Blogs
Machine Balancing
How Industrial Machines are Balanced in the UAE?
Industrial machines operate under continuous load at a high rotational speed. After prolonged use, small deviation in mass distribution occurs inside a rotating component, leading to significant vibration.
Abnormal noise, seal leakage, increasing bearing temperature, and repeated maintenance are some of the early signs that can let us know the issue is “rotor imbalance”.
Rotor imbalance occurs when the mass center of a rotating part does not coincide with the actual axis of rotation. This results in centrifugal forces that would increase at a high rate with the operating speed and get transferred to the bearings and machine supports.
If not addressed, rotor balance leads to structural fatigue, unexpected shutdown, and maintenance. To fix this, the rotating equipment needs “balancing” so that the rotational forces can be minimised.
Balancing machines is a preventive maintenance activity that improves equipment stability, reduces maintenance, and extends machine life. It can be classified as static and dynamic. Static balancing is used for low-speed or simple motors, while dynamic balancing is performed for most industrial equipment, like pumps, blowers, compressors, etc., that run at high speed and develop high unbalance along the rotor length. This makes dynamic balancing more common in industrial machine balancing.
This article explains the fundamentals of dynamic balancing, relevant ISO standards, and how the procedure is performed on an industrial machine.
How Acoustic Emission Testing (AET) Detects Material Defects
Vibration Sensors for Industrial Condition Monitoring: Types, Applications, and Benefits
Partial Discharge (PD) Testing: A Practical Q&A Guide
What Is Shaft Alignment and Its Role in Equipment Reliability
Preventive Maintenance Solutions for Long-Term Asset Performance
A Complete Guide To Earth Pit Testing: Importance, Methods, And Standards
What is Dynamic Balancing?
Dynamic balancing is the process of balancing a rotating component of a machine by correcting any uneven distribution of mass. It is performed when the machine is running.
Dynamic balancing ensures the component rotates without causing vibration, noise, or excessive wear.
Static Vs Dynamic Balancing
Features
Static Balancing
Dynamic Balancing
Condition
Performed on a stationary rotor
Performed while the rotor runs at operating speed
Purpose
Corrects a single heavy spot
Corrects the distributed imbalance along the rotor
Method
Component placed on balancing rollers to find the tilt point
Vibration amplitude and phase measured using instruments
Correction
Weight adjusted at one location
Correction weights applied at calculated positions or planes
Forces Considered
Gravity effect
Centrifugal forces during rotation
Application
Low-speed parts and simple components
Industrial rotating machinery such as motors, pumps, fans, and compressors
Role in Maintenance
Preliminary or basic balancing step
Final precision balancing for smooth operation
Accuracy Level
Limited
High accuracy
Dynamic Balancing ISO Standards
The international standard historically referenced for dynamic balancing is ISO 1940, now updated under ISO 21940-11. It is used to determine acceptable balance quality in rigid rotors.
ISO 1940 specifies:
- Allowable balance tolerances based on rotor mass and speed
- The required number of correction planes (single-plane or two-plane balancing)
- Procedures for verifying residual unbalance after correction
Dynamic Balancing Grade
Dynamic balancing is categorized into balance quality grades, or G-grades, according to ISO 1940. These grades define permissible residual imbalance and help maintenance teams match the balancing target to the application.
G16 - G40
For rough industrial components such as pulleys, conveyor rollers, and large ventilation fans, where higher vibration levels are acceptable.
G6.3
For standard industrial machinery, including electric motors, pumps, generators, and general-purpose turbines.
G2.5
For higher-speed equipment requiring improved smoothness, such as turbochargers, machine tool spindles, and performance fans.
G1.0
For precision assemblies, including aerospace mechanisms, gyroscopes, and sensitive measuring instruments, where very low vibration is necessary.
G0.4 - G0.1
These are ultra-precision grades intended for medical devices, optical systems, and micro-mechanical components.
Selecting the appropriate balancing grade helps minimize vibration, improve energy efficiency, and increase equipment reliability across UAE especially industrial facilities in Dubai, Abu Dhabi, and Sharjah.
