Site icon Future Skill

ISO/TR 230-8:2010 Part 8: Vibrations

Introduction

ISO/TR 230-8:2010 represents a critical technical report within the ISO 230 series, focusing specifically on vibration measurement and analysis in machine tools. This document provides comprehensive guidelines for measuring, analyzing, and evaluating vibrations that affect machine tool performance and precision.

 

Scope and Application

The technical report addresses:

  • Measurement and evaluation of vibrations in stationary and operational states.
  • Impact of external and internal vibration sources.
  • Effects on machining precision and surface quality.
  • Standardized testing procedures and measurement protocols.

 

Key Technical Components

Measurement Parameters
  1. Displacement amplitude.
  2. Velocity measurements.
  3. Acceleration characteristics.
  4. Frequency spectrum analysis.
  5. Time domain measurements.

 

Testing Conditions
  • Steady-state operations.
  • Transient conditions.
  • Different spindle speeds.
  • Various tool configurations.
  • Load and no-load situations.

 

Measurement Points

The standard specifies critical measurement locations:

  • Machine tool foundation.
  • Machine frame.
  • Spindle housing.
  • Workpiece mounting points.
  • Tool interface points.

 

Evaluation Methods

Data Analysis
  • Fast Fourier Transform (FFT) analysis.
  • Time domain statistical analysis.
  • Frequency response functions.
  • Modal analysis techniques.

 

Assessment Criteria
  1. Peak-to-peak amplitudes.
  2. RMS values.
  3. Frequency content.
  4. Resonance identification.
  5. Damping characteristics.

 

Implementation Guidelines

Test Environment Requirements
  • Controlled ambient temperature.
  • Isolation from external vibration sources.
  • Stable foundation conditions.
  • Calibrated measurement equipment.

 

Documentation Requirements
  1. Machine tool specifications
  2. Test conditions and parameters
  3. Measurement equipment details
  4. Environmental conditions
  5. Data processing methods

 

Practical Applications

Quality Control
  • Acceptance testing.
  • Periodic monitoring.
  • Performance verification.
  • Troubleshooting.

 

Performance Optimization
  • Vibration isolation design.
  • Machine tool placement.
  • Operating parameter selection.
  • Maintenance scheduling.

 

Impact on Manufacturing

Production Quality
  • Surface finish improvement.
  • Dimensional accuracy.
  • Tool life optimization.
  • Process stability.

 

Economic Considerations
  • Maintenance cost reduction.
  • Production efficiency.
  • Quality assurance.
  • Equipment longevity.

 

Summary

It provides essential guidelines for understanding and controlling machine tool vibrations, directly impacting manufacturing quality and efficiency. Its implementation is crucial for maintaining high-precision manufacturing capabilities and ensuring consistent product quality.

 

Exit mobile version