Soil-nailing have been widely used in soil excavation and slope stabilization. Closely spaced nails are buried or drilled into soil to form a reinforced structure. Close space between nails then cause stresses overlap, which may reduce the effectiveness of individual nail. The purpose of this study is to investigate the pullout behavior of the nail through the tests of single. A non-dimensional surface roughness factor R was described the interface between nail and soil. In order to understand mechanical behavior of the group nails, experimental program is performed for the tests of double and three nails. Additionally, the cavity expansion theory is made to construct a theoretical model for modeling the pullout force-displacement behavior. The influence of size effect for the pullout resistances of single and group-nails was concerned. The conclusions via the tests and theoretical analysis are summarized: (1) The peak and residual apparent friction coefficients at the soil-nail interface are increased with increase of the screw pitch and particle size but decreased with increase of the nail diameter. The overburden pressure has not a significant influence on the apparent friction coefficient. Besides, such of smooth nails are not influenced by the nail diameter. (2) The group efficiency of a double nail was shown to be dependent on the surface roughness factor and nail diameter. The minimum required distance for 100% efficiency is increased with increasing the surface roughness factor but reduced with increasing the nail diameter. (3) In the group tests, the pullout behavior of both sides nails is similar a double nail. However, the influence overlap zone of the center nail is complex; the pullout resistance of a center nail is less than a both sides nail in the test results. (4) Using the cavity expansion theory to model the pullout force-displacement behavior is performed by way of the assumption for the linear relationship of soil dilative angle and pullout displacement. (5) Analytical results reveal that the apparent friction coefficient reduced with increasing overburden pressure and nail diameter. Apparent friction coefficient reaches a constant value while the large diameter and/or the higher overburden pressure.