Technological Aspect of Processing Maps for the AA2099 Alloy

doi:10.1007/s40195-014-0150-3

Abstract

Abstract: Results

of an experimental and modelling study of forming processes in the AA2099 Al-Cu-Li alloy, for a wide range of temperatures, strains and strain rates, are presented. The analyses are based on tensile testing at 20°C at a strain rate of 0.02s^-1 and uniaxial compression testing in the temperature range 400-550°C at strain rates ranging from 0.001 to 100s^-1, for constant values of true strain of 0.5 and 0.9. The stability of plastic deformation and its relationship with a sensitivity of stress to strain rate are considered. The power dissipation efficiency coefficient, η(%), and the flow instability parameter, ξ≤0, were determined. The complex processing maps for hot working were determined and quantified, including process frames for basic forging processes: conventional forging and for near-superplastic and isothermal conditions. A significant aspect is the convergence of power dissipation when passing through the 500°C peak. Deformation, temperature and strain-rate-dependent microstructures at 500°C for strain rates of 0.1, 1, 10 and 100s^-1 are described and analysed for the conventional die forging process frame, corresponding to 465-523°C and strain rates of 50-100s^-1.

Key words: Al-Cu-Li alloy, Power dissipation efficiency, Processing maps, Microstructure, Hot deformation

Aneta Łukaszek-Sołek. Technological Aspect of Processing Maps for the AA2099 Alloy[J]. Acta Metallurgica Sinica (English Letters), 2015, 28(1): 22-31.

Figures/Tables 12

Table 1 Chemical composition (wt%) of the investigated AA2099 alloy

Cu	Li	Zn	Mg	Mn	Zr	Ti	Fe	Al
2.6	1.8	0.7	0.29	0.3	0.1	0.03	0.02	Bal.

Table 2 Properties of AA2099 alloy

ρ (g/cm³)	R _p0.2 (N/mm²)	R _m (N/mm²)	A₅ (%)	Z _z (%)	E (GPa)	HB
2.63	596.9	615	5.8	9.7	83	157.5

Fig.1 Microstructure of the investigated alloy (as-delivered conditions): a, b longitudinal section, c, d transverse section of a bar

Fig.2 Stress-strain curves of AA2099 alloy obtained at different strain rates and temperatures of 450°C a and 500°C b

Fig.3 Relations between log σ and $ { \log }\;\dot{\varepsilon } $ for true strain of 0.5 a and 0.9 b

Table 3 Examples for statistically estimated structural parameters of a polynomial regression function (Eq. (3)) for true strain of 0.9

Parameters	Temperature (°C)
Parameters	400	550
a	1.9469	1.4967
b	0.1295	0.1890
c	0.0038	0.0016
d	0.0059	0.0001

Fig.4 Changes of strain rate sensitivity exponent (m): a as a function of $ { \log }\;\left( {\dot{\varepsilon }} \right) $, for the analysed temperatures and b as a function of temperature, at constant strain of 0.9

Fig.5 Variations of J co-content as a function of temperature, strain rate and constant strain value

Fig.6 Optical a, c, e, g and SEM b, d, f, h microstructures of AA2099 alloy after deformation in isothermal conditions in uniaxial compression test, at the temperature of 500°C and strain rate of:$ a, b $ \dot{\varepsilon } = 0.00 1\,{\text{s}}^{ - 1} $, c, d $ \dot{\varepsilon } = 0. 1\,{\text{s}}^{ - 1} $, e, f $ \dot{\varepsilon } = 1\,{\text{s}}^{ - 1} $, g, h $ \dot{\varepsilon } = 10\,{\text{s}}^{ - 1} $$, for true strain of 0.9

Fig.7 Variations of power dissipation efficiency, as a function of forging temperature and strain rate, for constant strain value of 0.5 a and 0.9 b

Fig.8 Complex map of power dissipation efficiency and flow instability parameter, for AA2099 alloy, as a function of strain rate and temperature, for true strain of 0.5 a and 0.9 b

Fig.9 Shape of the final forging of a contact tip

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