A novel hybrid process combining electrolysis process and micellar enhanced ultrafiltration process (MEUF) for treatment low-concentration-copper wastewater was developed. While MEUF process is employed to retain copper ions inside the reactor, the electrolysis process liberates copper ions from the micellar-copper complexes and continuously reduces copper ions by electroplating them onto the cathode. Thus the proposed hybrid process is operated as a continuous adsorption (MEUF) and regeneration (electrolysis) process. Experimental results show the removal efficiency of copper increases with increasing feed SDS concentration, current density, initial pH value, and hydraulic retention time (HRT). Under the optimum operation condition which has current density of 66A/m2, SDS influent concentration of 5.67mM, pH value of 6, and HRT of 15min, the system was able to obtain copper removal and electrolytic current efficiencies of above 90.3% and 30.5%, respectively, and membrane was not significant with transmembrane pressure (TMP) increasing only around 10% after 24-hour operation. Addition of a nonionic surfactant, polyoxyethylene Octyl phenyl ether (Triton X-100), with concentration higher than its critical micellar concentration (CMC), to a MEUF process can decrease the CMC value and permeate concentration of sodium dodecyl sulfate (SDS). Results show that the removal efficiency of copper increases with increasing Triton X-100 concentration. The adsorption density (q) of SDS micelles for copper was not affected by Triton X-100 addition with q of around 0.21 mole-Cu per mole-SDS, indicating that each mole copper would need five moles of SDS. However, the membrane fouling was worsening by addition of Triton X-100. Competitive binding of mixed metals onto SDS micelles was studied, and both atomic electronegative and radius of metals affect their removal efficiencies which are in the order of Pb>Cu≒Ni>Zn. For example, with metals, SDS and Triton X-100 concentration fixed at 136 mg/L of each metals, 8.5mM and 3.01mM, respectively, the metal removal efficiency of Pb, Cu, Ni and Zn are 63.8%, 18.0%, 14.0% and 5.2%, respectively. Membrane fouling is calculation by Darcy’s law, and the membrane fouling resistance (RC) increases from 0.8 to 11.28 (m-1) when metal concentration increasing from 13.6 to 136mg/L. The reason for the increases of membrane fouling with increasing metals concentration is not clear at this point, deserving further investigation in the future.