In this study, photocatalytic reduction and ion exchange methods were employed to fabricate the ternary nanocomposite photocatalysts of Ag-TiO2-graphene (ATG) and Ag3PO4-TiO2-graphene oxide (APTGO), respectively. The contents of graphene and Ag in ATG were adjusted, and the molar ratio of Ag3PO4 to TiO2 in APTGO was tuned. The properties and photocatalytic activity of the nanocomposites were examined, and their photodegradation mechanisms were explored. When an ATG had more graphene, light absorption and charge transport were enhanced, leading to higher efficiencies of photodegradation and hydrogen production from water splitting. It was proved that the optimum ratio between TiO2 and graphene was 5:1. More Ag contributed to light absorption and reduced impedance. The surface enhanced Raman scattering (SERS) effect induced by Ag nanoparticles was favorable to photocatalytic activity. However, excess Ag decreased the specific surfacearea of an ATG photocatalyst, and lower light absorption and increased recombination probability were thereby caused. Accordingly, an appropriate content of Ag was required so as to obtain more effective photocatalysis. Moreover, it was found that the optimum Ag content was different for a different mixing ratio between TiO2 and graphene. The best photocatalytic efficiency of ATG (max. hydrogen production 4233 mole g-1 and QE = 26.2 %) was achieved when graphene and Ag both existed optimal contens. More TiO2 in APTGO improved light absorption but caused a larger impedance and inferior charge transport. Excess TiO2 distributed over the surfaces of Ag3PO4 and graphene oxide decreased the specific surface area and thus lower light absorbance of an APTGO photocatalyst. It has been evidenced that an appropriate TiO2 content was beneficial to enhance photocatalytic performance. Larger and wider light absorption and thereby highest photocatalytic efficiency of APTGO (max. hydrogen production 1312 mole g-1 and QE = 8.13 %) were achieved when the molar ratio of Ag3PO4 to TiO2 was 0.6.