Yoko Hirono scite author profile

Selective laser melting (SLM) is one of the additive manufacturing (AM) methods which is applicable to metal. This technique makes it possible to form complex internal shapes such as lattice structures. The lattice structure is expected to have weight reduction and vibration suppression effects on the product. In addition, a support structure is essential for the SLM fabrication process, which has the role of supporting the product and dissipating heat from the product. However, steep temperature gradients due to local laser irradiation and non-uniform heat conduction during the process can cause bending and cracking of the product. In particular, the support structure and lattice structure consisting of thin metal struts are greatly affected by process conditions, so it is necessary to select conditions suitable for stable and high-precision modeling. In this study, the influence of laser power and scanning speed on the mechanical characteristics of the support structure and lattice structure formed by SLM is investigated. In the tensile test of the support structure, a positive correlation with the volumetric energy density was confirmed, and suitable laser conditions were examined. In the compression test of the lattice structure, it was clear that the amount of energy absorption changed depending on the laser power, and the condition of 240 W achieved the maximum energy absorption.

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Optimization of process parameters for hardness in high speed coating by Directed Energy Deposition

Satoh

Koike²,

Kakinuma³

et al. 2022

Procedia CIRP

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Powder velocity-based nozzle design for directed energy deposition

TAKEMURA

Koike

Kakinuma

et al. 2021

LEM21

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Cracking suppression by substrate preheating using an induction heater in directed energy deposition

Hirono¹,

Mori²,

Ueda³

et al. 2023

JAMDSM

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The applications of wear resistant material coatings or claddings by directed energy deposition (DED) are rapidly increasing in industrial engineering fields. DED allows us the use of non-expensive substrate materials and add functional materials such as Co-based superalloys on them. However, depending on the deposition parameters, cracks can easily occur on the workpiece. The determination of the appropriate deposition parameters is crucial because it is still difficult to predict and to control cracking. This paper discusses the effect of substrate preheating by an induction heater on the crack generation for DED of Co-based superalloys. An induction heater was adopted for its high efficiency, low waste heat and ability to quickly induce a high temperature in the workpiece directly. The material used in this study is Stellite® 1, which is widely used for die cut rolls or screw shafts. To investigate the effect of the preheating, experiments were conducted by changing the process parameters: preheating temperature and laser power. Sufficient hardness of 642 HV was obtained without cracking when the preheating temperature was 500 ℃ and the laser power was 1750 W. Although cracking did not occur when the preheating temperature or the laser power was higher, the hardness decreased. There is a trade-off between hardness and crack occurrence. This trade-off is considered to be influenced by thermal stress and the precipitation amount of chromium carbides, which are hard and brittle materials. The amount of chromium carbide precipitation is affected by the cooling rate of the deposited material. In addition, a higher cooling rate may result in greater thermal stress.

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Yoko Hirono

Automatic Chip Detection Using Differnet

Mechanical property evaluation of the SLM support structure and lattice structure of SUS316L

Optimization of process parameters for hardness in high speed coating by Directed Energy Deposition

Powder velocity-based nozzle design for directed energy deposition

Cracking suppression by substrate preheating using an induction heater in directed energy deposition

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