Optimization of Temperature Regimes of the Hotend for Devices of Additive Manufacturing

Andrey Y. Sinev; Roman A. Panasenko; Valeria V. Petrenko; Aleksandr Vasilievich Berestov; Yuri V. Bozhko

doi:10.4028/www.scientific.net/MSF.1037.41

Paper Titles

Modeling and Optimization of Additive Systems Based on Intelligent Technologies
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Influence of Surfacing Modes on the Formation of Pores in the Deposited Metal Produced by Wire Arc Additive Method (WAAM) Using Al-Mg Alloy
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Mortar for 3D Printing Based on Gypsum Binders
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Measurement Assurance of Additive Manufacturing on the Example of Laser Surface Polishing Products by Remelting
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Optimization of Temperature Regimes of the Hotend for Devices of Additive Manufacturing
p.41

Stress Simulation of the Structure of a Stretch Die Made by Fused Deposition Modeling
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Experimental Investigation of Nozzle Clogging Using Vibration Signal-Based Condition Monitoring for Fused Deposition Modeling
p.55

Cold Resistance and Mechanical Properties of 07Cr25Ni13 (ER309LSI) Stainless Steel Obtained by 3D Printing by Electric Arc Surfacing on a CNC Machine
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Investigation of the Peculiarities of Deformation and Fracture of Metals Obtained on the Basis of 3D Printing with Registration of an Acoustic Emission Signal
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HomeMaterials Science ForumMaterials Science Forum Vol. 1037Optimization of Temperature Regimes of the Hotend...

Optimization of Temperature Regimes of the Hotend for Devices of Additive Manufacturing

Abstract:

In this work, the authors tried to solve a typical problem of inexpensive 3D printers using FDM technology: material clogging of the hotend. To cope with the problem, it is necessary to solve the problem of optimization the temperature regimes of the hotend. For this, the temperature fields of the heating device were simulated taking into account the physical properties of the printing materials. Modeling was carried out using the ANSYS software package, the verification of theoretical calculations was carried out in a full-scale experiment. The data obtained was used to upgrade the 3D printer hotend.

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Periodical:

Materials Science Forum (Volume 1037)

Pages:

41-46

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.1037.41

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Online since:

July 2021

Authors:

Andrey Y. Sinev, Roman A. Panasenko*, Valeria V. Petrenko, Aleksandr Vasilievich Berestov, Yuri V. Bozhko

Keywords:

3D-printer, Extruder, Feed Mechanism, Heating Element, Hotend, Nozzle, Print Head, Thermal Barrier, Thermal Insulator, Thermistor

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