Real-time monitoring of raster temperature distribution and width anomalies in fused filament fabrication process

The aim of this study is to monitor the raster temperature distribution and width anomalies in a fused filament fabrication(FFF)process by an infrared(IR)array sensor.To achieve this goal,two experiments were conducted on a desktop FFF machine.For the first experiment,three normal samples with different raster widths were fabricated,and thermal images of the newly deposited rasters were collected during the process.To process the low-resolution images,a segmentation-based image processing method was proposed.The temperature distributions along the horizontal direction of the raster section and along the raster length were obtained.The temperature features that could indicate the raster widths were extracted and then fed to recognition models for training and testing.The classification performance of the models were evaluated based on the F-score.The models with high F1-scores could be used to recognise width anomalies online.For the second experiment,an abnormal sample with raster width anomalies was fabricated.The temperature features were extracted from the collected experimental data.The obtained features were then fed to the built and evaluated models to recognise the width anomalies online.The effectiveness of the monitoring method was validated by comparing the recognition results with the actual optical images.The support vector machine(SVM)and k-nearest neighbour(KNN)were adopted to build the recognition models.The F1-score and online recognition results of the models were compared.The comparison study shows that SVM is more suitable for our situation than KNN.A method for monitoring the temperature distribution and width anomalies of the FFF raster is provided in this paper.To the best of the authors’knowledge,this is the first study to explore the actual temperature distribution along the horizontal direction of the raster section,and the first study to monitor the width anomalies of the raster in the FFF process.