Microstructure and Hardness Evolution during Deformation near <i>A</i>e<sub>3</sub> in a Cr–Mn–Ti Gear Steel

Ma, Qiuchen; Xi-nan, Zhao; Meng, Dexu; Dong, Chaofang; Hou, Zhiwen; Misra, R.D.K.

doi:10.1002/srin.201800332

Cited by 9 publications

(7 citation statements)

References 37 publications

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“…When ferrite appears, the hardness decreases significantly. Hardness corresponds with the microstructure, and martensite fraction after quenching has a great influence on hardness, which aligns with the previous research results of Ahmed et al [27][28][29].…”

Section: Hardness Test and Microstructure Observationsupporting

confidence: 90%

The effect of TiN precipitated particles on the austenite grain and hardenability of 20CrMnTi gear steel

Cheng

et al. 2022

Ironmaking & Steelmaking

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To study the effect of TiN precipitated particles on two end-quenching specimens of 20CrMnTi steel with different hardenability characteristics, the peripheral hardness of the samples is tested. The microstructures, austenite grain structures, characteristics of TiN particles are analyzed. The larger the grain size, the higher the martensite fraction and the higher the hardness. More uniform and more refined grains reduce the maximum peripheral hardness difference of end-quenched samples from 9.1HRC to 3.3HRC. The precipitation of as much fine TiN as possible in the solid phase plays an important role in obtaining more refined and more uniform austenite grains. TiN precipitates less during solidification and more in the solid phase in the sample with better hardenability, promoting grain refinement and more uniform peripheral hardness. In production, with a specific mass fraction of Ti, effectively inhibiting the precipitation of coarse TiN during solidification is the key to control narrow hardenability bandwidth for 20CrMnTi gear steel.

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Section: Hardness Test and Microstructure Observationsupporting

confidence: 90%

The effect of TiN precipitated particles on the austenite grain and hardenability of 20CrMnTi gear steel

Cheng

et al. 2022

Ironmaking & Steelmaking

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“…These maps represent local orientation gradients. Thus, low LAM values indicate grains with relatively low GND density (depicted by blue) and high LAM values -increased GND density (represented by green and red) [20][21][22]. In the samples processed by a thermal cycle of welding, the parent austenite grains were identified using the ARPGE program [23].…”

Section: Structure Characterizationmentioning

confidence: 99%

Effect of heat treatment on the mechanical properties and microstructure of HSLA steels processed by various technologies

Zavdoveev¹,

Poznyakov²,

Baudin³

et al. 2021

Materials Today Communications

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This study presents a striking advance in investigating the influence of heat treatment on the microstructure and properties of high strength low-alloyed steels obtained using various technologies. In contrast to the normalization treatment, the application of the thermo-mechanical control process (TMCP) offers higher strength characteristics but less stable properties during consequent high-temperature heat treatment. It has been established that the mechanical properties of both the steels are stable up to 650 °C. With an increase in the treatment temperature, the mechanical properties of the TMCP steel (grade S460M) are strongly degraded, while the normalized steel (grade S355J2) remains stable up to 950 °C. This is attributed to intensive grain growth at a temperature higher than Ac3 for TMCP steel and to the microstructural stability of the normalized steel. It is shown that the structural stability during high-temperature heat treatment is controlled by a number of factors such as heating temperature and holding time, grain growth, accumulated strain, the presence of deformation texture, steel deoxidation, and dissolution/uncontrolled growth of precipitations.

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“…TC4 (Ti-6Al-4V) alloy is a (α+β) two-phase titanium alloy. It has the advantages of high specific strength, high temperature resistance, corrosion resistance and matching with composite materials, so it is widely used in military, aerospace, navigation, medicine, chemical and other fields [2,3] . Titanium alloy has the characteristics of poor thermal conductivity and easy reaction with tool material at high temperature.…”

Section: Introductionmentioning

confidence: 99%

Optimization analysis of processing parameters for high efficiency wire cutting of TC4 alloy gear in space transmission mechanism

Yang,

Zhang,

Wang

et al. 2023

Ninth International Conference on Mechanical Engineering, Materials, and Automation Technology (MMEAT 2023)

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Titanium alloy has many advantages such as high Strength ratio and low density, and is widely used in space transmission mechanism. However, titanium alloy has poor wear resistance, poor high-temperature oxidation resistance and sensitive surface stress concentration, which leads to difficult grinding of titanium alloy gears and easy to destroy the surface. In addition, the space transmission mechanism has high lightweight requirements, and the gear structure has many lightweight treatments such as thin wall and hole digging, resulting in low overall gear stiffness. When machining, the cutting force is large, and the overall structure of the gear is at great risk of deformation. Therefore, it is proposed to use wire cutting to process titanium alloy gears, and to improve the processing efficiency by processing multiple gears at the same time. By means of orthogonal test, the effects of Processing voltage (OV), Discharge time (ON), Quiescent time (OFF) and Line feed (WF) on the tooth surface roughness were studied, and the optimal parameter combination was obtained: Processing voltage (OV) is 90V, Discharge time (ON) is 550ns, Quiescent time (OFF) is 10 μs and Line feed (WF) is level7. This scheme can meet the requirements of the quality of the tooth surface roughness and the machining efficiency at the same time.

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Microstructure and Hardness Evolution during Deformation near Ae₃ in a Cr–Mn–Ti Gear Steel

Cited by 9 publications

References 37 publications

The effect of TiN precipitated particles on the austenite grain and hardenability of 20CrMnTi gear steel

The effect of TiN precipitated particles on the austenite grain and hardenability of 20CrMnTi gear steel

Effect of heat treatment on the mechanical properties and microstructure of HSLA steels processed by various technologies

Optimization analysis of processing parameters for high efficiency wire cutting of TC4 alloy gear in space transmission mechanism

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Microstructure and Hardness Evolution during Deformation near Ae3 in a Cr–Mn–Ti Gear Steel

Cited by 9 publications

References 37 publications

The effect of TiN precipitated particles on the austenite grain and hardenability of 20CrMnTi gear steel

The effect of TiN precipitated particles on the austenite grain and hardenability of 20CrMnTi gear steel

Effect of heat treatment on the mechanical properties and microstructure of HSLA steels processed by various technologies

Optimization analysis of processing parameters for high efficiency wire cutting of TC4 alloy gear in space transmission mechanism

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Microstructure and Hardness Evolution during Deformation near Ae₃ in a Cr–Mn–Ti Gear Steel