Abstract WG EGGS is a large-scale food factory facing various wastewater treatment challenges. WG EGGS deals with high concentrations of organic wastewater from egg washing, egg liquid, chicken excrement, and domestic sewage, with water quality varying based on the daily egg breakage rate. To address the difficulty in homogenizing egg liquid in the water, the plant added activated sludge and a (membrane bioreactor, MBR) treatment unit to the existing contact aeration treatment system, forming an activated sludge/contact aeration/MBR combined treatment system. Due to the presence of suspended and attached microorganisms, including aerobic, facultative anaerobic, and anaerobic bacteria, the system has a diverse biological community, ensuring stability and resistance to environmental impacts, achieving the expected water quality treatment effects. Although MBR is considered one of the most promising wastewater treatment technologies, it still faces high costs and membrane fouling issues. In this combined system, biological media filtration in the contact aeration tank effectively solves the membrane fouling problem and achieves good treatment effects in terms of average removal rates for COD, BOD, SS, and grease, while also reducing operating and equipment costs. After treatment by this system, the average removal rates were 97.7% for suspended solids, 94.5% for COD, 96.7% for BOD, and 92.1% for grease. The average values ± standard deviations for influent COD, BOD, SS, and grease were (567.6±473.7) mg/L, (282.5±252.4) mg/L, (390±689.8) mg/L, and (30.5±27) mg/L, respectively. After treatment, the effluent average values ± standard deviations decreased to (30.9±14.8) mg/L, (9.2±4.6) mg/L, (8.7±9.8) mg/L, and (2.4±2.2) mg/L, respectively. Despite significant variations in influent concentration, the effluent water quality remained stable, demonstrating the system's stability and resilience to environmental impacts. Through water quality analysis of various tanks at the WG EGGS plant and (next generation sequencing, NGS), it was found that each tank had a diverse biological community, including species with nitrification and denitrification capabilities, contributing to effective removal of various pollutants. The water quality average removal rates for COD, BOD, grease, total nitrogen, ammonia nitrogen, organic nitrogen, total phosphorus, and dissolved organic carbon at 05:00, 08:00, and 11:00 were 94%, 97%, 96%, 46%, 86%, 88%, 65%, and 97%, respectively. The system achieved certain efficiencies in removing total nitrogen and total phosphorus, with effluent meeting reclaimed water standards. The variations in nitrate nitrogen and nitrite nitrogen values indicated significant transformations of organic nitrogen to ammonia nitrogen, followed by aerobic nitrification to nitrite nitrogen and nitrate nitrogen. The average reductions were 7 mg/L for total nitrogen, 5.5 mg/L for ammonia nitrogen, 6.9 mg/L for organic nitrogen, and an average increase of 5.4 mg/L for nitrate nitrogen. The average removal rates were 46% for total nitrogen, 87% for ammonia nitrogen, 88% for organic nitrogen, and an increase of 93% for nitrate nitrogen. The system also showed effectiveness in total phosphorus removal, with an average reduction of 1.4 mg/L and a removal rate of 65%. The treatment system exhibited high biological diversity, including competitive aerobic, anaerobic, and facultative anaerobic microorganisms, with metabolic pathways involving nitrification and denitrification, and survival modes including attached and suspended microorganisms.