A numerical model to predict the powder–binder separation during micro‐powder injection molding

Islam, Sk Tanbir; Samanta, Sudip Kumar; Das, Santanu; Chattopadhyay, Himadri

doi:10.1111/jace.18401

Cited by 6 publications

(2 citation statements)

References 26 publications

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“…To alleviate the aforementioned problems, the injection gate was positioned so that it was pointed from the C part toward the B part as shown in Figure 2b. According to the proposed model about the influence of filling patterns on the powder-binder separation in powder injection molding, it was likely that binder separation would occur toward the side the gate pointed to [38][39][40]. Accordingly, the gate position used in this study was placed so that it pointed toward the A part, which would intentionally direct the unavoidable powder-binder separation to the end of the A part.…”

Section: Moldflow Analysismentioning

confidence: 99%

Moldflow Simulation and Characterization of Pure Copper Fabricated via Metal Injection Molding

et al. 2023

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Metal injection molding (MIM) is a representative near-net-shape manufacturing process that fabricates advanced geometrical components for automobile and device industries. As the mechanical performance of an MIM product is affected by green-part characteristics, this work investigated the green part of pure copper processed with MIM using the injection temperature of ~180 °C and injection pressure of ~5 MPa. A computational analysis based on the Moldflow program was proposed to simulate the effectivity of the process by evaluating the confidence of fill, quality prediction, and pressure drop of three distinctive regions in the green part. The results showed that the ring and edge regions of the green parts showed localized behavior, which was related to processing parameters including the position of the gate. A microstructural observation using scanning electron microscopy and a 3D X-ray revealed that both the surface and body matrix consisted of pores with some agglomeration of micro-pores on the edges and ring part, while any critical defects, such as a crack, were not found. A microhardness analysis showed that the three regions exhibited a reasonable uniformity with a slight difference in one specific part mainly due to the localized pore agglomeration. The simulation results showed a good agreement with the microstructures and microhardness data. Thus, the present results are useful for providing guidelines for the sound condition of MIM-treated pure copper with a complex shape.

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Section: Moldflow Analysismentioning

confidence: 99%

Moldflow Simulation and Characterization of Pure Copper Fabricated via Metal Injection Molding

et al. 2023

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“…The significance of the mass production of intricately downsized or micro-structured components has intensified in recent years. Micro-powder injection molding (µPIM), which is a modification of the powder injection molding (PIM) process, is a financially viable method of processing materials for the fabrication of ceramic and metallic micro-sized components [1][2][3]. Similarly to PIM, the µPIM process offers several advantages such as low production cost, excellent surface finishes, nominal post-production scrap, and outstanding mechanical properties [4][5][6][7][8][9].…”

Section: Introductionmentioning

confidence: 99%

Micro-Injection Molding and Debinding Behavior of Hydroxyapatite/Zirconia Bi-Materials Fabricated by Two-Component Micro-Powder Injection Molding Process

Basir,

Muhamad,

Sulong

et al. 2023

Materials

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The micro-scale joining of two different materials using two-component micro-powder injection molding (2C-µPIM) is an intriguing technique. The formation of defects in bi-materials at different processing stages makes this technique challenging. This study presents the fabrication of defect-free bi-material micro-parts containing hydroxyapatite (HA) and 3 mol% yttria-stabilized zirconia (3YSZ) via 2C-µPIM. Critical powder volume concentrations (CPVCs) of 61.7 vol% and 47.1 vol% were obtained for the HA and 3YSZ powders, respectively. Based on the CPVCs, the optimal loadings for the HA and 3YSZ powders were selected as 60 vol% and 45 vol%, respectively. The HA and 3YSZ feedstocks were prepared by separately mixing the optimal powder contents with low-density polyethylene (LDPE) and palm stearin binders. The feedstocks displayed pseudoplastic behavior, and the lowest ranges of viscosity for the HA and 3YSZ at a temperature of 180 °C were 157.1–1392.5 Pa·s and 726.2–985.5 Pa·s, respectively. The feedstocks were injected to produce green HA/3YSZ micro-sized components. It was found that a solvent debinding temperature of 70 °C removed 60.6% of the palm stearin binder from the sample. In the thermal debinding stage, the open channels that formed in the bi-material sample’s solvent debound at 70 °C and contributed to the removal of 93 to 95% of the binder system. When the debound bi-materials were sintered at 1300 °C, the highest relative density of 96.3% was obtained. The sintering operation revealed a linear shrinkage between 13 and 17% in the sintered HA/3YSZ micro-parts.

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Flow-induced defects during metal injection molding: Role of powder morphology

Sanetrnik,

Hausnerova,

Ponizil

et al. 2024

Physics of Fluids

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Owing to the quality issues of highly filled compounds used in metal injection molding, the current research is focused on intercepting flow-induced inhomogeneities in multiphase compounds resulting from the segregation of metal powder particles from (typically) three/four-component polymer binders, resulting in an unacceptable porosity of the final sintered metal parts. A recently developed nondestructive approach for quantifying the extent of these flow-induced defects was employed to study the effect of the size and shape of water- and gas-atomized 17-4PH stainless steel powders on segregation. This method combines scanning electron microscopy/energy dispersive x-ray spectroscopy with an in-house analytical tool. The results show a higher tendency of coarser particles (D50 of 20 μm) for flow-induced defects, while an irregular shape (water-atomized particles) reduces this unwanted phenomenon.

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A numerical model to predict the powder–binder separation during micro‐powder injection molding

Cited by 6 publications

References 26 publications

Moldflow Simulation and Characterization of Pure Copper Fabricated via Metal Injection Molding

Moldflow Simulation and Characterization of Pure Copper Fabricated via Metal Injection Molding

Micro-Injection Molding and Debinding Behavior of Hydroxyapatite/Zirconia Bi-Materials Fabricated by Two-Component Micro-Powder Injection Molding Process

Flow-induced defects during metal injection molding: Role of powder morphology

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