Abstract
This study discusses the effect of a duplex aging + nitriding process on the wear resistance of an aged double-phase titanium alloy, BT22. Nitriding was applied simultaneously with the heat treatment of the alloy, which is advantageous over the conventional heat and surface treatment methods applied to titanium alloys. According to the results, the thickness of the case depth of the nitrided samples was 40–50 μm. Moreover, nitrogen was uniformly dispersed in the substrate, which was indicated by the hardness tests. The average microhardness of the substrate material was 300 HV0.01, while the hardness of the top layer was 1190 HV0.01, which is an almost four-fold increase. The applied duplex treatment substantially affected the wear performance of the tested alloy. For the untreated alloy, the maximum coefficient of friction was 0.8, while in the surface-modified sample, the maximum fluctuations reached 0.6. The abrasive wear process was dominant in the nitrided samples, while delamination and adhesive wear were observed for the untreated specimens. The nitrided alloy exhibited double the wear resistance of the untreated samples. The proposed treatment does not require additional time or energy consumption, providing a substantial technological advantage over conventional methods. Though the alpha case reduces the mechanical performance of titanium, the nitriding of only the component sections intended to withstand friction will have a positive effect.
Highlights
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If not specially treated, they are characterized by relatively low wear resistance [1,2], a significant limiting factor for their application
Our study proposed a method of improving the wear resistance of a heavyduty double-phase Ti-64, BT22 alloy by a duplex aging and thermochemical treatment
Summary
Aerospace is an important field requiring advanced structural materials and engineering solutions, including composite materials (metal–fiber laminates, carbon–carbon and other advanced composites), high-strength heat-treatable aluminum alloys (7075, 7068, 6061), CRES and PH steels (Type 316, 15-5PH, 17-7PH), nickel and cobalt superalloys (HAYNESS 188, Inconel 718, TMS 162), titanium alloys (Ti-64, BT22, Ti-1023), etc. The application of titanium alloys is expanding due to their high corrosion resistance and excellent strength-to-weight ratio. If not specially treated, they are characterized by relatively low wear resistance [1,2], a significant limiting factor for their application. In virtually fixed joints (e.g., skin rivets, splined joints, threaded joints), vibration-induced displacements cause fretting wear. In kinematic joints (e.g., cylinder-compression rings, flap track-rollers), high-contact pressure limits the application of conventional anti-wear coatings [4]. One possible exception is fan blades, where thick, hard facing coatings protect the blades’ root section and mid-span shrouds [5]
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