A mathematical model describing the transient hydraulic head distribution induced by a constant-head pumping/injection in a radial two-zone confined aquifer at a partially penetrating well is a mixed-type boundary value problem. The analytical solution of the model is very complicated and difficult to evaluate accurately. This study aims at developing a new approximate solution describing the transient hydraulic head distribution for a constant-head test (CHT) at a partially penetrating well in aquifers of infinite extent. This approximate solution is acquired based on a time-dependent diffusion layer approximation proposed in the field of electrochemistry. The approximate solution is in terms of modified Bessel functions for aquifers with a partially penetrating well and can reduce to a simpler form in terms of natural logarithmic function for the case of well full penetration. Moreover, it can further reduce to Perrochet’s solution (2005) if the aquifer is without the skin zone and at a fully penetrating well. The predicted transient hydraulic heads from the present approximate solutions are compared with those estimated by Yang and Yeh’s Laplace-domain solution (2005) for partial penetration case and Yang and Yeh’s time-domain solution (2006) for full penetration case. The results show that the differences between the present approximate solution and Yang and Yeh’s solutions (2005, 2006) are large when the test time is small. The differences are however less than 10-3. This newly developed approximate solution has advantages of easy computing and good accuracy from practical viewpoint and thus is a handy tool to evaluate temporal and spatial hydraulic head distributions for the CHT.