Thermal spray can provide the substrate with coating surface for heavy corrosion environment, preventing the substrate from deformation caused by high temperature or strength decrease. As a corrosion prevention technology, thermal spray is environmentally friendly. The thermal spray equipment is expensive and complex. For decreasing cost and being portable, in this study ,a new thermal spray system to be developed with substitutes gliding arc system for heat source. Through the adjustment of the electrode gap, the coating area can also be adjusted. This study uses electrodes of different geometric shapes, angles, and gaps to measure the relation between gas flow and arc gliding distance, and to decide the working limit of the system. In the following spray experiment, the coatings were examined by SEM, roughness measurement, coating efficiency test, and the changed amount of coatings volume in different parameters. The consequences of the above tests help estimate the practicability of thermal spray. The observation of gliding arc indicates that the increase in electrode angle results in the decrease in the arc sliding distance. The main reason is that when the arc slides down, the electrode angle will be greater, which makes the gap below electrode become wider, and consequently, the intensity of the electric field between the electrodes will decrease. This will cause the power unable to maintain the arc; therefore, the greater the electrode angle is, the shorter arc sliding distance will be. When the flow rate increases, the arc sliding distance becomes shorter – with the fixed diameter of the nozzle, whenever gas flow increases, the flow rate increases; thus, the arc is easily cooled, so that the electronics in the arc will transform from the excited state to the ground state. The increase in electrode gap distance will make the arc sliding distance longer, and the main reason is that with the same gas flow, the wider the electrode gap is, the lower the flow rate will be. As a result, the cooling effect is not good enough to make the electronics of the arc transform from the excited state to ground state. However, when the electrode gap is widened to 10mm, this gap is close to the critical gap for arc ignition, which weakens the electric field strength, resulting in drastically shortened arc sliding distance. Spraying result indicates that with 2mm electrode gap and 30L/min gas flow, coatings show smoother surface, lower roughness, higher coating efficiency, and larger change in coating volume. The main reason for the good result is that high gas flow and small electrode gap allow melting powder to have high kinetic energy to hit the substrate. Therefore, the coating surface is smooth and has better attaching ability.