Phenol-formaldehyde resin (PF) is one of the most important synthetic resins. In addition to being used as an adhesive, impregnated resins and molding materials, porous carbon can be obtained from PF resin through a high-temperature heat treatment with high yield. In this study, phenol and formalin were used as raw materials to prepare hardened PF resins by suspension polymerization (PF-A), inverse emulsion polymerization (PF-B) and in situ polymerization (PF-C). Among them, PF-A was an independent spherical resin, PF-B was a particle formed by the aggregation of many tiny spherical resins, and PF-C is a bulk resin. FTIR analysis showed that the structure of PF-A was dominated by tetra-substituted benzene rings, while PF-B and PF-C were dominated by 1,2,4- and 1,2,6-trisubstituted benzene rings. TGA results showed that PF-A and PF-C had better thermal resistance. They had a char yield of more than 65% when heated to 750°C, while the thermal resistance of PF-B is low. After carbonization, the adsorption capacity of the three PF resins could be greatly improved. Among them, PF-C had the most developed pore structure and the largest adsorption capacity. Its carbonized materials had both micropores and mesopores with a specific surface area of 419.6 m^2/g, and had the nitrogen isothermal adsorption-desorption curves belonged to IUPAC (International Union of Pure and Applied Chemistry) Classification of Type IV (a).