A Novel Flow Model of Strain Hardening and Softening for Use in Tensile Testing of a Cylindrical Specimen at Room Temperature

We develop a new flow model based on the Swift method, which is both versatile and accurate when used to describe flow stress in terms of strain hardening and damage softening. A practical issue associated with flow stress at room temperature is discussed in terms of tensile testing of a cylindrical specimen; we deal with both material identification and finite element predictions. The flow model has four major components, namely the stress before, at, and after the necking point and around fracture point. The Swift model has the drawback that not all major points of stress can be covered simultaneously. A term of strain to the third or fourth power (the “second strain hardening exponent”), multiplied and thus controlled by a second strain hardening parameter, can be neglected at small strains. Any effect of the second strain hardening exponent on the identification of the necking point is thus negligible. We use this term to enhance the flexibility and accuracy of our new flow model, which naturally couples flow stress with damage using the same hardening constant as a function of damage. The hardening constant becomes negative when damage exceeds a critical value that causes a drastic drop in flow stress.

Download Full-text

Deformation of an extruded nickel beryllide between room temperature and 820 °C

Journal of Materials Research ◽

10.1557/jmr.1991.2653 ◽

1991 ◽

Vol 6 (12) ◽

pp. 2653-2659 ◽

Cited By ~ 2

Author(s):

G.M. Pharr ◽

S.V. Courington ◽

J. Wadsworth ◽

T.G. Nieh

Keyword(s):

Mechanical Properties ◽

High Temperature ◽

Elevated Temperature ◽

Flow Stress ◽

Strain Hardening ◽

Room Temperature ◽

High Temperature Strength ◽

Compression Tests ◽

Tension And Compression ◽

Better Than

The mechanical properties of nickel beryllide, NiBe, have been investigated in the temperature range 20–820 °C. The room temperature properties were studied using tension, bending, and compression tests, while the elevated temperature properties were characterized in compression only. NiBe exhibits some ductility at room temperature; the strains to failure in tension and compression are 1.3% and 13%, respectively. Fracture is controlled primarily by the cohesive strength of grain boundaries. At high temperatures, NiBe is readily deformable—strains in excess of 30% can be achieved at temperatures as low as 400 °C. Strain hardening rates are high, and the flow stress decreases monotonically with temperature. The high temperature strength of NiBe is as good or better than that of NiAl, but not quite as good as CoAl.

Download Full-text

Study on Compression Behaviour of AZ31 Magnesium Alloy at Room-Temperature

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.476-478.1960 ◽

2012 ◽

Vol 476-478 ◽

pp. 1960-1964

Author(s):

Jia Le Sun ◽

Rui Chun Li ◽

Gao Feng Quan ◽

Zhao Ming Liu

Keyword(s):

Magnesium Alloy ◽

Strain Hardening ◽

Room Temperature ◽

Deformation Behaviour ◽

Az31 Alloy ◽

Strain Hardening Exponent ◽

Surface Cracks ◽

Compression Properties ◽

Compression Behaviour ◽

Az31 Mg Alloy

The microstructure, surface morphology, compression properties, deformation behaviour and strain hardening exponent of as-cast and as-extruded AZ31 Mg alloy after different annealing treatments were investigated. The results show that the compression properties are great different between cast AZ31 alloy and extruded AZ31 alloy. Extruded AZ31 alloy is discontinuous yield and on the surface no signs of damage have been observed; on the contrast, cast AZ31 alloy is continuous yield and shows wavy patterns, and the surface cracks can be easily found. In addition, there is a linear relationship between the strain hardening exponent in first deformation stage and the yield ratio. Further more, the twinning mechanism plays very different role in cast AZ31 alloy and extruded AZ31 alloy.

Download Full-text

Cryogenic Material Properties of Polycaprolactone

Volume 3: Biomedical and Biotechnology Engineering ◽

10.1115/imece2019-10180 ◽

2019 ◽

Author(s):

Amrit Sagar ◽

Christopher Nehme ◽

Anil Saigal ◽

Thomas P. James

Keyword(s):

Yield Strength ◽

Strain Hardening ◽

Liquid Nitrogen ◽

Material Properties ◽

Room Temperature ◽

Strain Hardening Exponent ◽

Strength Coefficient ◽

Finite Element Software ◽

Aspect Ratios ◽

Deform 3D

Abstract In pursuit of research to create a synthetic tissue scaffold by a micropunching process, material properties of Polycaprolactone (PCL) in liquid nitrogen were determined experimentally. Specimens were prepared using injection molding and tested under compression to determine the stress-strain relationship of PCL below its glass transition temperature. Cryogenic conditions were maintained by keeping the PCL specimens submerged in liquid nitrogen throughout the loading cycle. Specimens of two different aspect ratios were used for testing. Yield Strength, Strength Coefficient, and Strain Hardening Exponent were determined for different specimen aspect ratios and extrapolated for the case with zero diameter to length ratio. Material properties were also determined at room temperature and compared against results available in the literature. Results demonstrate that PCL behaves in a brittle manner at cryogenic temperatures with more than ten times increase in Young’s modulus from its value at room temperature. The results were used to predict punching forces for the design of microscale hole punching dies and for validation of a microscale hole punching model that was created with a commercially available finite element software package, DEFORM 3D. The three parameters Yield Strength, Strength Coefficient, and Strain Hardening Exponent used in Ludwik’s equation to model flow stress of PCL in DEFORM 3D were determined to be 94.8 MPa, 210 MPa, and 0.54, respectively.

