Your search keyword '"Menesklou, Philipp"' showing total 5 results

1. Further developments of a dynamic real-time model of a tubular centrifuge fed with multi-component dispersions for application in fractionation for Direct Recycling of lithium-ion batteries

Author

Sinn, Tabea, Menesklou, Philipp, Nirschl, Hermann, and Gleiss, Marco

Published

2023

2. Dewatering of finely dispersed calcium carbonate-water slurries in decanter centrifuges: About modelling of a dynamic simulation tool

Author

Menesklou, Philipp, Nirschl, Hermann, and Gleiss, Marco

Published

2020

3. Autonomous Processes in Particle Technology.

Author

Nirschl, Hermann, Winkler, Marvin, Sinn, Tabea, and Menesklou, Philipp

Subjects

ENERGY consumption, SOLAR cells, RAW materials, PRODUCT quality, MACHINE learning

Abstract

Battery materials, pharmaceuticals, solar cells, coffee powder, 3D printed components, etc., all these products have in common that they are predominantly made of particles. Ensuring high product quality with optimal raw material and energy utilization is only possible with extensive and many years of experience in the operation of such processes. This unsatisfactory situation is due to the complexity of particulate products, which still hinders extensive automation and autonomous process control. The challenge is to couple the respective basic operations with characterization devices, process dynamics and modern control algorithms to form a closed loop for process control. As a result, some day it should be possible to set the desired property profiles of particulate products with the most energy‐ and raw material‐efficient operation possible with a "push of a button". [ABSTRACT FROM AUTHOR]

Published

2022

4. Grey Box Modelling of Decanter Centrifuges by Coupling a Numerical Process Model with a Neural Network.

Author

Menesklou, Philipp, Sinn, Tabea, Nirschl, Hermann, and Gleiss, Marco

Subjects

*ARTIFICIAL neural networks, *CENTRIFUGES, *DECANTERS, *SEDIMENT transport, *MECHANICAL models

Abstract

Continuously operating decanter centrifuges are often applied for solid-liquid separation in the chemical and mining industries. Simulation tools can assist in the configuration and optimisation of separation processes by, e.g., controlling the quality characteristics of the product. Increasing computation power has led to a renewed interest in hybrid models (subsequently named grey box model), which combine parametric and non-paramteric models. In this article, a grey box model for the simulation of the mechanical dewatering of a finely dispersed product in decanter centrifuges is discussed. Here, the grey box model consists of a mechanistic model (as white box model) presented in a previous research article and a neural network (as black box model). Experimentally determined data is used to train the neural network in the area of application. The mechanistic approach considers the settling behaviour, the sediment consolidation, and the sediment transport. In conclusion, the settings of the neural network and the results of the grey box model and white box model are compared and discussed. Now, the overall grey box model is able to increase the accuracy of the simulation and physical effects that are not modelled yet are integrated by training of a neural network using experimental data. [ABSTRACT FROM AUTHOR]

Published

2021

5. Scale-Up of Decanter Centrifuges for the Particle Separation and Mechanical Dewatering in the Minerals Processing Industry by Means of a Numerical Process Model.

Author

Menesklou, Philipp, Sinn, Tabea, Nirschl, Hermann, Gleiss, Marco, Cisternas, Luis A., and Lucay, Freddy A.

Subjects

*CENTRIFUGES, *MINERAL processing, *DECANTERS, *MINERAL industries, *MANUFACTURING processes

Abstract

Decanter centrifuges are frequently used for thickening, dewatering, classification, or degritting in the mining industry and various other sectors. Their use in an industrial process chain requires a sufficiently accurate prediction of the product and the machine behaviour. For this purpose, experiments on a smaller pilot-scale are carried out for scale-up of a decanter centrifuge, which is usually a major challenge. Predicting the process behaviour of decanter centrifuges from laboratory tests is rather difficult. Basically, there are two common ways of scale-up: First, via analytical methods and the law of similarity, which often requires an enormous experimental effort. Second, using numerical models, which demands a mathematically and physically precise description of the multiple processes running simultaneously in such machines. This article provides an overview of both methods for scale-up of a decanter centrifuge. The concept of a previous developed numerical approach is introduced. Pros and cons of both scale-up methods are compared and further discussed. Experiments on lab-scale, pilot-scale, and industrial-scale decanter centrifuges with two different finely dispersed calcium carbonate water suspensions were carried out and simulations were done to investigate and prove the scale-up capability and transferability of the numerical approach. [ABSTRACT FROM AUTHOR]

Published

2021