The Development and Applications of Powder Metallurgy Manufacturing Methods in Automotive Industry

Erdem, Oğuz

doi:10.29137/umagd.349955

Cited by 5 publications

(4 citation statements)

References 19 publications

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“…Recently, PM methods have determined all the above-mentioned requirements, which will be the most common technique used for manufacturing many automotive parts [4][5]. PM engineering parts are in high international demand in the automotive sector due to their functional flexibility and cost benefits.…”

Section: Introductionmentioning

confidence: 99%

Recent Advances In Production of Automotive Industry’s Spare Parts By Powder Metallurgy

Elkady

2023

International Journal of Materials Technology and Innovation

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Powder metallurgy (PM) is a cutting-edge technique used for the manufacturing of spare parts out of metal, alloys, and composite powders with unique mechanical properties. Nowadays, PM manufactures more than 70% of the industrial spare parts. Due to its high productivity, ability to make more sophisticated shapes, and cost-benefit analysis. Production of items in net shape or nearly net shapes is possible. Iron, copper, and aluminum are the primary constituents of automotive spare parts. According to the European Aluminum Association (EAA), manufacturing automotive spare parts from aluminum has many advantages, e.g., the reduction of the vehicle's weight, which saves 0.6 liters of fuel per 100 km for every 100 kg. Using aluminum instead of steel in the production of automotive spare parts saves 300 kg weight with a weight of 1400 kg. This is more valid as it helps in the reduction of fuel consumption. Further decreases air pollution by about 20%. Cast iron was utilized in the manufacturing of brake systems in automobiles, but nowadays, more efforts are being made to replace heavy iron with lighter materials. So, by using PM, aluminum matrix composite (Al-MC) was utilized for the manufacturing of brake discs, brake drums, and other brake equipment with low density and superior mechanical properties. The purpose of this state of the art is to provide an overview of powder metallurgy techniques and their importance in the manufacturing and development of automotive spare parts in the automotive sector from the last century to the present.

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Section: Introductionmentioning

confidence: 99%

Recent Advances In Production of Automotive Industry’s Spare Parts By Powder Metallurgy

Elkady

2023

International Journal of Materials Technology and Innovation

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“…Powder metallurgy (PM) is a promising technology for the cost-effective production of near-net shape components across several engineering industries. PM steels find extensive applications in the automotive field, meeting the demand for complex and multifunctional parts, e.g., engine, transmission, brake, chassis and electromagnetic components [1][2][3][4]. On the industrial scale, PM steels can compete with conventional steels and are broadly employed in gear manufacturing, where wear, fatigue and dynamic resistance are crucial [5].…”

Section: Introductionmentioning

confidence: 99%

Microstructural Investigation and Impact Strength of Sinter-Hardened PM Steels: Influence of Ni Content and Tempering Temperature

Suman,

Fortini,

Vezzani

et al. 2023

Metals

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This study analyzed the influence of tempering treatment temperature on the microstructural and mechanical behavior of two different powder metallurgy steels containing 0 wt. % Ni and 4 wt. % Ni. The evolution of the microstructure and the macro- and microhardness of the microstructural constituents resulting from tempering treatments conducted on the sinter-hardened materials at temperatures ranging from 160 °C to 300 °C were investigated. The role of the tempering conditions in the impact behavior was assessed using Charpy tests on V-notched and unnotched samples, tempered at 180 °C, 220 °C and 280 °C. The observed macrohardness reduction with increasing tempering temperature was related to martensite transformations. At high tempering temperatures, the remarkable loss in impact energy values was attributed to microfracture modes. The contribution of Ni-rich austenite areas in enhancing impact strength was detected.

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“…In engine parts, the camshaft and crankshaft gears, the timing gears, gear type oil pumps, the water pump impellers, the distribution pulleys, the fuel pump parts, the flange distributor gears, swing arm supports and attachments, engine ears, valve weights, valve housing inserts, valve lift guides, stainless steel gas flap attachments, turbochargers and fuel injector parts can also be produced by PM methods. Besides that, in transmission parts, all major components of both semi-automatic and automatic transmissions: hubs, clutch plates, clutch plate bearings, synchromesh parts and many other components have recently been produced by the PM method (Erdem, 2017; Fujiki, 2001). PM method compared with conventional manufacturing methods (machining, casting and forging) has advantages such as low production costs, high tolerance and little need for secondary processing (Torralba et al , 2003), very low interface reactions between matrix and reinforcement (Ay et al , 2016), homogeneous particle distribution (Lim et al , 2003) and low processing temperatures (Ozyurek and Ciftci, 2011; Özyürek et al , 2010).…”

Section: Introductionmentioning

confidence: 99%

Wear behaviors at different temperatures of ZrO₂ reinforced A356 matrix composites produced by mechanical alloying method

Şimşek

Özyürek

Salman

2022

ILT

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Purpose The purpose of this study, the tribological behaviors at different temperatures of aluminium matrix composites (AMCs) with different amounts of ZrO2 added were investigated. Design/methodology/approach Aluminium graphite (A356/2 wt% graphite (solid lubricant)) composite powders prepared by adding four different amounts (3 wt%, 6 wt%, 9 wt% and 12 wt%) of Zirconia (ZrO2) to the matrix were mechanically alloyed for 4 h. Wear tests were conducted at five different temperatures (20 °C, 100 °C, 180 °C, 260 °C and 340 °C) and for three different sliding distances (53 m, 72 m and 94 m) on the pin-on-disc type wear tester. Findings Results of the study showed that the highest hardness and density value were measured for 12% ZrO2 added AMC material. Wear test results showed that weight loss increases with increasing temperature; weight loss decreases at all temperatures with the increasing amount of reinforcement in the matrix. Originality/value In this paper, the tribological properties of aluminium matrix composites produced by the mechanical alloying method by adding different amounts of ZrO2 were determined by simulating the tribological properties at different loads and temperatures.

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The Development and Applications of Powder Metallurgy Manufacturing Methods in Automotive Industry

Cited by 5 publications

References 19 publications

Recent Advances In Production of Automotive Industry’s Spare Parts By Powder Metallurgy

Recent Advances In Production of Automotive Industry’s Spare Parts By Powder Metallurgy

Microstructural Investigation and Impact Strength of Sinter-Hardened PM Steels: Influence of Ni Content and Tempering Temperature

Wear behaviors at different temperatures of ZrO₂ reinforced A356 matrix composites produced by mechanical alloying method

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The Development and Applications of Powder Metallurgy Manufacturing Methods in Automotive Industry

Cited by 5 publications

References 19 publications

Recent Advances In Production of Automotive Industry’s Spare Parts By Powder Metallurgy

Recent Advances In Production of Automotive Industry’s Spare Parts By Powder Metallurgy

Microstructural Investigation and Impact Strength of Sinter-Hardened PM Steels: Influence of Ni Content and Tempering Temperature

Wear behaviors at different temperatures of ZrO2 reinforced A356 matrix composites produced by mechanical alloying method

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Wear behaviors at different temperatures of ZrO₂ reinforced A356 matrix composites produced by mechanical alloying method