High-rise reinforced concrete buildings can be built with the aids of the structural wall. In these cases, ductile coupled shear wall, an efficient lateral-force-resisting system, is usually placed at the core the coupled wall system can area of tall building. As compared to the traditional shear wall system, satisfy better the demand of space. The ductility of coupled shear wall requiresa good deformation capability on connected beams. According to previous researches, adequate shear strength is indispensable for develop went of ductility. Therefore this research focuses on maintaining and improving shear strength by varying the properties of material and apect-ratio. Eight full-scale specimens were designed to study the effects of shear strength under different aspect-ratio, properties of material (concrete strength, steel strength of diagonal bar), and alignment at the end of diagonal bar. Test results indicate that reducing the aspect-ratio will increase the shear demand. Meanwhile, it indicates that the more amounts of diagonal reinforcements are required. Although using higher strength of concrete can increase the shear capacity, it accelerates the softening effect of concrete. Moreover, providing higher yielding strength of diagonal bar could improve limited shear capacity and deformation ability. The different detailing at the ends of diagonal bar made no different on strength development and deformation capacity. This research also proposed an analytical model to predict the shear strength of coupling beam.