Understanding CNC Machine Tolerances and Their Impact on Part Accuracy
Understanding CNC Machine Tolerances and Their Impact on Part Accuracy
In the field of precision manufacturing, CNC machine tool tolerance is a core indicator of the quality of parts processing, which directly affects the assembly performance, functional reliability and service life of the product. Whether it is aerospace components or medical devices, the strict control of CNC tolerances has become the key to enterprise competitiveness. This article will be from the definition of tolerance, influencing factors, control methods, three dimensions of in-depth analysis of the precision logic of CNC machine tools, and share how to optimise the technology to achieve the overall improvement of the accuracy of the parts.
I. Analysis of CNC tolerances: from basic concepts to industry standards
1. What is CNC tolerance?
Definition: CNC tolerance refers to the CNC machine tool machining process, the actual size of the part and the design of the size of the allowable deviation range.
Classification:
Dimensional tolerances: such as hole diameter, shaft diameter of ± 0.01mm.
Form and position tolerance: including flatness, roundness, perpendicularity, etc. (such as flatness ≤ 0.005mm).
Surface roughness: Ra value (such as Ra 0.8μm) affects the friction and sealing performance.
2. Comparison of industry tolerance standards
ISO 2768: Medium accuracy requirements for general mechanical parts (e.g. m-level tolerances).
ASME Y14.5: High-precision areas (such as aviation, automotive) of the stringent standards.
Enterprise internal control standards: some precision manufacturers require tolerances of ± 0.005mm or less.
II. Affect the CNC tolerance and precision of the parts of the 5 key factors
1. machine tool rigidity and thermal stability
Problem: Machine vibration or temperature rise (spindle elongation of about 12μm for every 1℃ rise) leads to machining errors.
Solution:
Select mineral casting bed to reduce thermal deformation.
Install a constant temperature cooling system to control the ambient temperature within ±1℃.
2. Tool wear and cutting parameters
Data: When machining aluminium alloy with carbide tools, the wear is about 0.02mm per 100 pieces.
Optimisation strategy:
Dynamically adjust the feed rate and depth of cut (e.g. F=2000mm/min, ap=0.2mm).
Extend the life by 30% by using coated tool (TiAlN).
3. Clamp positioning error
Typical error sources:
Fixture repetitive positioning accuracy (e.g. ±0.003mm).
Workpiece clamping force deformation (thin-walled parts deformation up to 0.1mm).
Improvement programme:
Use hydraulic/vacuum clamps to reduce contact stresses.
Increase auxiliary support points to disperse the clamping force.
4. CNC system and feedback accuracy
Core indicators:
Raster scale resolution (1μm level).
Repeat positioning accuracy of servo motor (±0.002mm).
Technology upgrade:
Five-axis linkage CNC system (e.g. Heidenhain TNC640).
Real-time compensation algorithm to correct trajectory error.
5. Material properties and residual stress
Case: Aluminium alloy 6061-T6 rebound of about 0.05-0.1mm after machining.
Countermeasures:
Pre-ageing treatment to eliminate material internal stress.
Staged roughing and finishing (leaving a margin of 0.1mm).
III. Enhance the accuracy of the parts of the 4 core technologies
1. Online detection and compensation processing
Technology flow:
Measurement in machining → data feedback → real-time correction of tool path.
Effect:
Reduce tolerance fluctuations by 50%, suitable for mass production consistency requirements.
2. Intelligent management of tool life
Solution:
RFID chip tracks tool wear status.
Predictive replacement (alarm when 10% life remaining).
3. Multi-process co-optimisation
Typical scenario:
Mill-turn machining reduces the number of clamping times and improves accuracy by 20%.
5-axis machine tools form complex surfaces in one go, avoiding cumulative errors.
4. Digital process simulation
Tool application:
VERICUT simulates the machining process and predicts the risk of interference and overcutting.
Finite Element Analysis (FEA) predicts workpiece deformation.
IV. How to choose a high-precision CNC machining service provider?
1. Core assessment indicators
Machine Configuration: 5-axis linkage, linear motor drive, nano-scale grating.
Quality control system: ISO 9001 certification, three-dimensional inspection coverage.
Case data: historical project tolerance achievement rate (e.g. 99.5% or more).
2. Industry application scenarios
Medical devices: joint implant surface roughness Ra ≤ 0.4μm.
Optical devices: flatness requirement ≤ 0.001mm.
V. JLCCNC: Global Partner for Precision Parts Manufacturing
JLCCNC focuses on high-precision CNC machining, and through technological innovation and strict management, we provide customers worldwide with precision parts with tolerance control within ±0.005mm.
Contact JLCCNC today to push the limits of precision for your parts!
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