Precision Measurement System for Cylindrical Gear Machining Parameters with Manufacturing Error Compensation

This paper presents an advanced measurement system designed to evaluate machining parameters of cylindrical gears while accounting for permissible manufacturing deviations. By integrating machine vision and motion control technologies, the system achieves enhanced accuracy in gear parameter quantification through systematic error compensation strategies.

System Architecture and Hardware Implementation

The measurement framework for cylindrical gear analysis comprises three primary modules:

Module	Component	Specification
Optical Acquisition	Dual Telecentric Lens	0.0415× magnification, 8μm resolution
Motion Control	3-Axis Precision Stage	±3μm positioning accuracy, 200mm travel
Data Processing	Industrial PC	Xeon E5-2678, 64GB RAM

The optical system resolves gear tooth profiles using:

$$ \rho = x\cos\theta + y\sin\theta $$

where (x,y) represents image coordinates, ρ denotes radial distance, and θ indicates angular displacement.

Error-Compensated Image Processing

The system implements modified Hough transform for cylindrical gear profile extraction:

$$ Q(\rho,\theta) = \sum_{i=1}^{n} \delta(\rho – x_i\cos\theta – y_i\sin\theta) $$

where δ is Dirac delta function, n represents edge pixels, and Q(ρ,θ) accumulates evidence in parameter space.

Error Compensation Parameters

Error Type	Compensation Factor	Range
Tooth Spacing	0.12-0.18μm/px	±5μm
Profile Deviation	0.08-0.15μm/°	±3°
Helix Angle	0.25μm/arcmin	±15′

Measurement Algorithm for Cylindrical Gears

The tooth pitch measurement algorithm incorporates error tolerance:

$$ P_d = \frac{1}{N}\sum_{k=1}^{N} \left( \frac{2\pi r}{Z} – \Delta_k \right) $$

where Z = number of teeth, r = reference radius, and Δ_k = measured pitch deviation.

System Performance Comparison

Parameter	Proposed System	Conventional System	Improvement
Tooth Profile Error	2.3μm	3.1μm	25.8%
Pitch Accumulation	4.7μm	6.5μm	27.7%
Runout Measurement	5.2μm	7.8μm	33.3%

Experimental Verification

Testing on ISO 1328-1 Grade 5 cylindrical gears demonstrated:

$$ \sigma_{\text{total}} = \sqrt{\sigma_{\text{profile}}^2 + \sigma_{\text{pitch}}^2 + \sigma_{\text{helix}}^2} $$

where σ_total represents combined standard uncertainty, reduced by 18.6% compared to conventional systems.

Conclusion

This measurement system for cylindrical gears demonstrates significant improvements in parameter quantification accuracy through manufacturing error compensation. The integration of adaptive image processing and precision motion control enables reliable quality assessment for high-precision cylindrical gear manufacturing processes.