In this study, a basic design is proposed for an alpha-type hot air Stirling engine developed from a diesel engine. The engine is designed to be heated by the solar radiation from a concentrated solar collector and cooled by cooling water. The gas flow channels in the heater and cooler are constructed by finned and non-finned parallel metal plates, respectively. The regenerator design uses parallel wire screens. A third order model for the Stirling engine and a kinematic model for the slider- crank structure are developed and the two models are interconnected to simulate the operation of the whole Stirling engine. The Stirling engine model solves the mass, momentum and energy conservation equations for each control volume or node of the heater, cooler, regenerator and the hot and cold cylinders. The simulation of the base design case reveals the cyclic operating conditions of the working gas and the solid temperatures. For the gas, the pressure ranged 0.58-1.17 MPa, the maximum pressure difference in the engine is about 0.1 MPa and the temperature ranged 290-1200 K. For the metal in the regenerator, the temperature distribution is linear and the effectiveness of the regenerator is 82.6%. The power output from the engine is 0.6 kW and the thermal efficiency is 12.5%. In this study, six modified design cases are analyzed, including the adjustment of cooler size, heater size, cooling water temperature, cooling water flow rate and mass of working gas. The simulation results indicate that reducing the size of cooler provides the maximum improvement. The power output and the thermal efficiency can be raised to 0.8 kW and 14.29%., respectively.