Resorcinol-formaldehyde resin (RF) is one of the most important widely used adhesives in the wood industry. It is mainly applied in the manufacturing of laminated wood. After the adding of crosslinking hardener, RF adhesive has the capability to set at room temperature under neutral conditions. However, because resorcinol is costly, phenol-resorcinol-formaldehyde copolymer resin (PRF) is often used in order to reduce its production cost. In this study, wood of Cryptomeria japonica was liquefied with phenol as solvent. The liquefied wood (LW) was reacted with formaldehyde under different formaldehyde/phenol (F/P) molar ratios to form LW-PF prepolymer, resorcinol were then added at different ratios to form LW-PRF copolymers. The results showed that, compared to the acidic condition, the basic condition was better for preparing LW-PRF copolymer resins. The properties of the LW-PRF copolymers were affected by the synthesis conditions. Using lower F/P molar ratio at pre-polymerization stage, the resulted LW-PRF copolymer resin had higher solid content and viscosity, less unreacted formaldehyde content and relatively longer storage life. Increasing resorcinol in the co-polymerization stage would decreased the gel time and reduce the the viscosity of LW-PRF copolymer resin, while at the same time, enhanced solid content and storage life. Differential scanning calorimetry (DSC) thermal analysis showed that resins cured at room temperature exhibited an exothermic peak due to further crosslinking reaction. The LW-PRF copolymer resin with the addition of higher amount of resorcinol had the exothermic peak shifted to lower temperature region. When these LW-PRT copolymer resins were applied for wood gluing, resins prepared with the F/P molar ratio of 1.8/1 during pre-polymerization and with 40% and 30% of resorcinol during copolymerization had better bonding performance with bonding strength and wood failure rate meet the CNS 11031 standard requirements for structural laminated wood of the first type tree species.