About this Abstract |
Meeting |
2025 TMS Annual Meeting & Exhibition
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Symposium
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Mechanical Response of Materials Investigated Through Novel In-Situ Experiments and Modeling
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Presentation Title |
High Temperature Profilometry-based Indentation Plastometry (HT-PIP) – Influence of Creep on Experimental Outcomes |
Author(s) |
James Rees Miller, Philip John McKeown, Chizhou Fang, Bill Clyne |
On-Site Speaker (Planned) |
James Rees Miller |
Abstract Scope |
Profilometry-based Indentation Plastometry (PIP) gives stress-strain curves via automated indentation. The machine comprises loading frame, profilometer and control software (implementing iterative FEM simulation of the test). This paper concerns use of a heating stage (plus software controlling thermal conditions) with an 800˚C capability. For some metals, there is good agreement between stress-strain curves from PIP and from tensile testing, with neither affected by test timescale. However, for others (particularly at higher temperatures), creep affects outcomes, so stress-strain curves from both tests depend on timescale - with neither giving a genuine (‘purely plastic’) relationship. Furthermore, the two tests are affected differently, so there is no reliable agreement between the two curves. This has been investigated for several alloys and a procedure devised that reveals (during a standard PIP test) whether the case (material and temperature) concerned is one for which creep is significantly affecting the outcome. |
Proceedings Inclusion? |
Planned: |
Keywords |
Mechanical Properties, High-Temperature Materials, Characterization |