In this study, we focus on investigating the performance of the solar collector of a evacuated tube in the adsorption refrigeration system. Using methanol and activated carbon as the working pair, the desorbed mass is measured under different initial pressure so that the theoretical COP is calculated. The effects of outlet temperature of the adsorber, the initial presure, and the porosity of the activated carbon are discussed. In addition, we employ the thermal resistance analysis to determine the heat transfer associated with different compoents of the adsorber. The experimental results show that when outlet temperature of the adsorber is 100°C, the maximal theoretical COP and collector efficiency can be reached. The theoretical COP and the collector efficiency increase as the outlet temperature of the adsorber increases. In contrast, once the outlet temperature of adsorber is increased to 110°C, heat loss of the evacuated tube increases and the required heating also augment. Hence, the theoretical COP and the collector efficiency would decrease or be the same value as the outlet temperature of the adsorber is 100°C. When the porosity of activated carbon is decreased to 18.1%, the maximal theoretical COP and the collector efficiency can be achieved. When the amount of activated carbon in the adsorber increases, more methanol can be adsorbed and the amount of desorbed methanol also increases. On the other hand, the effect of the porosity of activated carbon on the effective thermal conductivity of the working pair is negligible. As a result, the effect of the amount of desorbed methanol dominates the role the porosity plays in COP. We also find the theoretical COP and collector efficiency are nearly independent of the initial pressure. Increasing the initial pressure leads to a higher saturation temperature for methanol at the exit of the throttling valve with lower enthanlpy of vaporiation. Consequently, the cooling capacity would almost be constant and The effect of initial pressure is negligible.