Creep testing is critical to understanding and preventing product failures. ÌìÃÀ´«Ã½ performs both stress rupture and creep testing for metals, composites, and plastics to determine the long-term stress on materials.

Stress rupture and creep testing are specialized mechanical testing methods that provide manufacturers with critical data about their product's performance over time. During testing, a material is held under a definite constant temperature for a given period of time, at up to 1200°C (2192 °F), until failure occurs. Our experts then analyze the results to provide essential data about physical and thermal stress over extended periods.

 

How is creep testing performed?

Creep testing is performed using a tensile specimen with a special design extensometer, applied constant stress, and temperature. The test is performed in furnaces or environmental chambers and recorded on a graph of strain versus time to show the creep rate

At a certain temperature and stress, materials begin to "creep," meaning they permanently deform. This can be observed in metals and alloys, ceramics, plastics, and even wood and stone. In metals, this process begins at about one-third of the melting temperature and increases at higher temperatures. Creep is caused by diffusion processes and dislocation movements in the material.

Creep is the time-dependent deformation of a material while under an applied load below its yield strength. It is most common at elevated temperatures, but some materials will exhibit creep at room temperature. Unless stopped, testing terminates in creep rupture.

 

What are the three stages of creep?

Creep occurs in three stages:

  • Primary creep (stage I) – Start of the test. The creep curve is rising, and the creep rate is high at the start of the test, slowly decreasing with time.
  • Secondary creep (stage II) – This is the stable part of the curve, where the creep rate is low and stable.
  • Tertiary creep (stage III) – This is the final creep stage, the creep rate is rising at the same rate as elongation, and there is a reduction of the sample area. This will soon result in a rupture of the specimen.

 

What is stress rupture?

Stress rupture is the sudden and complete failure of a material under stress. During testing, the sample is held at a specific load level and temperature for a pre-determined amount of time. In stress rupture testing, loads may be applied by tensile bending, flexural, biaxial, or hydrostatic methods.

 

Our stress rupture and creep test services

With accreditations including ISO and Nadcap, ÌìÃÀ´«Ã½ is committed to providing the highest quality stress rupture and creep testing services to clients across many sectors. Our stress rupture testing and creep testing laboratories are continuously growing to meet the needs created by new and advanced materials. 

 

Why choose ÌìÃÀ´«Ã½?

ÌìÃÀ´«Ã½ laboratories are also fully supported by experienced in-house machine shops that provide precise specimen preparation and fixture fabrication on all specimen and material types.

For more information about our stress rupture and creep test methods or to request a quote, contact an expert today

 

American Society for Testing and Materials

ASTM E139, ASTM E292, ASTM D1654, ASTM C1291, ASTM C1337, ASTM D7337, ASTM D2990, ASTM D3039, ASTM D7337, ASTM F519,

British Standards

BS EN 2002-5, BS ISO 8013, BS 4A4-1, BS EN ISO 204, BS EN ISO 899-1

International Standards Organization

ISO 903

Military Standards 

MIL-STD-1312

National Aerospace Standards

NASM 1312

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