• Title/Summary/Keyword: Powder melting

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Production of Ni-Cr Metal Powder by Selective Laser Melting for Dentistry to Observation of Characteristics (치과 SLM용 Ni-Cr 금속분말 특성 관찰)

  • Hong, Minho
    • Journal of Technologic Dentistry
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    • v.37 no.1
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    • pp.23-29
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    • 2015
  • Purpose: The selective laser melting (SLM) process for dentistry, which is one of the additive manufacturing technologies (AM) allows for rapid production of a three-dimensional model with complex shape by directly melting metal powder. This process generates detailed items of a three-dimensional model shape through consolidation of a thin powder layer by utilizing both selective melting and laser beam simultaneously. In regard to SLM process, Fe-base powder, Ti-6AI-4V powder, AI-base powder, etc. have been researched. It is believed that the aforementioned technologies will be widely utilized in manufacturing metal parts using metal powder of raw material. This study chose Ni-Cr-Mo metal powder in order to manufacture metal powder materials that would be used in the selective laser melting for dentistry. Methods: This study manufactured metal powder using mechanical alloying technique (MA) among those metal powder manufacturing techniques. Moreover, this study aimed to utilize the metal powder manufactured after observing the characteristics of powder as preliminary data of Ni-Cr-Mo metal powder. This study could obtain the following conclusions within the experimental limitations. Results: As a result of mechanically alloying Ni-Cr-Mo powder over time, its mean particle size was $66.93{\mu}m$ $54.4{\mu}m$ and $45.39{\mu}m$ at 10h, 20h and 30h, respectively. The gtain form of metal powder by mechanical alloying technique was a sponge-like shape of irregular plate; however, the gtain form manufactured by high-pressure water aromization process had the following three types: globular type, chain type and oval type. Conclusion: This study found $37.65{\mu}m$ as the mean particle size of Ni-Cr-Mo metal powder, which was manufactured using water atomization technique under the following conditions: water atomization flux of 300 liter/min, hydraulic pressure of $400kgf/cm^2$ and injection angle of $45^{\circ}$. This study confirmed that the grain form of powder (solid particle form) would vary depending on the manufacturing process.

A study of size and frictional effect on the evolution of melting PartII: Twin screw extruder

  • Kim, D.S.;Lee, B.K.;Kim, H.S.;Lee, J.W.;C.G. Gogos
    • Korea-Australia Rheology Journal
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    • v.13 no.2
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    • pp.89-95
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    • 2001
  • Effects of particulate size and frictional characteristics were examined on the melting behavior of PP(polypropylene) in a twin screw extruder. Powder and pellet types of PP were used and each component was blended with PE(polyethylene) wax and clay, respectively. It was observed that small size particulates, 1.e. powder systems exhibit accelerated melting behavior; and it was also found that the abrasive auditive acts as an effective agent for fast melting of PP powder. Retardation of melting due to the reduced friction was observed in both types of PP, contrary to the result found in a batch mixer. The tendency observed in variation of torque and exit temperature was explained in terms of frictional effect and length of compacted region formed during evolution of melting.

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Effect of Powder Morphology on the Deposition Quality for Direct Laser Melting (Direct Laser Melting 공정시 분말 형태가 적층 품질에 미치는 영향)

  • Lee, S.H.;Kil, T.D.;Han, S.W.;Moon, Y.H.
    • Transactions of Materials Processing
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    • v.25 no.3
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    • pp.195-202
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    • 2016
  • Direct laser melting(DLM) is an additive manufacturing process that can produce parts by solidification of molten metallic powder layer by layer. The properties of the fabricated parts strongly depend on characteristics of the metallic powder. Atomized powders having spherical morphology have commonly been used for DLM. Mechanical ball-milling is a powder processing technique that can provide non-spherical solid powders without melting. The aim of the current study was to investigate the effect of powder morphologies on the deposition quality in DLM. To characterize the morphological effect, the performances of spherical and non-spherical powders were compared using both single- and multi-track DLM experiments. DLM experiments were performed with various laser process parameters such as laser power and scan rate, and the deposition quality was evaluated. The surface roughness, cross-section bead shape and process defects such as balling or non-filled area were compared and discussed in this study.

