In recent year, owing to the improvement of construction machine and technique of diaphragm walls, more and more cases use the diaphragm walls as supporting piles for structures. The diaphragm wall differs from the traditional circular pile not only by on the shape of cross section, but also on the method of construction. However, in engineering applications, the design method for wall-type pile still use the conventional method for circular piles. The suitability for this kind of analysis needs to be investigated. The purpose of this study is to investigate the behavior and bearing capacity of axially loaded wall-type piles. In this study, a set of wall-type pile load tests for the Daan Extra-high Voltage Substation(E/S), including a compressional test and a uplift test, is conducted. Besides, 8 sets of diaphragm wall load test cases in Taipei area are collected for analysis. All the test diaphragm walls are constructed by MASAGO-type machine with size ranged from 80cm×260cm to 100cm×270cm, and length ranged from 30m to 50m. From the analysis, the characteristics of the t-z curves and q-z curves for both the compressional and uplift cases are obtained. Besides, based on all test data, a normalized load-deflection curve and corresponding parameters for stiffness are deduced for engineering applications. In addition, the finite element method by using the compute code ABAQUS is adopted in this study to simulate the response of axially loaded piles with various shapes of the cross sections. The characteristic t-z and q-z curves are deduced from the simulation analyses and discussed. The results of numerical analyses reveal that the skin friction developed in the wall-type pile is generally greater than that of circular pile for the cases of sand layers. However, for the case of clay layers, the skin friction developed in both the wall-type pile and circular pile are almost same. Then, the finite element method is used to simulate the wall-type pile load test for the case of Daan E/S. A three-dimensional elasto-plastic analysis with frictional interface between the pile and soil are considered in the analysis. Results obtained are agreed well to the field data.