This paper shows some preliminary results of non-destructive tests performed by means of lock-in thermography on 3D printed items embedding optical fibres. The intention is to verify if lock-in thermography can be a valid means to identify the path of optical fibres which are buried inside a material and that cannot be identified with the naked eye. To this end feasibility tests have been carried out on some PLA samples manufactured by using the fused deposition modelling technique and by varying some key parameters.
Lock-In Thermography to Visualize Optical Fibres Buried Inside 3D Printed PLA Items / Boccardi, S.; del Core, G.; di Palma, P.; Iadicicco, A.; Campopiano, S.; Meola, C.. - 753:(2021), pp. 31-37. (Intervento presentato al convegno AISEM Regional Workshop on Sensors and Microsystems, AISEM 2020 tenutosi a ita nel 2020) [10.1007/978-3-030-69551-4_5].
Lock-In Thermography to Visualize Optical Fibres Buried Inside 3D Printed PLA Items
Boccardi S.;del Core G.;di Palma P.;Iadicicco A.;Campopiano S.;
2021
Abstract
This paper shows some preliminary results of non-destructive tests performed by means of lock-in thermography on 3D printed items embedding optical fibres. The intention is to verify if lock-in thermography can be a valid means to identify the path of optical fibres which are buried inside a material and that cannot be identified with the naked eye. To this end feasibility tests have been carried out on some PLA samples manufactured by using the fused deposition modelling technique and by varying some key parameters.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