A Study of Size and Frictional Effects on the Evolution of Melting Part I : Batch Mixer (입자크기와 마찰효과가 용융 과정에 미치는 영향 Part I : 회분식 혼련기)

  • Kim, Dong-Sung;Park, Yung-Jin;Lee, Bong-Kyu;Kim, Hyung-Su;Lee, Jae-Wook
    • The Korean Journal of Rheology
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    • v.11 no.1
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    • pp.44-49
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    • 1999
  • Effects of particulate size and frictional characteristics were examined on the melting behavior of PP (polypropylene) in a batch mixer. Powder and pellet types of PP were used and each component was blended with PE (polyethylene) wax and clay, respectively. It was observed that small size particulates, i.e. powder systems exhibit accelerated melting behavior; and it was also found that the abrasive additive acts as an effective agent for fast melting of PP powder. Retardation of melting due to the reduced friction was observed in PP pellet/PE wax blends, while melting rate of PP powder was increased by addition of PE wax.

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Status Quo of Powder Bed Fusion Metal Additive Manufacturing Technologies (Powder Bed Fusion 방식 금속 적층 제조 방식 기술 분석)

  • Hwang, In-Seok;Shin, Chang-Seop
    • Journal of the Korean Society of Manufacturing Process Engineers
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    • v.21 no.7
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    • pp.10-20
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    • 2022
  • Recently, metal additive manufacturing (AM) is being investigated as a new manufacturing technology. In metal AM, powder bed fusion (PBF) is a promising technology that can be used to manufacture small and complex metallic components by selectively fusing each powder layer using an energy source such as laser or an electron beam. PBF includes selective laser melting (SLM) and electron beam melting (EBM). SLM uses high power-density laser to melt and fuse metal powders. EBM is similar to SLM but melts metals using an electron beam. When these processes are applied, the mechanical properties and microstructures change due to the many parameters involved. Therefore, this study is conducted to investigate the effects of the parameters on the mechanical properties and microstructures such that the processes can be performed more economically and efficiently.

Manufacture of Precsion Model Using Laser Melting Process (레이저 용융 적층 공정을 이용한 정밀 형상 제작)

  • 김재도;전병철;권택열;이영곤;신동훈
    • Laser Solutions
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    • v.3 no.3
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    • pp.21-29
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    • 2000
  • For the direct metal shape processing the powder feed device which is different from the widely used in rapid prototyping. is developed, The three dimensional object is shaped with the melting metal powder. The developed research has applied to rapid prototyping in ultraprecision for MEMS and medical science fields required of rapid manufacture of complex shape. The goal of this study make 3D model which has precision accuracy. Powder spreading apparatus has been more improved because that the control of powder spread is very important in layer manufacturing. It consists of the vibration motor, nozzle and tube which supplies various metal powder. This apparatus could control the spreading velocity that could control powder spreading thickness. Laser on/off switch was adapted because laser scanning velocity must be preserved constantly to prevent heat transformation of laser overheating. The error between sintered thickness md experimental one occurred by shrinkage in sintering melting process. The problem of heat transformation was solved by On/Off switching system.

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Alloy Design and Powder Manufacturing of Al-Cu-Si alloy for Low-Temperature Aluminum Brazing (저온 알루미늄 브레이징용 Al-Cu-Si-Sn 합금 설계 및 분말 제조)

  • Heeyeon Kim;Chun Woong Park;Won Hee Lee;Young Do Kim
    • Journal of Powder Materials
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    • v.30 no.4
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    • pp.339-345
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    • 2023
  • This study investigates the melting point and brazing properties of the aluminum (Al)-copper (Cu)-silicon (Si)-tin (Sn) alloy fabricated for low-temperature brazing based on the alloy design. Specifically, the Al-20Cu-10Si-Sn alloy is examined and confirmed to possess a melting point of approximately 520℃. Analysis of the melting point of the alloy based on composition reveals that the melting temperature tends to decrease with increasing Cu and Si content, along with a corresponding decrease as the Sn content rises. This study verifies that the Al-20Cu-10Si-5Sn alloy exhibits high liquidity and favorable mechanical properties for brazing through the joint gap filling test and Vickers hardness measurements. Additionally, a powder fabricated using the Al-20Cu-10Si-5Sn alloy demonstrates a melting point of around 515℃ following melting point analysis. Consequently, it is deemed highly suitable for use as a low-temperature Al brazing material.

