A Review On Superplastic Behaviour In Light Alloys

DOI : 10.17577/IJERTV1IS9457

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A Review On Superplastic Behaviour In Light Alloys

Dr. P. Prabhakar Reddy; Dr. P. V .R. Ravindra Reddy; A. A. Sriramakrishna

Associate Professors, Department of Mechanical Engg, Chaitnaya Bharathi Institute of Technology, Gandipet, Hyderabad- 500 075

Abstact

Superplasticity is a term used to indicate the exceptional ductility that certain materials can exhibit when deformed under proper conditions. Materials with a fine grain size, usually less than 10

m, show superplasticity when they are deformed within the strain rate range of 10-5 to 10-3 sec-1 at temperatures greater than 0.5 Tm, where Tm is the melting point in Kelvin. The Superplastic Forming manufacturing process usually consists of heating the material to about half its absolute melting temperature and then slowly blowing it into the die of the required shape. Extremely thin and strong components can be formed using this technique.

Key words: Superplasticity, grain size, alloys

  1. Introduction

    Superplastic materials are polycrystalline solids which have the ability to undergo large uniform strains prior to failure [1]. The schematic sketch of the Superplastic deformation of a tensile specimen after undergoing tensile test is as shown in Fig 1.

    Fig 1: Schematic sketch indicating superplastic deformation

    Thus, the superplastic term is most often related to the ductile tensile behavior of the materials, however superplastic deformation has the characteristic of easy deformation under low pressure and compressed deformation characteristic are also described as superplastic. Superplastic materials exhibit very high tensile elongation, typically 500% or more, in a particular range of temperature and strain rate [2]. Such superplasticity

    in a material depends highly on the strain rate and occurs only in a narrow range of strain rate with an optimum value that is unique to each material: usually very low, such as 10-3 – 10-5 sec-1.

    Superplasticity in material arises from a high resistance to plastic instability during deformation, which leads to extremely large elongation (several hundred to several thousand percent), as shown in Table 1 [3]. Internal stress induced superplasticity is developed due to internal strain produced by thermal expansion mismatch between two phases

    [4] by phase transformation or by expansion anisotropy. However, The process could not be developed to a sufficiently controllable stage for commercial use.

    There are several different types of Superplasticity in terms of the microstructure mechanisms and deformation conditions, including the following.

    1. Micro Grain Superplasticity

    2. Transformation Superplasticity

    3. Internal Stress Superplasticity

      At this time, only the micro gain Superplasticity is of importance in the fabrication of parts and the discussion will be limited to this type. For micro grain superplasticity, the high ductilities are observed only under certain conditions and the basic requirements for this type of super plasticity are:

      • Very fine grain size material (of the order of 10m)

      • Relatively high temperature (Greater than about one-half the absolute melting point)

      • A controlled strain rate (usually 0.0001 to 0.01 sec-1)

  2. Prerequisites for Micrograin Superplasticity

    1. Grain Size

      Grain size is probably the single most important parameter for developing micrograin

      superplasticity. An ultrafine grain size is the most important microstructural attribute of superplastic alloy. The finer, the grain size, more are the grain boundaries. Since grain boundary structure is random and therefore behaves like viscous material, superplasticity develops in fine grain material. The apparent viscosity of superplastic Materials have been determined to be 104 109 poises [5] (for hot glass the value is 107). When the grain size is finer, the flow stress is lower, the strain rate sensitivity m becomes higher and the total tensile elongation is greater [6]. A finer grain size also tends to increase the strain rate range at which the superplastic region exists [7]. The dependence of stress on grain size can be described by the following relationship

    2. Temperature

      It is generally agreed that the temperature for superplastic deformation must be in excess of about

      0.5 Tm, where Tm is the absolute melting point. The need for the elevated temperature is to provide the diffusion mechanism necessary for permitting the superplastic deformation to proceed. Below 0.3Tm, the diffusion kinetics becomes too sluggish [8]. The maximum deformation temperature is, however, limited by the consideration of grain coarsening or the phase transformation temperature. For high strength precipitation hardening A1-alloys like 7475 the optimum superplastic deformation temperature has been reported as 789K, which is slightly above its solutionising temperature (755K). On the other hand, for A1-Li alloy the optimum superplastic temperature (773-783K) was marginally below the solutionising temperature.

