Hogar » Límite elástico

Límite elástico

1860

Yield strength, or the yield point, is the stress at which a material begins to deform plastically. Prior to the yield point, the material deforms elastically and will return to its original shape when the applied stress is removed. Once the yield point is passed, some fraction of the deformation will be permanent and non-reversible. It marks the limit of elastic behavior.

The transition from elastic to plastic behavior is a critical design consideration. For materials with a clear, sharp yield point (like low-carbon steel), it’s easily identified on the stress-strain curve as a distinct peak (upper yield point) followed by a drop to a lower, constant stress plateau (lower yield point). However, many materials, such as aluminum alloys, exhibit a gradual transition. For these, a proof stress or offset yield point is defined. This is commonly determined by the 0.2% offset método, where a line parallel to the initial elastic portion of the curve is drawn from a strain value of 0.002 (or 0.2%). The stress at which this line intersects the stress-strain curve is defined as the 0.2% proof yield strength. This value represents the stress that would cause a permanent, non-recoverable strain of 0.2% upon unloading. The yield strength is a fundamental parameter used to determine the maximum allowable load a mechanical component can bear before it is considered to have failed, as permanent deformation can render a part unusable even if it has not fractured.

Aleaciones, Diseño para la fabricación (DfM), Fijaciones, Ciencia de los materiales, Ingeniería Mecánica, Propiedades mecánicas, Metales, Ingeniería estructural, Tensile Testing

UNESCO Nomenclature: 3313

– Materials science

Tipo

Physical Property

Disrupción

Fundacional

Utilización

Uso generalizado

Precursores

understanding of elastic vs. plastic behavior in metals
development of accurate extensometers to measure small deformations
industrial need for predictable material performance under load
theories of dislocation motion in crystalline solids

Aplicaciones

structural design of buildings and bridges to prevent permanent deformation
automotive crashworthiness design (energy absorption through plastic deformation)
design of fasteners and bolts
Procesos de conformado de metales como laminación, forja y extrusión
setting pressure limits for pipes and pressure vessels

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Related to: yield strength, yield point, plastic deformation, elastic limit, stress-strain curve, proof stress, 0.2% offset, material science, mechanical design, permanent set.

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