Evaluation of the Thermal Behaviour of Injection Moulds

The use of specific softwares was the basis for a new approach for teaching ordinary and partial differential equations, in the field of heat transfer and fluid mechanics. The main objective was to enhance learning effectiveness of Numerical Methods in the post-graduate course of Polymers Engineering at the University of Minho. This degree takes place into two different environments: at the university campus and at the industrial field. Different commercial codes were used, namely EXCEL, MATLAB, and FLUENT, as well as two tools developed in house at University of Minho: CoNum and a graphics application PDE v.1. Lectures were based on videoconferencing and other web utilities. The teaching methodology presented and discussed in this article was well received and accepted by the post-graduate students, motivating teachers to improve their teaching/ learning strategies.

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Teaching differential equations in different environments: A first approach

Carneiro

Leão

Teixeira

2010

Comp Applic In Engineering

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Spectral refinement for clustered eigenvalues of quasi-diagonal matrices

Ahués¹,

d'Almeida

Largillier³

et al. 2006

Linear Algebra and its Applications

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Estimation of Bulk Melt-Temperature from In-Mold Thermal Sensors for Injection Molding, Part A: Method

Johnston

Mendible

Gao

et al. 2015

International Polymer Processing

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To improve part quality and consistency injection molders strive to control the temperature of the molten plastic during cavity filling. In-mold temperature sensors can effectively measure the temperature of the mold surface that contacts the melt; however, they do not provide a measure of the bulk melt temperature. An analysis was developed to use data from in-mold thermocouples to predict the plastic's bulk melt temperature. This analysis integrates the heat flux through the mold steel to calculate the bulk melt temperature. A mold instrumented with an in-mold thermocouple and an IR temperature sensor was used to validate the predictions. The effects of changing barrel temperature, coolant temperature, injection velocity, and cooling time were studied using a 21 run DOE. Validation was performed by comparing bulk temperature data from the IR temperature sensor with temperature predictions derived from the in-mold temperature sensor. Trends in the melt temperature were consistently predicted, however, the magnitudes were low due to residual heat remaining in the part at the end of the molding cycle. The analysis was more sensitive to process changes than raw data from the in-mold temperature sensor, thereby improving process observability.

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Evaluation of the Thermal Behaviour of Injection Moulds

Cited by 3 publications

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Teaching differential equations in different environments: A first approach

Teaching differential equations in different environments: A first approach

Spectral refinement for clustered eigenvalues of quasi-diagonal matrices

Estimation of Bulk Melt-Temperature from In-Mold Thermal Sensors for Injection Molding, Part A: Method

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