Characterization of Energy Absorption and Strain Rate Sensitivity of a Novel Elastomeric Polyurea Foam

Koohbor, Behrad; Blourchian, Aryan; Uddin, Kazi Zahir; Youssef, George

doi:10.1002/adem.202000797

Cited by 31 publications

(30 citation statements)

References 40 publications

(64 reference statements)

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“…Over the range of investigated load application regions, only two buckling modes are observed, those starting at 2α = 16 deg and 2α = 23 deg, which is mechanistically consistent with the results of the considered boundary conditions and shown experimentally by Shorter et al [7]. Such elastic deformation is highly desirable in polymeric foams because (1) it signifies recoverable deformation where the foam padding can sustain repeated loading (recently demonstrated experimentally by our group [13]), and (2) it implies large energy dissipation due to buckling to shunt the energy protecting human brains from a concussion in biomechanical impact scenarios [14].…”

Section: Effect Of Microcell Wallsupporting

confidence: 89%

Mechanics of Microspheres Reinforced Hollow Microcells

Youssef

Nacy

Huynh

2021

Journal of Applied Mechanics

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Emerging polymeric foams exhibiting unique microstructure of microspherical shells with reinforcing dense microspheres creates a new opportunity for impact-tolerant foam paddings in sport gears applications. This paper describes the static response of reinforced microcell consisting of an outer spherical shell and uniformly distributed microspheres while quantifying the stiffening effect. The distribution of the microspheres is illustrated using the Fourier series, allowing tuning of the reinforcing strategy. Expressions of the external and internal works are derived, whereas the Ritz energy method is adopted to calculate the deformations due to a compressive load distributed over a range of areas. Emphasis is given to the effect of the geometrical attributes of the microcell and the reinforcing microspheres on the resulting deformation response and stiffening effect. The framework is used to investigate the response of several case studies to elucidate the effects of relative radii ratio, reinforcement density, microcell wall thickness, and loading configurations on the stiffness. A new normalized strain energy parameter is introduced to simplify and accelerate the analysis while providing insights on the underpinnings of the observed buckling response. The results strongly suggest the viability of the newly discovered foam microstructure in managing static loads while providing an opportunity to strategically tune the mechanical response using the analytical framework presented herein.

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Section: Effect Of Microcell Wallsupporting

confidence: 89%

Mechanics of Microspheres Reinforced Hollow Microcells

Youssef

Nacy

Huynh

2021

Journal of Applied Mechanics

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“…Dynamic testing of the graded foam stacks was carried out using an instrumented drop weight tower (Figure a) by dropping a 723 g impactor from a height of 1000 mm. The utilized impact conditions subjected the graded samples to a nominal strain rate of ∼120 s –1 , determined based on the impact velocity (discussed in refs and ) and the original length of the foam stacks (∼37 mm). The transmitted impact force–time history was recorded using a sensor placed below the foam sample, which was then used to analyze the dynamic response of graded foam stacks.…”

Section: Methodsmentioning

confidence: 99%

“…The recorded images were postprocessed using the commercial DIC software Vic-2D (Correlated Solutions Inc., SC, USA) with subset, step, and strain filter sizes optimized for each case. The DIC parameter optimization process has been reported in detail in refs and .…”

Section: Methodsmentioning

confidence: 99%

“…The present study examines the role of interface adhesive properties on the mechanical response of bilayer density-graded polyurea foam structures. In recent years, polyurea foam has attracted a good amount of interest due to its hierarchical cellular network and semiclosed cellular structure in impact mitigation applications. ,, Polyurea shows an extended plateau area in stress–strain response. , The mechanical characterization of polyurea foams demonstrates a superior characteristic under both quasi-static and dynamic loading conditions. ,, The outstanding mechanical performance of polyurea foam under different loading conditions distinguishes it from other elastomeric cellular solids. , …”

Section: Introductionmentioning

confidence: 99%

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Tuning the Mechanical Behavior of Density-Graded Elastomeric Foam Structures via Interlayer Properties

et al. 2022

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The concept of density-graded foams has been proposed to simultaneously enhance strain energy dissipation and the load-bearing capacities at a reduced structural weight. From a practical perspective, the fabrication of density-graded foams is often achieved by stacking different foam densities. Under such conditions, the adhesive interlayer significantly affects the mechanical performance and failure modes of the structure. This work investigates the role of different adhesive layers on the mechanical and energy absorption behaviors of graded flexible foams with distinct density layers. Three adhesive candidates with different chemical, physical, and mechanical characteristics are used to assemble density-graded polyurea foam structures. The mechanical load-bearing and energy absorption performances of the structures are evaluated under quasi-static and dynamic loading conditions. Mechanical tests are accompanied by digital image correlation (DIC) analyses to study the local strain fields developed in the vicinity of the interface. Experimental measurements are also supplemented by model predictions that reveal the interplay between the mechanical properties of an adhesive interlayer and the macroscale mechanical performance of the graded foam structures. The results obtained herein demonstrate that the deformation patterns and macroscale properties of graded foam composites can be tuned by selecting different bonding agents. It is also shown that the proper selection of an adhesive can be a practical way to address the strength–energy dissipation dichotomy in graded structures.

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“…If the cells are completely devoid of cell walls, this type of open-cell foams can further be classified as reticulated foams. [1][2][3] Open-cell foams are porous, tortuous and permeable; they can be used in a variety of applications including energy absorption, [2][3][4] airborne sound absorption, [5,6] selective extraction, [7,8] and membrane. [9] When made with biodegradable and/or biocompatible materials, open-cell foams may also be used as bioscaffolds and drug-delivery carriers.…”

Section: Introductionmentioning

confidence: 99%

Scalable Fabrication of Microcellular Open‐Cell Polymer Foams

2021

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Open‐cell foams are foams with porous, interconnected cellular structure. This unique structure has given open‐cell foams the versatility to be used in different types of applications including acoustics, filtration, membranes, and bioscaffolds. Conventional open‐cell polymer foams comprise mainly thermosetting and/or crosslinked materials; such materials are difficult to process and have limited end‐product recyclability. This article presents a commercially viable molding process to fabricate open‐cell foams using noncrosslinked thermoplastic polypropylene (PP). Highly open‐cell and/or reticulated structures at an open‐cell content of 84% are attained. The strategies employed in molding of PP foam with high open‐cell degree include: 1) use of mold‐opening method to achieve high void fractions; 2) reduction of cell‐wall thickness through increasing the cell densities via controlled crystallization; and 3) use of low viscosity or low melt‐strength polymer resins to promote cell‐wall opening. The molding process proposed may be extended to other semicrystalline thermoplastic materials for fabricating recyclable open‐cell foams.

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Characterization of Energy Absorption and Strain Rate Sensitivity of a Novel Elastomeric Polyurea Foam

Cited by 31 publications

References 40 publications

Mechanics of Microspheres Reinforced Hollow Microcells

Mechanics of Microspheres Reinforced Hollow Microcells

Tuning the Mechanical Behavior of Density-Graded Elastomeric Foam Structures via Interlayer Properties

Scalable Fabrication of Microcellular Open‐Cell Polymer Foams

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