• Title/Summary/Keyword: carburizing

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Heat Transfer Analysis in the Vacuum Carburizing Furnace (진공 침탄로 내의 전열 해석)

  • Lee, In-Sub;Ryou, Hong-Sun;Kim, Won-Bae;Yang, Je-Bok
    • Transactions of the Korean Society of Mechanical Engineers B
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    • v.27 no.7
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    • pp.877-882
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    • 2003
  • The main objective of the present study is to analyze the heat transfer characteristics in the vacuum carburizing furnace. Local temperatures are measured at different locations in the self-fabricated furnace for various operating conditions using K-type thermocouples. In addition, the present study simulates the fluid flows and heat transfer in the vacuum carburizing furnace using a commercial package (Fluent V. 6.0), and compares the predictions of local temperatures with experimental data. The temperature and flow fields are predicted. It is found that the time taken for reaching the steady-state temperature under the vacuum pressure is shorter than that under the normal pressure condition. It means that the carburizing furnace under vacuum pressure condition is capable of saving the required energy more efficiently than the furnace under the normal pressure condition. Furthermore, the temperature variations predicted by the numerical simulations are in good agreement with experimental data.

The Fatigue Life Evaluation of Gas Nitro-Carburizing Material (침탄질화처리재의 피로수명평가)

  • 송삼홍;이상훈
    • Proceedings of the Korean Society of Precision Engineering Conference
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    • 1995.04b
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    • pp.39-44
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    • 1995
  • The gas nitro-carburizing treatment with the merits of carburizing and nitriding treatment is recently applied to transmission gears. the shafls of an engine oil pump and steering shafls. For all that, the researches of the gas nitro-carburizing treatment are short of the fatigue behavior and the evaluation of fatigue life. In this paer, it is examined for the effect of inclusions and hole defects with fatigue limit and the evaluation of the fatigue strengthaccording tothe hardness and resifualstress with the specimen of a notro-carburizing treatment.

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Microstructure and Effective Case Depth of the Vacuum Carburized Steels (진공침탄열처리강의 조직 및 유효경화깊이)

  • Choi, Y.T.;Byoun, S.K.
    • Journal of the Korean Society for Heat Treatment
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    • v.5 no.1
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    • pp.32-40
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    • 1992
  • This content is a part of the results of the study on the development of the vacuum carburizing technology. In this study the vacuum carburizing furnace being used was the furnace that developed through the joint project between KIMM and Kyung-Pook Heat Treating Co. from June 1988 to Nov. 1990. And the used carburizing gas was the propane gas and the introducing methods of the gas applied two methods such as pulse and constant pressure. By this study we established the basis of the furnace manufacturing technology and of the processing technology in the vacuum carburizing. Above all in this work there are notable meanings in a viewpoint of the foremost research in home. Hereafter, we are going to industrialize the vacuum carburizing technology by improving the results of the present work and by developing the process for the mass production.

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Enhancement of Surface Hardness and Corrosion Resistance of AISI 310 Austenitic Stainless Steel by Low Temperature Plasma Carburizing Treatment

  • Lee, Insup
    • Journal of Surface Science and Engineering
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    • v.50 no.4
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    • pp.272-276
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    • 2017
  • The response of AISI 310 type austenitic stainless steel to the novel low temperature plasma carburizing process has been investigated in this work. This grade of stainless steel shows better corrosion resistance and high temperature oxidation resistance due to its high chromium and nickel content. In this experiment, plasma carburizing was performed on AISI 310 stainless steel in a D.C. pulsed plasma ion nitriding system at different temperatures in $H_2-Ar-CH_4$ gas mixtures. The working pressure was 4 Torr (533Pa approx.) and the applied voltage was 600 V during the plasma carburizing treatment. The hardness of the samples was measured by using a Vickers micro hardness tester with the load of 100 g. The phase of carburized layer formed on the surface was confirmed by X-ray diffraction. The resultant carburized layer was found to be precipitation free and resulted in significantly improved hardness and corrosion resistance.