Download Full-text

Effect of tempering temperature on strain hardening exponent and flow stress curve of 1000 MPa grade steel for construction machinery

Journal of Iron and Steel Research International ◽

10.1016/s1006-706x(17)30138-3 ◽

2017 ◽

Vol 24 (9) ◽

pp. 950-956 ◽

Cited By ~ 2

Author(s):

Yang Yun ◽

Qing-wu Cai ◽

Bao-sheng Xie ◽

Shuang Li

Keyword(s):

Flow Stress ◽

Strain Hardening ◽

Strain Hardening Exponent ◽

Tempering Temperature ◽

Construction Machinery ◽

Stress Curve ◽

Flow Stress Curve ◽

Grade Steel

Download Full-text

Deformation behavior of Austenitic stainless steel at subzero temperature

E3S Web of Conferences ◽

10.1051/e3sconf/202130901215 ◽

2021 ◽

Vol 309 ◽

pp. 01215

Author(s):

M. Krishnamraju ◽

Abhishek Kumar ◽

Sushil Mishra ◽

K Narasimhan

Keyword(s):

Mechanical Properties ◽

Tensile Strength ◽

Stainless Steel ◽

Austenitic Stainless Steel ◽

Strain Hardening ◽

Room Temperature ◽

High Strength ◽

Tensile Tests ◽

Subzero Temperature ◽

Strain Hardening Exponent

Austenitic stainless steel is one of the second generation advanced high strength steel which finds application in automobile, aerospace and cryogenic components. The component made of austenitic steel might operate in subzero temperature condition because of its excellent formability even at subzero temperature. In the present work several tensile tests were performed on austenitic stainless-steel sheet of thickness 1.2 mm at 0°C, -40°C, -80°C, -120°C and at different strain rates of 0.01/sec,0.001/sec,0.0001/sec. The resultant mechanical properties, like yield strength, tensile strength, elongation percent and strain hardening exponent, along with phase fractions and microstructural properties were analyzed to understand the reasons for change in mechanical properties, on comparing with room temperature properties. It was noticed that tensile strength is 635 Mpa, & strain hardening exponent is 0.38 at room temperature (25 °C) and tensile strength is 1236 Mpa, & strain hardening exponent is O.49 at -120°C. Similarly, XRD characterization revealed that strain induced martensite increased from zero percent at 25°C (room temperature) to 57 percent at-120°C Similarly EBSD characterization revealed that grain average misorientation which also increased from room temperature to-120°C.

Download Full-text

Dislocation structures around SiO2 Particles in aged Cu-Cr-SiO2

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100110118 ◽

1978 ◽

Vol 36 (1) ◽

pp. 594-595

Author(s):

N.J. Long ◽

M.H. Loretto ◽

C.H. Lloyd

Keyword(s):

Flow Stress ◽

Single Crystals ◽

Room Temperature ◽

Thin Foil ◽

Age Hardening ◽

Dispersion Strengthening ◽

Accurate Picture ◽

The Matrix ◽

Very High ◽

Good Agreement

IntroductionThere have been several t.e.m. studies (1,2,3,4) of the dislocation arrangements in the matrix and around the particles in dispersion strengthened single crystals deformed in single slip. Good agreement has been obtained in general between the observed structures and the various theories for the flow stress and work hardening of this class of alloy. There has been though some difficulty in obtaining an accurate picture of these arrangements in the case when the obstacles are large (of the order of several 1000's Å). This is due to both the physical loss of dislocations from the thin foil in its preparation and to rearrangement of the structure on unloading and standing at room temperature under the influence of the very high localised stresses in the vicinity of the particles (2,3).This contribution presents part of a study of the Cu-Cr-SiO2 system where age hardening from the Cu-Cr and dispersion strengthening from Cu-Sio2 is combined.

Download Full-text

Effects of Dynamic Strain Hardening Exponent on Abnormal Cleavage Fracture Occurring During Drop Weight Tear Test of API X70 and X80 Linepipe Steels

Metallurgical and Materials Transactions A ◽

10.1007/s11661-013-2046-7 ◽

2013 ◽

Vol 45 (2) ◽

pp. 682-697 ◽

Cited By ~ 6

Author(s):

Minju Kang ◽

Hyunmin Kim ◽

Sunghak Lee ◽

Sang Yong Shin

Keyword(s):

Strain Hardening ◽

Cleavage Fracture ◽

Dynamic Strain ◽

Strain Hardening Exponent ◽

Drop Weight ◽

Drop Weight Tear Test ◽

Linepipe Steels

Download Full-text

Modelling Texturised Cast Structures in the Forging of Superalloys

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.278.210 ◽

2011 ◽

Vol 278 ◽

pp. 210-215

Author(s):

Jan Terhaar ◽

Nikolaus Blaes ◽

Dieter Bokelmann ◽

Hendrik Schafstall

Keyword(s):

Flow Stress ◽

Material Flow ◽

Cylindrical Specimen ◽

Material Model ◽

Growth Direction ◽

Solidification Structure ◽

Vacuum Arc ◽

Correct Prediction ◽

Dendrites Growth ◽

Stress Dependency

The main objective of remelting processes commonly used in the production of super¬alloys is to obtain a columnar dendritic solidification structure throughout the whole ingot. Besides reduced microsegregation, this cast structure features a preferred orientation, which is depending on the primary dendrites’ growth direction and therefore closely related to the ingot’s pool shape. As a result, non-isotropic material behaviour can be observed during initial forging operations. Since the correct prediction of material flow is a prerequisite for the further analysis of forging processes by means of numerical simulation, the solidification texture’s influence on plastic flow was accounted for by the application of an anisotropic material model. The model according to Barlat was used to scale the flow stress with respect to the crystal orientations observed in the examination of vacuum arc remelted alloy 718, thereby considering the flow stress’ dependency on strain, strain rate and temperature. The parameters defining the material's anisotropy could be determined by the upsetting of cylindrical specimen from a remelted ingot.

Download Full-text