Study on the Gas Release of 3D-Printed Furan Resin Sand Core during the Casting Process

Wang, Xiaolong; Wu, Qing; Huang, Yuhang; Li, Na; Wu, Xiaohong; Chen, Xiuming; Kang, Jinwu; Jing, Tao; Huang, Tianqiang; Wang, Jiwu

doi:10.3390/ma16114152

Cited by 3 publications

(2 citation statements)

References 17 publications

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Section: Introductionmentioning

confidence: 99%

“…A good gas permeability reduces the metal filling resistance and can reduce the porosity defects on the surface, thus improving the quality of the castings. Wang et al [18] compared the exhaust speed of blind and hollow sand cores and found that the peak speed of the former was 1.10 m/s, which is lower than that of the latter, 1.89 m/s. Moreover, scholars have recently initiated studies on hollow sand molds, investigating the correlation between hollow structures and the performance of 3D-printed sand molds.…”

Section: Introductionmentioning

confidence: 99%

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Study on the Mechanical Properties of 3D-Printed Sand Mold Specimens with Complex Hollow Structures

Xu,

Kang,

et al. 2024

Materials

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Casting, as a fundamental process in metal forming, finds widespread applications in the manufacturing industry. The advent of 3D printing hollow sand mold technology presents a novel method for casting technology to revolutionize traditional dense sand molds, offering increased flexibility in achieving quality control and improvement in casting processes. Consequently, this study delves into an examination of the mechanical strengths of 3D-printed sand molds with complex hollow structures and further investigates the influence of hollow sand mold concession on castings. The results indicate that compressive and high-temperature residual tensile and bending strengths vary in hollow structures. Multi-layer shells have greater high-temperature residual tensile, compressive, and bending strengths than truss hollow sand molds with roughly the same hollow volume fraction. Compared to dense sand molds, hollow sand molds, which have a lower mechanical strength, have better retractability, which helps reduce the residual stress and crack tendency of castings. The breaking of hollow structures is limited to local areas, unlike the penetrative cracking of dense sand molds. The I-beam-shaped casting test results indicate that a hollow structure is beneficial for the preservation of the integrity of a sand mold during the casting process. Compared to dense and truss hollow molds, a multi-layer shell hollow sand structure has the comprehensive advantages that it improves retractability while maintaining strength relatively well, reduces the residual stress, and avoids cracks in castings and itself.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Study on the Mechanical Properties of 3D-Printed Sand Mold Specimens with Complex Hollow Structures

Xu,

Kang,

et al. 2024

Materials

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A P/N/S containing flame retardant for epoxy resins with excellent optical, mechanical and flame retardant properties

Jiang,

Chen,

Luo

et al. 2024

Polymer Degradation and Stability

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The Influence of 3D Printing Core Construction (Binder Jetting) on the Amount of Generated Gases in the Environmental and Technological Aspect

Bobrowski,

Woźniak,

Żymankowska-Kumon

et al. 2023

Materials

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This article presents the findings of a study focusing on the gas generation of 3D-printed cores fabricated using binder-jetting technology with furfuryl resin. The research aimed to compare gas emission levels, where the volume generated during the thermal degradation of the binder significantly impacts the propensity for gaseous defects in foundries. The study also investigated the influence of the binder type (conventional vs. 3D-printed dedicated binder) and core construction (shell core) on the quantity of gaseous products from the BTEX group formed during the pouring of liquid foundry metal into the cores. The results revealed that the emitted gas volume during the thermal decomposition of the organic binder depended on the core sand components and binder type. Cores produced using conventional methods emitted the least gases due to lower binder content. Increasing Kaltharz U404 resin to 1.5 parts by weight resulted in a 37% rise in gas volume and 27% higher benzene emission. Adopting shell cores reduced gas volume by over 20% (retaining sand with hardener) and 30% (removing sand with hardener), presenting an eco-friendly solution with reduced benzene emissions and core production costs. Shell cores facilitated the quicker removal of gaseous binder decomposition products, reducing the likelihood of casting defects. The disparity in benzene emissions between 3D-printed and vibratory-mixed solid cores is attributed to the sample preparation process, wherein 3D printing ensured greater uniformity.

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Study on the Gas Release of 3D-Printed Furan Resin Sand Core during the Casting Process

Cited by 3 publications

References 17 publications

Study on the Mechanical Properties of 3D-Printed Sand Mold Specimens with Complex Hollow Structures

Study on the Mechanical Properties of 3D-Printed Sand Mold Specimens with Complex Hollow Structures

A P/N/S containing flame retardant for epoxy resins with excellent optical, mechanical and flame retardant properties

The Influence of 3D Printing Core Construction (Binder Jetting) on the Amount of Generated Gases in the Environmental and Technological Aspect

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