Abstract
This study presents a parameter selection strategy developed for the Stretch-Blow Molding (SBM) process to minimize the weight of preforms used. The method is based on a predictive model developed using Neural Networks. The temperature distribution model of the preform was predicted using a 3-layer NN model with supervised backpropagation learning. In addition, the model was used to predict the uniform air pressure applied inside the preform, taking into account the relationship between the internal air pressure and the volume of the preform. Parameters were validated using in situ tests and measurements performed on several weights and lengths of a 0.330 Liter Polyethylene Terephthalate (PET) bottles. Tests showed that the model adequately predicts both the blowing kinematics, mainly zone temperatures and blowing and stretching pressures along the walls of the bottle while maintaining the bottle strength and top load requirements. In the second step, the model was combined to automatically compute the lowest preform weight that can be used for a particular 330 ml bottle design providing a uniform wall thickness distribution.
Highlights
The two-stage Stretch-Blow Molding (SBM) process is the most popular technique used for the manufacturing of Polyethylene Terephthalate (PET) bottles [1]
This study presents a parameter selection strategy developed for the Stretch-Blow Molding (SBM) process to minimize the weight of preforms used
We present Neural Networks (NN) approach to achieve a predictive model of the SBM process
Summary
The two-stage Stretch-Blow Molding (SBM) process is the most popular technique used for the manufacturing of Polyethylene Terephthalate (PET) bottles [1]. The method was based on a coupling between the Nelder-Mead optimization algorithm and Finite Element (FE) simulations of the forming process developed and the temperature distribution of the perform was predicted using a 3D finite-volume software. Even though kinematics of blowing may be the criteria to test the accuracy of results, a lack of heat transfer modeling is apparent due to high non-linearity and the temperature distribution zones through the preform wall thickness. Throughout the testing and simulation of neural network parameters, Swing Neural Networks [17] was used on a set of real-time data This method provides a predictive approach for the relationship between the internal temperature and air pressure and the enclosed parameters of the preform. Results were validated by careful in situ tests and measurements performed on various weights preforms of 330 ml PET bottles
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