    3. Strain-Rate

      Fine grained superplastic materials invariably exhibit a high strain-rate sensitivity of flow stress within a certain strain-rate range, as shown in Fig.2 schematically [7], usually in the strain rate range of 10-4 to 10-2 Sec-1. Superplasticity occurs in region II only, where the strain-rate sensitivity lies between 0.3 to 0.9 [9]. According to NIX, however, the value reaches a maximum of 0.5. In region I and III the strain rate sensitivity again falls to 0.2 or less for some alloys [10], and the tensile elongations are usually less than 200%.

      The strain rate () corresponding to maximum strain-rate sensitivity m generally increases with decreasing grain size, and with increasing temperature. Obviously the increase in is desirable from the standpoint of reducing forming time during practical forming. Moreover, grain

      coarsening is also minimum with minimum forming time.

    4. Strain-Rate Sensitivity Index m

      Superplastic ductility is generally found to be related to the strain rate sensitivity exponent m where

      m = (ln) / (ln) 2.2 where, = flow stress ,

      = true strain rate

      The high strain rate sensitivity of a material imparts high neck resistance which in turn results large elongation. Holt has provided the following explanation [11].

      By manipulating the well known equations,

      =P/A 2.3

      = -l/A (dA/dT) 2.4

      =Km 2.5

      The following relationship can be derived. dA/dT = – (P/K)l/m A l-l/m 2.6

      Table 1 : Summary of Superplasticity in Different Alloys [3]

      Alloys

      Test Temp. (ºC)

      Strain rate(S-

      1)

      m

      Elong(%)

      Statically Recrystallized

      Al-33Cu

      400-500

      8.0 x 10-4

      0.8

      400-1000

      Al-4.5Zn-4.5CA

      550

      8.0 x 10-3

      0.6

      600

      A1-6 to 10Zn- 1.0Mg-0.2Zr

      550

      10-1

      0.9

      1500

      A1-5.6Zn-2Mg-

      1.5Cu-0.2Cr

      516

      2.0 X 10-4

      0.8-0.9

      800-1200

      Dynamically Recrystalized

      A1-6Cu-0.5Zr

      450

      10-3

      0.3

      1000

      A1-6Cu- 0.35Mg-

      450

      10-4

      0.3

      900

      0.14S1

      A1-4Cu-3LI- 0.5Zr

      450

      5.00 X 10-4

      0.5

      900

      A1-3Cu-2LI- 1Mg-0.2Zr

      500

      1.30 X 10-4

      0.4

      878

      Iron Base Alloys Ultra High Carbon

      Fe-(1.3-1.6C)

      650

      1.67 X 10-4

      0.5

      250-1500

      Fe-(2.1-2.4C)

      650

      1.67 X 10-4

      0.5

      526

      Alloy Steels

      Fe-0.4C-1.9Mn

      727

      3.34 X 10-4

      0.5

      460

      Fe-0.13C-1.1Mn

      800

      8.30 X 10-4

      275

      Fe-0.33C- 1.14Mn

      900

      3.34 X 10-4

      430

      Fe-4Ni-3Mo- 1.6Ti

      900-

      960

      8.30 X 10-4

      0.5-0.7

      800

      High Carbon Low Alloy:

      Fe-1.0C-0.5W-

      0.2V-1Mn

      650

      1.67 X 10-4

      0.5

      1200

      Stainless Steels

      Fe-26Cr-6.5Ni

      960

      3.30 X 10-3

      0.55

      1000

      Fe-18.5Cr- 4.9Ni-

      2.8Mo

      1000

      8.3 X 10-4

      0.7

      700

      Ni-Base Alloys:

