Technology of Obtaining and Mechanical Processing of Resistant Powder Coatings of Ni-Mo-Al System

Alexey Yu. Plesovskikh; Svetlana E. Krylova; Vladimir I. Yurshev; Andrey A. Seregin; Ivan A. Kurnoskin

doi:10.4028/p-1k1vx0

Paper Titles

Some Aspects of the Experimental Method for Determining Residual Stresses in the Circular Grooves of Body Parts
p.436

Influence of Preheating and Postweld Heat Treatment on the Structure and Strength of the Wire Frame Welded Joint Made of Spring Steel C62D
p.442

Simulation of Hydro-Mechanical Billet Pressing of Fibrous Bimetallic Composites
p.450

The Effect of Hydrogen on the Crack Resistance in the Laser Treatment Area of Structural Steels Used for the Manufacture of Sealed Capsules during Hot Isostatic Pressing
p.458

Technology of Obtaining and Mechanical Processing of Resistant Powder Coatings of Ni-Mo-Al System
p.464

Modernization of Electrode Composite Material Based on Copper Powder for Electrical Discharge Machining of High-Strength Alloys
p.472

Development of Thermoplastic Composite Tube from HDPE/Barley Straw Fibers Using Extrusion Method
p.478

Sequential Treatment of Steel Surfaces by Nitriding and Ultrasonic Hardening
p.484

Quality Control of Gas-Thermal Coatings of Variable Composition
p.490

HomeKey Engineering MaterialsKey Engineering Materials Vol. 910Technology of Obtaining and Mechanical Processing...

Technology of Obtaining and Mechanical Processing of Resistant Powder Coatings of Ni-Mo-Al System

Abstract:

The results of a technological process development for obtaining a wear-resistant powder coating of Ni-Mo-Al system, applied by cold gas-flame spraying to the surface of a critical unit of compressor equipment in the oil and gas industry, within the framework of repair production are presented. Using scanning electron microscopy (SEM), the features of the structure and distribution of alloying elements in the coating are determined. The authors rationalized mechanical processing of the surface layer in order to obtain minimum roughness of the working area of the compressor cylinder. It is shown that the sprayed coating of Ni-Mo-Al system has a satisfactory adhesion strength in the range of 30-50 MPa, microhardness of 200-210 HV, which provides an increased running-in rate of piston rings of 6-10 mm³/Nm when operating the compressor in the temperature range of 350 - 400 °C. The parameters of finishing machining process of the finished coating are worked out, which makes it possible to ensure the minimum possible roughness of the coating of Ni-Mo-Al system in the range of 0.08-0.15 Ra in order to reduce wear of the working surface and extend service life.

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Periodical:

Key Engineering Materials (Volume 910)

Pages:

464-471

DOI:

https://doi.org/10.4028/p-1k1vx0

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Online since:

February 2022

Authors:

Alexey Yu. Plesovskikh*, Svetlana E. Krylova, Vladimir I. Yurshev, Andrey A. Seregin, Ivan A. Kurnoskin

Keywords:

Cold Gas-Flame Spraying, Compressor Equipment Repair, Distribution of Alloying Elements, Finishing Machining Process, Powder Coating, Surface Roughness

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