Aero-engine combustion chambers， blades， turbine outer rings and other hot-end components operate in harsh environments. In addition to being subjected to high temperature environments， these components are also subjected to corrosion and leaching caused by high temperature gases， so the application of high temperature protective coatings is critical. Protective coatings not only improve the temperature resistance of components， but also extend their service life， which in turn improves the overall performance of the engine. NiCoCrAlYTa coating is a typical high-temperature protective coating， demonstrating excellent oxidation and corrosion resistance at 1 050 ℃. Since elements such as Ta and Y have a promoting effect on the selective generation of Al₂O₃ oxide film， the NiCoCrAlYTa coating can form a complete Al₂O₃ film at high temperatures， resulting in good oxidation and thermal corrosion resistance. NiCoCrAlYTa coatings prepared on high-temperature alloys using low-pressure plasma spraying technology have the advantages of dense structure， uniform elemental distribution， low porosity， as well as significantly improving the fatigue limit of the substrate and excellent high-temperature service performance， which has become the coating of choice for the hot-end components of turboshaft engines， especially the turbine blades. However， the low-pressure plasma sprayed NiCoCrAlYTa coating has problems such as the thickness distribution is not easy to be regulated and the size of the unmelted particles exceeds the standard. Especially， the unmelted particles will lead to the decrease of coating performance and the reduction of oxidation and corrosion resistance， which will shorten the service life of the blade. The problem of batch size exceedance of unmelted particles occurred in the trial production of a turbine blade coating for a certain type of engine. Through the analysis of the unmolten particles in the spraying process， it is determined by exclusion and reproduction verification that the NiCoCrAlYTa dust in the vacuum chamber enters the coating during spraying， leading to the exceeding of the size of the unmelted particles in the coating. To address the cause of the problem， by adopting enhanced transfer arc cleaning， the problem of exceeding the size of unmelted particles caused by dust contamination can be effectively avoided， and coatings that meet the technical quality requirements can be obtained. This study provides engineering experience for the disposal of low pressure plasma spraying coatings with excessive size of unmelted particles.