Sintering graded foamed beads: Compressive properties

Errichiello, Fabrizio; Cammarano, Aniello; Maio, Ernesto Di; Nicolais, L.

doi:10.1002/app.52052

Cited by 6 publications

(4 citation statements)

References 29 publications

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“…[22] It has been exploited to produce samples with simple geometries, such as slabs or beads, and has proven to be efficient in targeting specific compressive properties of sintered foamed beads. [23] Accordingly, in the present work we introduce a novel procedure to design and produce a topologically optimized 3D gradedfoam structure through physical foaming. With the knowledge of the load conditions and constraints, as well as the mechanical properties of the expanded polymer, an optimized 3D density map is calculated with a topology optimization module within a finite element method (FEM) software.…”

Section: Doi: 101002/adem202301798mentioning

confidence: 99%

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Topologically Optimized Graded Foams

Iaccarino,

Maresca,

Morganti

et al. 2024

Adv Eng Mater

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The adoption of Nature‐inspired strategies to improve materials has fostered the introduction of cavities. But how to mass‐produce structures in which a complex architecture of cavities is point‐to‐point fine‐tuned to the local and global application requirements? To this aim, we herein report the use of a procedure based on topology optimization and gas foaming. As an example case, a polymeric foamed beam whose density map is optimized in 3D for three‐point bending was designed and produced by gas foaming a purpose‐designed preform. The preform was produced with polypropylene and by a high pressure autoclave with as blowing agent. Optical and scanning electron microscopy as well as X‐ray microscopy were used to analyze the 3D optimized foamed structures and showed the effectiveness of the foaming design protocol in producing the FEM‐optimized structures. A remarkable two‐fold increase in the stiffness of the optimized structures was measured with respect to that of the uniformly foamed counterpart with equal overall mass. With the use of a single recyclable material in a single processing step, this method allows one to conceive the mass production of optimized, therefore more sustainable, plastic parts.This article is protected by copyright. All rights reserved.

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Section: Doi: 101002/adem202301798mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Topologically Optimized Graded Foams

Iaccarino,

Maresca,

Morganti

et al. 2024

Adv Eng Mater

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“…A preliminary experiment reported the use of the method to achieve complex shapes endowed with morphological gradients, such as a 1:10 scale human femur. The authors adopted polystyrene as a model polymer and polycaprolactone for the femur, showing the versatility of the method for any foamable biomedical thermoplastic [ 70 , 71 , 72 , 73 , 74 ]. Most recently, the gas foaming method with time-varying boundary conditions has been coupled with additive manufacturing, providing additional versatility in terms of porosity architecture [ 75 ].…”

Section: Advanced Control Of Scaffold Architecturementioning

confidence: 99%

Current Trend and New Opportunities for Multifunctional Bio-Scaffold Fabrication via High-Pressure Foaming

Fanovich,

Di Maio,

Salerno

2023

JFB

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Biocompatible and biodegradable foams prepared using the high-pressure foaming technique have been widely investigated in recent decades as porous scaffolds for in vitro and in vivo tissue growth. In fact, the foaming process can operate at low temperatures to load bioactive molecules and cells within the pores of the scaffold, while the density and pore architecture, and, hence, properties of the scaffold, can be finely modulated by the proper selection of materials and processing conditions. Most importantly, the high-pressure foaming of polymers is an ideal choice to limit and/or avoid the use of cytotoxic and tissue-toxic compounds during scaffold preparation. The aim of this review is to provide the reader with the state of the art and current trend in the high-pressure foaming of biomedical polymers and composites towards the design and fabrication of multifunctional scaffolds for tissue engineering. This manuscript describes the application of the gas foaming process for bio-scaffold design and fabrication and highlights some of the most interesting results on: (1) the engineering of porous scaffolds featuring biomimetic porosity to guide cell behavior and to mimic the hierarchical architecture of complex tissues, such as bone; (2) the bioactivation of the scaffolds through the incorporation of inorganic fillers and drugs.

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“…Recently, some attempts have been made to prepare bead foam parts by synergizing the constrained expansion of foamed beads with simultaneous welding under high temperature conditions [23,[82][83][84]. Figure 11 shows the schematic of the in-mold foaming and molding (IMFM) process.…”

Section: In-mold Foaming and Molding (Imfm)mentioning

confidence: 99%

Polymer Bead Foams: A Review on Foam Preparation, Molding, and Interbead Bonding Mechanism

Jiang,

Wang,

Tian

et al. 2023

Macromol

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The diverse physical appearances and wide density range of polymer bead foams offer immense potential in various applications and future advancements. The multiscale and multilevel structural features of bead foams involve many fundamental scientific topics. This review presents a comprehensive overview of recent progress in the preparation and molding techniques of bead foams. Firstly, it gives a comparative analysis on the bead foam characteristics of distinct polymers. Then, a summary and comparison of molding techniques employed for fabricating bead foam parts are provided. Beyond traditional methods like steam-chest molding (SCM) and adhesive-assisted molding (AAM), emerging techniques like in-mold foaming and molding (IMFM) and microwave selective sintering (MSS) are highlighted. Lastly, the bonding mechanisms behind these diverse molding methods are discussed.

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Sintering graded foamed beads: Compressive properties

Cited by 6 publications

References 29 publications

Topologically Optimized Graded Foams

Topologically Optimized Graded Foams

Current Trend and New Opportunities for Multifunctional Bio-Scaffold Fabrication via High-Pressure Foaming

Polymer Bead Foams: A Review on Foam Preparation, Molding, and Interbead Bonding Mechanism

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