleration recording. This may reveal problems that are not visible in the frequency domain.
  9. If everything is fine, proceed to the test level.

This will protect the shaker from damage as much as possible. If these precautions are not taken, the shaker will be forced to deliver more than the intended force or acceleration levels, shortening its life. 

 

Discover LDS Vibration Test Systems and HBK Accelerometers:

> LDS Vibration Test Equipment 
> HBK Accelerometers