      Ni-Cr-Fe

      1000

      0.5

      960

      Inconel

      0.7-0.9

      250

      Astrology

      Zn-6KP

      0.4-0.6

      Ni-Mo

      IN-100(PM)

      IN-738(PM)

      0.4

      500

      713LC (PM)

      0.5

      230

      NASA TAZ-8 (PM)

      600

      MAR-M200 (PM)

      1038

      PA 101

      RENE 95 (PM)

      927

      Ni-Cr-Fe

      1000

      0.5

      960

      REGION I

      DIFFUSION CREEP

      m = 1 m = 1 or 0.2

      REGION II

      SUPER PLASTICITY

      m = 0.5

      REGION III

      POWER LAW CREEP

      m = 0.2

      LOG (STRESS)

      LOG (STRAIN RATE)

      m=0.4 – 0.8

      m=0.2 – 0.33

      m

      log .

      Fig. 2 : Schematic representation of Superplastic behaviour

    5. Characteristics of superplastic metals

For a superplastic metal that is tensile tested under proper conditions of temperature, the observed ductility is seen to vary substantially with strain rate, as shown in Fig.3 for a Zinc-Aluminum eutectoid alloy. As shown, there is a maximum ductility at a specific strain rate, with significant loss in ductility as the strain is increased or decreased relative to this maximum. It is well known that the primary factor related to this behavior is the rate of change of flow stress with strain rate, usually measured and reported as m, the strain rate sensitivity exponent, is defined as;

m = ln /ln ———-(1)

where is the flow stress and is the strain rate.

Fig:3.Tensile fracture strain versus initial strain rate for a Zn-22Al alloy having a grain size of 25 m tested at temperatures ranging from 423 to 503 K.

Conclusions

Superplasticity in different alloys can be attributed to different parameters like grain size, temperature, strain rate and strain rate sensitivity index etc. The ability of superplasticity can be attained by different techniques which enable an alloy to form into difficult to form and complicated shapes because of its high ductility. An alloy, on attaining superplasticity can have higher ductility values even above 500%.

References

  1. J.Pilling and N.Ridley, Superplasticity in crystalline solids, The Institute of Metals, 1989.

  2. K.Padmanabhan and G.J.Davis, Superplasticity, Springer, Berlin, 1980.

  3. Hamilton, C.H., Ghosh A.K. and wert, J.A., Superplasticity in Engineering Alloys: A Review, Metals Forum, 8, 172(1985).

  4. Wu.M.Y. and Sherby O.D., Scripta Met.8, 773(1984)

  5. Avery D.H., Backofen W.A., Trans.Am.Soc.Met., 58, 531(1965).

  6. Hamilton C.H., Ghosh A.K. and Wert J.A., Superplasticity in Engineering, Metal Forum, 8, 172(1985).

  7. Hamilton C.H. Superplasticity in strength of Metals and Alloys, ICSMA-7, Eds. N.J.Mc. Queen et.al., pergamon press, Oxford, 3, 1831-1857(1986).

  8. Ghosh A.K. and Hamilton C.H., Superplastic Forming and Diffusion Bonding of Titanium Alloys, Defence

    Science Journal (India), 36, No. 2, April, 153-177(1986).

  9. Edingon, Jeff W., Microstructural Aspects of Superplasticity, Met. Trans., 13(A), 703 (1982).

  10. Nix, W.D. , On some Fundamental Aspects of Superplastic Flow, in Superplastic Forming, Ed. Suphal Agarwal, ASM, Metals park, ohio, 3- 12(1984).

  11. Holt, D.L., Superplastic Fine Grain Alloys in the Forming of Sheet Metal, in Ultrafine Grain Metals, Eds. John J. Burke and Volker Weiss, Syracuse University Press, New York, 355-375(1969).

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