Preparation of Low-Oxygen Ingot by Repetitive Melting and Mo Metal Powder by Hydrogen Reduction from $MoO_3$ Powder (삼산화 몰리브덴 분말로부터 수소 환원에 의한 금속 분말 및 반복 용해에 의한 저산소 잉곳 제조)

  • Lee, Back-Kyu;Oh, Jung-Min;Kim, Hyung-Seok;Lim, Jae-Won
    • Particle and aerosol research
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    • v.9 no.1
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    • pp.31-36
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    • 2013
  • In this study, Mo metal powder was prepared by hydrogen reduction of Mo trioxides with different purity of 2N and 3N grades. We have obtained Mo metal powder with oxygen content of 1450 ppm by hydrogen reduction and subsequent heat treatment for degassing. Using the Mo metal powder, a low-oxygen Mo ingot was prepared by repetitive vacuum arc melting. The oxygen content of the obtained Mo ingot was less than 70 ppm after vacuum arc melting for 30 min. The purity of the Mo metal powder and the ingot was evaluated using glow discharge mass spectrometry. The purity of the respective Mo ingots was increased to 3N and 4N grades from the Mo powder of 2N and 3N grades after the repetitive vacuum arc melting. The low oxygen Mo ingot thus can be used as a raw material for sputtering targets.

Laser Processing Technology using Metal Powders (금속분말의 레이저 공정 기술)

  • Jang, Jeong-Hwan;Moon, Young-Hoon
    • Korean Journal of Metals and Materials
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    • v.50 no.3
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    • pp.191-200
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    • 2012
  • The purpose of this paper is to review the state of laser processing technology using metal powders. In recent years, a series of research and development efforts have been undertaken worldwide to develop laser processing technologies to fabricate metal-based parts. Layered manufacturing by the laser melting process is gaining ground for use in manufacturing rapid prototypes (RP), tools (RT) and functional end products. Selective laser sintering / melting (SLS/SLM) is one of the most rapidly growing rapid prototyping techniques. This is mainly due to the processes's suitability for almost any materials, including polymers, metals, ceramics and many types of composites. The interaction between the laser beam and the powder material used in the laser melting process is one of the dominant phenomena defining feasibility and quality. In the case of SLS, the powder is not fully melted during laser scanning, therefore the SLS-processed parts are not fully dense and have relatively low strength. To overcome this disadvantage, SLM and laser cladding (LC) processes have been used to enable full melting of the powder. Further studies on the laser processing technology will be continued due to the many potential applications that the technology offers.

A FACILE METHOD FOR THE PRODUCTION OF Sn-Ag ALLOY BY HIGH ENERGY BALL MILLING

  • ASHUTOSH SHARMA;BYUNGMIN AHN
    • Archives of Metallurgy and Materials
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    • v.65 no.4
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    • pp.1329-1333
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    • 2020
  • In this study, we have developed Sn-Ag alloy by a simple high energy ball milling technique. We have ball-milled the eutectic mixture of Sn and Ag powders for a period of 45 h. The milled powder for 45 h was characterized for particle size and morphology. Microstructural investigations were carried out by scanning electron microscopy and X-ray diffraction studies. The melting behavior of 45 h milled powder was studied by differential scanning calorimetry. The resultant crystallite size of the Sn(Ag) solid solution was found to be 85 nm. The melting point of the powder was 213.6℃ after 45 h of milling showing depression of ≈6℃ in melting point as compared to the existing Sn-3.5Ag alloys. It was also reported that the wettability of the Sn-3.5Ag powder was significantly improved with an increase in milling time up to 45 h due to the nanocrystalline structure of the milled powder.