Design for Creep

Penny, R. K.; Marriott, D. L.

doi:10.1007/978-94-011-0561-3

Cited by 160 publications

(141 citation statements)

References 0 publications

Supporting

Mentioning

131

Contrasting

Unclassified

Order By: Relevance

“…In a uniaxial creep test, damage occurs only in the tertiary creep region [35][36][37], while during a small punch creep test the material is subjected to damage in both the primary and secondary regions of the creep curve as well as in the tertiary region [20,24]. Damage can be described as the ratio between the damaged area and the initial area.…”

Section: Creep Damage Materials Modelmentioning

confidence: 99%

See 1 more Smart Citation

A study on the evolution of the contact angle of small punch creep test of ductile materials

Cacciapuoti

Sun

McCartney

2016

International Journal of Pressure Vessels and Piping

View full text Add to dashboard Cite

show abstract

Section: Creep Damage Materials Modelmentioning

confidence: 99%

“…Table 1 and Table 2 show, respectively, the chemical composition, in wt%, of the P91 steel used for the investigation in ref. [36] and the material constants of the P91 steel at 650 °C for the damage law [25].…”

Section: Tested Materials and Test Rigmentioning

confidence: 99%

A study on the evolution of the contact angle of small punch creep test of ductile materials

Cacciapuoti

Sun

McCartney

2016

International Journal of Pressure Vessels and Piping

View full text Add to dashboard Cite

show abstract

“…This model contains the total strain (α = 1) as well as the time hardening (α = 0) theories [5]. The simplest expression for the function λ(t) is λ(t) = e t g , and the common BaileyNorton function is obtained.…”

Section: Model and Fitting To The Experimental Resultsmentioning

confidence: 99%

Study of Time-Dependent Properties of Thermoplastics

Kolupaev

Bolchoun

Altenbach

2010

EPJ Web of Conferences

View full text Add to dashboard Cite

SummarySimple tests carried out with a common tension/compression testing machine are used to obtain timedependent properties of non-reinforced thermoplastics. These tests include ramp loadings as well as relaxation and creep tests. Two materials (PBT Celanex 2002-2 and POM Hostaform C9021, Ticona GmbH, Kelsterbach) were taken for the experiments. The experiments show that an adequate description of the long-term material properties can be obtained from the short-time tests, namely from tests with constant traverse speedL.Below a model for the time-dependent mechanical behavior is presented and fitted to the obtained measured data. For the evaluation of the fitting quality long-term tests are used. Especially creep and relaxation tests with "jumps", i.e. rapid change of loading, are important for this purpose. ExperimentsThe following experiments were carried out: ramp loading with constant stress rateσ = const and with constant traverse speedL = const, standard creep and relaxation tests as well as creep and relaxation tests with rapid change of loading ("jumps"). The ramp loading tests are short-time ones, the remaining tests are long-time. The deformations occurring during the tests are captured on a suitable element of the specimen's surface using the optical measuring system Vic-2D, Limess Messtechnik & Software GmbH, Pforzheim.The ramp loading tests are simple and with the settingL = const relatively stable. It is shown that these tests are sufficient to obtain the parameters of the Bailey-Norton functioṅthe elastic modulus E as well as the parameter α, which describes the material response to "jumps". The mentioned properties are required to fit the model to the measured data. If the material properties should be obtained from the long-time experiments, so the creep test only is not sufficient, and relaxation test is required (Fig. 1). The tests with "jumps" are essential in order to capture the material properties. A test with three "jumps" is used in order to control the quality of fitting. Since the strain is measured in both the longitudinal and the transverse directions, it is possible to compute the Poisson's ratio [2]. This can be used as an additional verification for the model.

show abstract

“…• C. Referring to [11] the damage evolution equation caused by low-cycle fatigue is introduced similarly to (2): …”

mentioning

confidence: 99%

“…• C. Referring to [11] the damage evolution equation caused by low-cycle fatigue is introduced similarly to (2): where the dependence for number of cycles to failure N * (∆ε, T ) describes the S-N diagrams; and ∆ε eff is an effective strain range, where the effective strain ε eff is defined as the maximum absolute value of principal strains multiplied by the algebraic sign of the dominant component within the one loading cycle in the following form:…”

mentioning

confidence: 99%

Creep‐fatigue analysis of the steel AISI type 316 component failure

Gorash

Altenbach

2011

Proc Appl Math and Mech

View full text Add to dashboard Cite

The purpose of this work is to extend a typical creep-damage model in order to describe material behavior under variable thermal and mechanical loading in wide stress range. The model basis is creep constitutive law in form of hyperbolic sine stress response function proposed by Nadai. The constitutive law is extended to assume the damage process under creep and fatigue by the introduction of scalar damage parameters and appropriate evolution equations according to Kachanov-Rabotnov concept. The material constants for model are identified by fitting the experimental creep and low-cycle fatigue data for the steel AISI type 316 at the range of temperatures 500• C -750• C. The development of such model is motivated by the well described failure case study of high-temperature components at unit 1 of Eddystone power plant, which have operated during 130520 hours under creep-fatigue interaction conditions. The main steam piping (MSP) from this power plant is selected for thermo-mechanical creep-fatigue analysis applying the proposed material model. The estimated values of damage parameters comply with the real location of the component failure and a scatter of experimental data on creep-fatigue interaction diagram. Although high-temperature components of such engineering structures as boilers, turbines and chemical facilities are designed to resist creep, thermal-fatigue, corrosion and environmental-degradation processes, the failures are regularly documented in literature sources devoted to engineering failure analysis. One of the common reasons for happened failure cases is an imperfection of available material models employed in design procedures for high-temperature components. The reported failure case study [1] of the steel AISI type 316 components at unit 1 of Eddystone power plant, which have totaly operated during 130520 hours, indicated, that their failure had been caused by the damage accumulated under variable thermomechanical loading conditions inducing complex interaction of different processes. Therefore, the material model assuming not only irreversible creep strains, but also significant plastic strains caused by high thermal stresses, which simultaneously result in low-cycle fatigue, have to be employed for thermo-mechanical creep-fatigue analysis of these components. The main steam piping (MSP) from this power plant is selected for numerical FE-analysis in CAE-software ABAQUS, as illustrated in Fig. 1, in order to obtain a correct life-time prediction confirming the applicability of the proposed material model.All basic thermal and mechanical properties of the steel AISI type 316 show significant temperature dependence [2]. Plastic deformations are described by isotropic hardening model using experimental true stress-strain curves [3] also at different temperatures derived under 4 · 10 −5 (1/s) strain rate. And the creep behavior is characterized by the following constitutive equation based on hyperbolic sine stress response function proposed by Nadai and extended with Arrhenius-type functions:where...

show abstract

Design for Creep

Cited by 160 publications

References 0 publications

A study on the evolution of the contact angle of small punch creep test of ductile materials

A study on the evolution of the contact angle of small punch creep test of ductile materials

Study of Time-Dependent Properties of Thermoplastics

Creep‐fatigue analysis of the steel AISI type 316 component failure

Contact Info

Product

Resources

About