Development of High Performance Low Pressure Carburizing System (Batch type 가스침탄 열처리로 국산화개발)

  • Kim, Won-Bae;Dong, Sang-Keun;Jang, Byoung-Lok;Han, Hyoung-Ki;Kim, Han-Suck;Cho, Han-Chang
    • Journal of the Korean Society for Heat Treatment
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    • v.19 no.5
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    • pp.262-269
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    • 2006
  • The development of eco-friendly low pressure carburizing system with high pressure gas quenching(LPC-GQ, 500kg/charge) led to new stage in the fundamental case-hardening treatments. This is due to its ability to provide tighter tolerances on the carburizing process with notable reductions in distortion of the carburized and hardened workpiece. This system is characteristics by high uniformity and reproducibility of heat treatment results, absence of an intergranular oxidation layer, carburizing of complex shapes, reduced cycle time, low operating costs, simplified production, eliminate post washing, and reduced grinding costs.

Effect of Carburizing Heat Treatment Process on Microstructure and Residual Stress Changes in AISI 9310 Steel. (AISI 9310강의 침탄열처리 경로가 조직 및 잔류응력 변화에 미치는 영향)

  • Youngchul Jeong;Joohyeon Bae;Jaeman Park;Seungjun OH;Janghyun Sung;Yongsig Rho
    • Journal of the Korean Society for Heat Treatment
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    • v.37 no.3
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    • pp.128-137
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    • 2024
  • In this study, the carburizing heat treatment process used in aircraft gear manufacturing was compared with the general carburizing heat treatment process using AISI 9310 steel. The process of carburizing followed by slow cooling, and then quenching after austenitizing(Process A) showed less compressive residual stress and less retained austenite in the surface layer compared to the process of quenching directly after carburizing(Process B). In prpcess B, there was a large amount of retained austenite when quenched immediately after carburization, and when treated with subzero, martensite rapidly increased and the compressive residual stress increased significantly, but at the same time, there is a risk of cracking due to severe expansion in volume. Therefore, in the case of aviation parts, it is believed that a step-by-step heat treatment cycle was adopted to ensure stability against heat treatment cracks. As a result of the final tempering after sub-zero treatment, the A process specimen showed a deeper effective case depth and HV700 depth and a higher hardness value above HV700 than the B process specimen.

A Study on Setting up Condition of Treatment for Vacuum Carburizing (진공침탄을 위한 처리조건 설정에 관한 연구)

  • Lee, Sang-Gill;Kang, Sun-Bae;Jung, Byong-Ho;Kim, Han-Goon
    • Journal of the Korean Society for Heat Treatment
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    • v.5 no.4
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    • pp.195-200
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    • 1992
  • SCM 415 has been vacuum carburized in the carburizing pressure of 60-65kpa and the carburizing temperature of 1233k and 1273k after varied to 0-20 in the ratio of $N_2/C_3H_8$ and then diffusion treated for various times at 1123k. The results obtained from the experiment are as follows. 1. With increasing from 0 to 20 in ratio of $N_2/C_3H_8$ the sooting formation of surface after carburizing considerably decreased. 2. The hardness control and surface carbon content of carburizing surface has been modified by the addition of nitrogen to the propan. 3. The appoximate value of k is indirectry calculated at 1123k which results are obtained to $0.58{\times}10^{-2}(wt.%.S^{-1/2})$. 4. A great deal of propan by addition of nitrogen gas in carburizing gas was possible to saving without considerable change in case hardening depth. 5. The effective carburizing depth range is obtained to 0.8-1.1mm by diffusion temperature of 1123k after carburization at 1273k-3.6ks, and the surface hardness is increased as the increasing of $T_D/T_c$ in our experimental condition, and the maximum hardness as reachin distance from surface is decreased.

