Contactless Material Tensile Testing Using a High-Resolution Camera

Bulava, Jaroslav; Hargaš, Libor; Koniar, Dušan

doi:10.3390/computation10070121

Computation

2022

DOI: 10.3390/computation10070121

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Contactless Material Tensile Testing Using a High-Resolution Camera

Jaroslav Bulava

Libor Hargaš

Dušan Koniar

Abstract: This article deals with the use of contactless measurement with a high-resolution imaging device during tensile testing of materials in a universal tearing machine (UTM). Setting the material parameters in tensile testing is based on changes in the geometrical properties of the sample being tested. In this article, authors propose the method and system for automated measuring the height, width, and crack occurrence during tensile testing. The system is also able to predict the location of crack occurrence. The… Show more

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2024

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Tensile Specimen Circular Grid Pattern and AI-Based Strain Calculation Method

Yi,

Hyun,

Hong

2024

Applied Sciences

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During tensile testing of materials, strain measurement is conducted using either contact or non-contact methods. Contact methods offer high accuracy and precision but are limited by the specimen’s thickness and dimensions, whereas non-contact methods minimize damage to thin specimens and allow measurements in various environments, though they require longer preparation and calculation times. This paper proposes a circular grid marking pattern and a strain prediction algorithm using artificial intelligence (AI), which simplifies the preparation process and allows strain prediction without additional equipment. The circular grid pattern can be arranged in various configurations from 1 × 5 to 5 × 7, and a laser marker, which requires minimal time, was used to engrave the pattern on the specimen to shorten the preparation time. The AI model, trained on image-based data, enables strain calculation regardless of the specimen’s gauge length and size, and allows measurement of local strain as well as gauge-length strain. The reliability of this concept was verified by applying it to tensile testing.

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Tensile Specimen Circular Grid Pattern and AI-Based Strain Calculation Method

Yi,

Hyun,

Hong

2024

Applied Sciences

View full text Add to dashboard Cite

show abstract

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Contactless Material Tensile Testing Using a High-Resolution Camera

Cited by 1 publication

References 24 publications

Tensile Specimen Circular Grid Pattern and AI-Based Strain Calculation Method

Tensile Specimen Circular Grid Pattern and AI-Based Strain Calculation Method

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