A field-scale(8.6${ imes}$2.5${ imes}$2.4 m) and pilot-scale(1.39${ imes}$0.89${ imes}$0.89 m) thermophilic aerobic oxidation (TAO) units were installed to investigate the volume reduction efficiency of slurry, by varying the aeration and treatment temperature of swine manure, and the collected liquid was evaluated as a liquid fertilizer. In the field-scale unit, the aeration level and numbers of foam breakers made different effects on the slurry volume and temperature in the TAO system. The experiments were peformed for three cases, using different levels of aeration and numbers of foam breakers: Treat-A (aeration rate; 120 ㎥ air/hr using 2 air pumps and 2 foam breakers), Treat-B (aeration rate; 180 ㎥ air/hr using 3 air pumps and 3 foam breakers) and Treat-C (aeration rate; 180 ㎥ air/hr using 3 air pumps and 4 foam breakers). With the same input volume (5 ㎥/day) of swine manure slurry, the resulting liquid levels, temperatures and evaporation rates were 50∼100 cm, 31∼$64^{circ}C$ and 55 $ell/m^2$/day for Treat-A; 40∼90 cm, 29∼$52^{circ}C$ and 75 $ell/m^2$/day for Treat-B; and 40∼70 cm, 45∼$54^{circ}C$ and 120.0 $ell/m^2$/day for Treat-C. In the pilot-scale unit, semi-continuous flow of swine manure slurry was introduced. 50 $ell$ every 2hr(T-1), 50 $ell$ every 3hr(T-2), 40 $ell$ every 2hr (T-3) and 60 $ell$ every 4hr (T-4) within 24 hours, in order to find the maximum slurry volume reduction conditions.