Optimization Analysis of Correction Tape Box Compounding Cavity Runner Balance Based on Moldflow

Aiming at the problem of runner unbalance in the compounding cavity of the upper and lower cover of the correction tape box, the plastic injection analysis software Moldflow was used to optimize runner balance. First, the 3D modeling software Proe was used to establish the geometric model of the upper and lower cover of the correction tape box, and introduced into the plastic injection analysis software Moldflow. Secondly, the upper and the lower cover of the correction tape box were meshed and the initial gating system was designed in Moldflow. Filling analysis of the initial scheme of the correction tape box combined cavity showed that the runner of the melt was not balanced in the mold cavity. Finally, the runner balance optimization analysis of the cavities was carried out. Through optimization, the time unbalance rate of the melt in the mold cavity decreased from 28.6% to 0.7%, the pressure unbalance rate decreased from 42.0% to 4.2%, and the pressure distribution in the cavity was more uniform in the whole injection process.

World Journal of Engineering and Technology ity, but also ensure the consistency of product quality in different cavity [1] [2].
The traditional design method is to achieve runner balance by constantly manually modifying the size of the gating system. This method not only takes time, but also improves the production cost. With the development of CAE technology, the experiment of the mold can be replaced by Moldflow simulation software and the efficiency can be improved [3] [4].
In this paper, the runner balance design of the correction tape box compounding cavity is analyzed by Moldflow. In the original model of the correction tape box compounding cavity, the time unbalance rate of the melt in the mold cavity is about 28.6% and the pressure unbalance ratio is about 42.0%. The original runner system is not balanced. The runner system is optimized through the filling analysis module and flow runner balance module of Moldflow. After optimization, the flow unbalance ratio changes from 28.6% to 0.7%. The optimized runner system is balanced.

The Geometric and Mesh Model of the Correction Tape Box
The geometric model of the upper cover of the correction tape box is shown in Figure 1. The geometric model of the lower cover of the correction tape box is shown in Figure 2.
The models are then imported to Moldflow software by STL format. The meshed models of the upper and lower of the correction tape box are shown in Figure 3 and Figure 4. The plastic material used for the products is GE Plastics (Europe) ABS. The thicknesses of the upper and lower of the correction tape box are 1.5 mm. The dimensions of the upper and lower covers of the correction tape box are all 125 mm × 60 mm × 1.5 mm. There are three mesh types in Moldflow including Midplane, 3D and Fusion. Because of the thicknesses of the products, the Fusion mesh is adopted.
The mesh statistical chart of the upper and lower cover is shown in Table 1.
The mesh models of the upper and lower covers satisfy the demand of the runner balance analysis in Moldflow.

Best Gate Location Analysis of the Correction Tape Box
The shape of the upper and lower cover of the correction tape box is different, and the compounding cavity is asymmetric. Therefore, before designing the layout of the compounding cavity, it is necessary to use the best gate location analysis to find the best gate position of the upper and lower cover, and to     ensure the reasonable flow of melt in the single cavity, so as to provide a basis for further design of the compounding cavity. The best gate location of the upper cover is shown in Figure 5 and the best gate location of the lower cover is shown in Figure 6. World Journal of Engineering and Technology

Initial Fill Analysis of the Compounding Cavity
The   is about 14.1% and result in the pressure distribution unbalance in the two cavities. This would influence the quality of the product. Pressure at V/P switchover is shown in Figure 9. The pressure at V/P switchover of the injection location is 73.17 MPa. From Figure 9 the lower is filled fully early and the pressure in the cavity is very high (the end pressure also attains 44.73 MPa). This condition results in over laden pack and influence the quality of the product.
Through the filling analysis of the initial design scheme of the compounding cavity of the upper and lower cover, it can be seen that the flow channel of the melt is unbalanced in the die cavity, and the time unbalance rate is 28.6%.
Under the influence of the flow unbalance, the pressure difference between the upper and lower cover is quite large, and the pressure unbalance is 42.0%. Next, the runner balance analysis of the compounding cavity is carried out to reduce the time and pressure unbalance rate.

The Runner Balance Analysis of the Compounding Cavity
By optimizing the compounding cavity, the time and pressure imbalance of melt flow in the cavity can be improved, the pressure difference between the upper and lower cavity can be reduced, and the product quality can be improved.
Iterative calculation parameters and convergence target settings are shown in Table 2. When setting iteration parameters, they can be adjusted by iterative calculation to obtain ideal parameters. World Journal of Engineering and Technology  After 13 iterations, the objective value converges, the convergence process of time imbalance rate is shown in Figure 10, and the pressure imbalance rate is shown in Figure 11. From Figure 10, it can be seen that the time and pressure imbalance rate have been significantly improved by optimizing the calculation. The time imbalance rate has been reduced from 28.6% to 0.7%, and the pressure imbalance rate has been reduced from 42.0% to 4.2%.
The size change of the optimized combined cavity runner is shown in Figure  12. As can be seen from Figure 12, the diameter of the diversion channel connecting the upper cover is almost unchanged, and the diameter of the diversion channel connecting the lower cover is reduced by 95.16%. The diameter of the diversion channel connecting the lower cove is changed from 5 mm to 0.25 mm.
From the runner balance analysis results, the runner balance optimization has achieved good results.

Conclusions
Aiming at the imbalance of flow in the compounding cavity of the upper and lower cover of correction tape box, Pro/e and Moldflow software were used to optimize the runner balance. Through optimization calculation, the time imbalance rate in the flow passage of the mould cavity decreased from 28.6% to 0.7%, and the pressure imbalance rate decreased from 42.0% to 4.2%. The pressure distribution in the cavity during the whole injection process was relatively uniform, and the optimization achieved very good results. World Journal of Engineering and Technology   The research shows that the injection mold with compounding cavity can realize the melt flow balance by runner balance optimization, which can effectively improve the molding quality of the products and improve the production efficiency. The results provide a useful reference for researchers engaged in die design.