The resultant thermoelectric properties of Cu/T/Cu composites welded with T = Bi0.88Sb0.12 alloy were measured in the temperature range from T = 193 K to 298 K and compared with those calculated as a function of x by treating these composites as an electrical and thermal circuit, where x is the ratio of thickness of Bi-Sb alloy to the interval between two thermocouples. Consequently, the resultant electrical resistivities rho of composites coincided closely with the calculated rho values as a function of x, while the resultant Seebeck coefficients alpha were enhanced significantly in the range from x=0.076 to 0.61. In the x range from 0.16 to 1.0, the x-dependence of the resultant thermoelectric power factor P was found to be explained roughly at every temperature by the simple model proposed here when an enhancement factor in alpha was taken into the calculation. However, the maximum resultant P appeared at a small x of 0.076. The resultant P at x = 0.076 increases with a decrease of T and reached a surprisingly great value of 128.3 mW/K-2 mW/K-2 m at 193 K, which is 15.5 times larger than 8.29 mW/K-2 m obtained for Bi0.88Sb0.12 alloy. On the other hand, its resultant ZT also increases monotonically with a decrease of T and has a great value of 0.54 at 193 K, which is 31% higher than 0.41 at 193 K for Bi-Sb alloy. The significant enhancement in the resultants P and ZT at low temperatures is owing predominantly to the increase in alpha due to the boundary effect.