Casting Defect Analysis and Process Optimization for High-Stress Components

In industrial casting applications, components like pull rod seats present unique challenges due to structural complexity and stringent quality requirements. This article details a systematic approach to resolving persistent casting defects through advanced process optimization and computational modeling.

1. Critical Challenges in Casting Defect Formation

The primary casting defects observed in initial production trials included shrinkage porosity and sand inclusion, particularly in thick-section regions. Key contributing factors were identified through metallurgical analysis:

Defect Type	Location	Formation Mechanism
Shrinkage porosity	Junction of flange and rod	Insufficient feeding during solidification
Sand inclusion	Upper surface features	Mold erosion during pouring
Dimensional distortion	Thin-wall sections	Uneven cooling stresses

The solidification behavior can be modeled using Chvorinov’s rule:

$$ t = B \left( \frac{V}{A} \right)^n $$

Where:
$t$ = Solidification time
$V$ = Volume of casting section
$A$ = Surface area
$B,n$ = Material constants

2. Process Optimization Strategy

The modified casting process incorporated three key improvements:

Parameter	Original	Optimized
Riser design	2 rectangular risers	4 tapered elliptical risers
Chill placement	16mm flat chills	Curved conformal chills
Gating ratio	1:1.5:2	1:2:1.8

The feeding efficiency improvement was calculated using:

$$ \eta = \frac{V_f}{V_c} \times 100\% $$

Where:
$\eta$ = Feeding efficiency
$V_f$ = Feed metal volume
$V_c$ = Casting volume

3. Solidification Simulation and Verification

Numerical simulation using ProCAST software revealed critical improvements in thermal gradients:

$$ \nabla T = \frac{\partial T}{\partial x} + \frac{\partial T}{\partial y} + \frac{\partial T}{\partial z} $$

The Niyama criterion for shrinkage prediction was applied:

$$ Ny = \frac{G}{\sqrt{\dot{T}}} $$

Where:
$G$ = Temperature gradient
$\dot{T}$ = Cooling rate

4. Production Validation Results

Post-optimization inspection data demonstrated significant quality improvement:

Quality Parameter	Initial Process	Optimized Process
UT合格率	18.7%	96.2%
Dimensional accuracy	±2.5mm	±0.8mm
Yield rate	63%	89%

The success of this optimization demonstrates that systematic analysis of casting defect formation mechanisms combined with modern simulation tools can effectively resolve complex foundry quality challenges. Future work will focus on implementing machine learning algorithms for real-time process control, further reducing defect rates in high-precision cast components.