Dynamic Balancing Planes - Single-Plane vs. Double-Plane Balancing
In dynamic balancing, there are specific positions at which we add correction weights to balance the machine. This position is called a balancing plane. Based on the shape and operating speed of the rotor, the weight correction may be required at one location or at multiple locations. Hence, dynamic balancing is either carried out in a single plane or in double-plane to control the vibration during the operation.
Single-Plane Balancing
Used for narrow or disc-type rotors. Imbalance is corrected at one location because the mass acts as a single concentrated force.
Eg: Suitable for components like pulleys and small fans.
Two-Plane Balancing
Used for long rotors where unbalance exists at different points along the shaft. Corrections are made in two separate planes to control both force and moment effects.
Eg: Motors, blowers, and large rotating equipment.
How to Balance a Machine: Step-by-Step Explanation
1. Equipment Assessment
The rotating equipment is first inspected to evaluate vibration levels and determine the presence of rotor unbalance. The technicians identify critical locations and operating conditions before corrective work begins.
2. Measurement Using Balancing Instruments
Specialized vibration analyzers and dynamic balancing instruments are installed to measure the magnitude and angular position of the unbalance while the machine is running.
3. Correction Procedure
Based on the measured data, corrective action is applied. This may involve adding or removing weights, adjusting component position, or fine-tuning the rotor to reduce vibration forces.
4. Calibration and Verification
After correction, the machine is run again at operating speed to verify that vibration levels fall within acceptable limits and smooth operation is restored.
5. Documentation and Reporting
A detailed balancing report is prepared, including initial readings, correction values, and final results. This record supports maintenance planning and future troubleshooting.
Why is Dynamic Balancing so Crucial?
Every rotating machine’s primary objective is to operate with controlled and acceptable vibration. Even though the complete elimination of vibration is not practical, maintaining proper balance keeps the machine vibration within safe limits. The main goal is to achieve a correct rotor balance so that the machine runs smoothly and reliably.
Many industrial facilities have achieved immediate performance improvement in the following areas after performing dynamic balancing:
Increased Equipment Life
Dynamic balancing helps to decrease excessive vibration caused by hydraulic or aerodynamic effects. This preventive maintenance step therefore prevents the wear caused in the related parts and extends the lifespan of the machine.
Improved Operational Safety
Severe imbalance in machines due to continuous vibration results in unexpected shutdowns and unsafe working conditions. Proper balancing can protect the personnel and the equipment.
Improved Product Quality
High-speed machines produce inaccurate results that affect the output quality. Dynamic balancing helps to achieve stable operation, thus ensuring consistent product quality.
Reduce Noise and Improve Performance
Excessive vibration and noise are indicators of poor equipment condition. This affects the product acceptance and operational performance. Dynamic balancing makes the machine smooth, quiet, and efficient.
Versatile
The dynamic balancing process can be applied to a wide range of equipment, including pumps, generators, crankshafts, and other turbomachineries.
Benefits of Dynamic Balancing
The major benefits of dynamic balancing are as follows:
- Elimination of Root Cause of Vibration
- Extends Bearing Life
- Prevent Repeated Failures
- Reduce Noise Levels
- Protects the Machine Structure
- Improve Energy Efficiency
- Enhances Operational Safety
- Minimise Unplanned Downtime
- Increase the Lifespan of the Equipment
- Improves Workplace Comfort and Productivity
Importance of Dynamic Field Balancing
In practice, the removal of large motors and taking them to the workshop is rarely feasible. So dynamic balancing is most commonly carried out directly on operating machines. This is called dynamic field balancing.
The importance of dynamic field balancing includes:
- Eliminate the vibration of the equipment at the source
- Prevents bearing and seal failure
- Avoid production shutdown
- Achieve accurate balancing
- Prevents structural damage
- Improve energy efficiency and safety
- Increase equipment life
Balance your Machine in the UAE with Asset Condition Monitoring
Dynamic balancing is not considered an occasional repair. It is performed as a standard part of every overhaul, inspection, and maintenance activity. Trusted and experienced experts ensure the root cause is eliminated rather than repeatedly treating the consequences.
Looking for Balance Machines in UAE?, Partner with us. At Asset Condition Monitoring, dynamic balancing is treated as a continuous reliability process, not an occasional repair. Here, we provide a proper balancing process through accurate measurement, vibration analysis, and precise correction.