Nan-yang Zhao scite author profile

The quality control of plastic products is an essential aspect of the plastic injection molding (PIM) process. However, the warpage and shrinkage deformations continue to exist because the PIM process is easily interfered with by several related or independent process parameters. Thus, great efforts have been devoted to optimizing process parameters to minimize the warpage and shrinkage deformations of products during the last decades. In this review, we begin by introducing the manufacturing process in PIM and the cause of warpage and shrinkage deformations, followed by the mechanism about how process parameters, like mold temperature, melt temperature, injection rate, injection pressure, holding pressure, holding and cooling duration, affect those defects. Then, we summarize the recent progress of the design of experiments and four advanced methods (artificial neural networks, genetic algorithm, response surface methodology, and Kriging model) on optimizing process parameters to minimize the warpage and shrinkage deformations. In the end, future perspectives of quality control in injection molding machines are discussed.

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The constant/variable kinematics adjustment of the crosshead and the mold’s stability management in injection molding

Zhao

Shan

et al. 2023

Int J Adv Manuf Technol

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During the clamping process in an injection-molding machine, the mold's movement is directly driven by the velocity of the crosshead. The form of the adjustment on the crosshead's kinematics can influence the final dynamics of the mold, which can contribute to the stability of the clamping duration further. This article is aimed at investigating the kinematics analysis and the stability management strategy of the mold in the early design stage for the clamping mechanism. The two different velocity-controlled forms of the crosshead, constant and variable kinematics adjustments, are applied and compared in the clamping analysis. Three factors of the crosshead, the maximum velocity, the acceleration/deceleration stage adjustment, and the multi acceleration/deceleration process, are validated for the stability control of the mold's motion in the injection molding process. The results show Article Title an extra "fast" process is detected in the constant condition when compared to the variable crosshead's kinematics adjustment. Furthermore, by the reasonable adjustment of the maximum velocity and two special positions of the crosshead during the acceleration and deceleration stages, the maximum acceleration fluctuation of the mold is decreased by more than 50%, allowing the mold to move more steadily.

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Mold Cooling System Design and Analysis of M-Type Hot Forming Parts

Li¹,

Sun²,

Zhao³

et al. 2016

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Nan-yang Zhao

Recent progress in minimizing the warpage and shrinkage deformations by the optimization of process parameters in plastic injection molding: a review

The constant/variable kinematics adjustment of the crosshead and the mold’s stability management in injection molding

Mold Cooling System Design and Analysis of M-Type Hot Forming Parts

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