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Influence of Acetylene Pressure of Low-Pressure Carburization on the Carburizing Properties of AISI 4120 steel (진공 침탄에서 아세틸렌 압력이 AISI 4120 강의 표면 물성에 미치는 영향)

  • Gi-Hoon Kwon;Yun-Ho Son;Young-Kook Lee;Kyoungil Moon
    • Journal of the Korean Society for Heat Treatment
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    • v.37 no.5
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    • pp.228-236
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    • 2024
  • Low pressure carburizing is an industrially adopted process to modify the mechanical properties of the iron surface. Since acetylene gas is used as a carbon source, it has excellent carbon absorption and uniform carburizing layer compared to other carburizing gas. The superiority of carburizing properties is determined by the selection of process parameters such as acetylene flow rate and process pressure. The the effects of the pressure of acetylene as a carburizing gas on carbon transfer and surface properties of carburized specimen. AISI 4120 steel was carburized using pure acetylene at flow rates of 10, 30 sccm and pressure conditions of 1, 5, 10, 15, 20 torr. In order to investigate the carbon behavior according to the acetylene pressure, the mass gain of carbon was measured and the abnormal structure formed on the surface was observed. With the experimental results, Abnormal layers such as soot and cementite were not observed on the surface of the carburized specimens under the 10 sccm condition, and there was no significant difference in carburizing properties according to pressure. On the other hand, as the pressure increased under the condition of 30 sccm, the cementite fraction increased, and soot was formed from 15 torr, reducing the overall hardness gradient.

Analysis of the Carburizing Heat Treatment Process for SNCM Alloy Steel Using the Finite Element Method (유한요소법을 이용한 SNCM 합금강의 침탄열처리 공정 해석)

  • Choi S.C.;Lee D.J.;Kim H.Y.;Kim H.J.
    • Transactions of the Korean Society of Mechanical Engineers A
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    • v.30 no.10 s.253
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    • pp.1284-1292
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    • 2006
  • Heat treatment is a controlled heating and cooling process to improve the physical and/or mechanical properties of metal products without changing their shapes. Today finite element method is widely used to simulate lots of manufacturing processes including heat treatment and surface hardening processes, which aims to reduce the number of time- and cost-consuming experimental tryouts. In this study we tried, using this method, to simulate the full carburizing process that consists of carburizing, diffusing and quenching, and to predict the distribution of carbon contents, phase fraction and hardness, thermal deformation and other mechanical characteristics as the results. In the finite element analysis deformation, heat transfer, phase transformation and diffusion effects are taken into consideration. The carburizing process of a lock gear, a part of the car seat recliner, that is manufactured by the fine blanking process is adopted as the analysis model. The numerical results are discussed and partly compared with experimental data. And a combination of process parameters that is expected to give the highest surface hardness is proposed on the basis of this discussion.

Influence of Super Carburization on the Roller Pitting Fatigue Life of 0.16C-0.60Si-2.00Cr-0.34Mo Steel (0.16C-0.60Si-2.00Cr-0.34Mo강의 피팅강도에 미치는 고탄소 침탄의 영향)

  • Shin, Jung-Ho;Lee, Woon-Jae;Kim, Young-Pyo;Ko, In-Yong
    • Korean Journal of Metals and Materials
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    • v.50 no.7
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    • pp.517-522
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    • 2012
  • In this study, a super carburizing treatment was applied to improve roller pitting fatigue life. It produced excellent properties of surface hardness and temper softening resistance by forming precipitation of fine and spherodized carbides on a tempered marstensite matrix through the repeated process of carburization and diffusion after high temperature carburizing step 1. The cycle II performed two times carburizing/diffusion cycle (process) after super carburization at $1,000^{\circ}C$ had fine and spherodized carbides to subsurface $200{\mu}m$. In this case, the carbide was $(Fe,Cr)_3C$ and there was not any massive carbides. In the case of Cycle II, the roller pitting fatigue life had a 6.15 million cycles. It was improved 48% compared to normal gas carburizing treatment.