The paper describes the early and final uniaxial creep behaviour of a Titanium alloy used for manufacturing intermediate power compressor disks and blades. Tests were conducted at the operating temperature (773 K) for such components and for rupture lives up to 3600 hours. Creep curves were fitted using either the conventional 4 Theta model or the recently developed 6 theta equation. Parameters allowing the interpolation of times to small strains were produced and their accuracy checked against experimental values using distributions found to be most supported by the data. At strains above 0.75% both methods yielded zero mean interpolation errors. At strains above 0.27% and below 0.75% the 4 Theta equation produced systematic errors in interpolation but the 6 theta function gave errors which were not statistically different from zero. For strains below 0.27% both techniques produced systematic interpolation errors but the 6 theta interpolations were always significantly better than their 4 Theta counterparts. Both the 6 theta and 4 Theta techniques produced systematic errors when predicting the failure time using interpolated rupture strains. Unlike the 4 Theta function, the 6 theta equation produced unbiased predictions of the minimum creep rate and so produced failure time interpolations from the Monkman-Grant relation that were indistinguishable from zero.