An attempt has been made to study the influence of the nature of microconstituents, strain rate and test temperature on the tensile properties of a zinc-based alloy (ZA 27). The properties of the alloy have been compared with those of a (leaded-tin) bronze (SAE 660) under similar test conditions. In the latter case, one of the phases (lead) has rather poor compatibility with the matrix. Properties such as hardness, density and electrical conductivity of the alloys have also been measured. The microstructure of the zinc-based alloy revealed primary alpha-dendrites surrounded by the eutectoid alpha + eta in the interdendritic regions. The metastable epsilon phase was also present. The bronze revealed primary alpha-dendrites together with the Cu-Sn intermetallic in the interdendritic regions. Discrete particles of lead were also observed in the microstructure of the bronze. Increasing test temperature caused a reduction in the ultimate tensile strength (UTS) and an increase in the ductility of the alloys, the zinc-based alloy being much more influenced than the bronze. Higher strain rates revealed improved strength and percentage elongation in which the zinc-based alloy was once again influenced more than the bronze. A comparison of the tensile properties revealed the UTS of the zinc-based alloy to be higher than that of the bronze at lower test temperatures while the trend reversed at higher temperatures. However, the percentage elongation of the former was always higher. Tensile fractured surfaces revealed the occurrence of material failure by a mixed mode, i.e. ductile and brittle type. The bronze specimens exhibited microcracking along the lead/matrix interfacial regions at low test temperatures. Fracture of lead was also observed in this case. However, this tendency was somewhat suppressed at higher test temperatures. The contribution of ductile fracture in the case of the zinc-based alloy was more than the bronze in general, whose extent increased at higher test temperatures. Coarsening of the dimples was another observation made at elevated test temperatures in the case of the zinc-based alloy. The behaviour of the alloys has been explained in terms of their microstructural and fractographic features. An attempt has also been made to understand the mechanisms of material failure.