Compressive Stiffness of CFDST Columns

The compressive stiffness of articular cartilage was examined in oscillatory confined compression over a wide frequency range including high frequencies relevant to impact loading. Nonlinear behavior was found when the imposed sinusoidal compression amplitude exceeded a threshold value that depended on frequency. Linear behavior was attained only by suitable control of the compression amplitude. This was enabled by real time Fourier analysis of data which provided an accurate assessment of the extent of nonlinearity. For linear viscoelastic behavior, a stiffness could be defined in the usual sense. The dependence of the stiffness on ionic strength and proteoglycan content showed that electrostatic forces between matrix charge groups contribute significantly to cartilage’s compressive stiffness over the 0.001 to 20 Hz frequency range. Sinusoidal streaming potentials were also generated by oscillatory compression. A theory relating the streaming potential field to the fluid velocity field is derived and used to interpret the data. The observed magnitude of the streaming potential suggests that interstitial fluid flow is significant to cartilage behavior over the entire frequency range. The use of simultaneous streaming potential and stiffness data with an appropriate theory appears to be an important tool for assessing the relative contribution of fluid flow, intrinsic matrix viscoelasticity, or other molecular mechanisms to energy dissipation in cartilage. This method is applicable in general to hydrated, charged polymers.

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Theoretical Analysis and Finite Element Simulation of the Flat Compressive Stiffness of Oblique Column Reinforced Foam Sandwich Composites

IOP Conference Series Materials Science and Engineering ◽

10.1088/1757-899x/394/3/032107 ◽

2018 ◽

Vol 394 ◽

pp. 032107

Author(s):

Wei Liang ◽

Jingcheng Zeng ◽

Jinshui Yang ◽

Xiaohui Li ◽

Jianming Zhang

Keyword(s):

Finite Element ◽

Theoretical Analysis ◽

Finite Element Simulation ◽

Sandwich Composites ◽

Compressive Stiffness ◽

Element Simulation

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Compressive stiffness of staggered woodpile lattices: Mechanics, measurement, and scaling laws

International Journal of Mechanical Sciences ◽

10.1016/j.ijmecsci.2020.105932 ◽

2020 ◽

Vol 187 ◽

pp. 105932

Author(s):

Enrique Cuan-Urquizo ◽

Faezeh Shalchy ◽

Atul Bhaskar

Keyword(s):

Scaling Laws ◽

Compressive Stiffness

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Big influence of small random imperfections in origami-based metamaterials

Proceedings of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rspa.2020.0236 ◽

2020 ◽

Vol 476 (2241) ◽

pp. 20200236

Author(s):

Ke Liu ◽

Larissa S. Novelino ◽

Paolo Gardoni ◽

Glaucio H. Paulino

Keyword(s):

Numerical Simulations ◽

Mechanical Behaviour ◽

The Other ◽

Basic Pattern ◽

Geometric Imperfections ◽

Compressive Stiffness ◽

Compressive Response ◽

Other Hand

Origami structures demonstrate great theoretical potential for creating metamaterials with exotic properties. However, there is a lack of understanding of how imperfections influence the mechanical behaviour of origami-based metamaterials, which, in practice, are inevitable. For conventional materials, imperfection plays a profound role in shaping their behaviour. Thus, this paper investigates the influence of small random geometric imperfections on the nonlinear compressive response of the representative Miura-ori, which serves as the basic pattern for many metamaterial designs. Experiments and numerical simulations are used to demonstrate quantitatively how geometric imperfections hinder the foldability of the Miura-ori, but on the other hand, increase its compressive stiffness. This leads to the discovery that the residual of an origami foldability constraint, given by the Kawasaki theorem, correlates with the increase of stiffness of imperfect origami-based metamaterials. This observation might be generalizable to other flat-foldable patterns, in which we address deviations from the zero residual of the perfect pattern; and to non-flat-foldable patterns, in which we would address deviations from a finite residual.

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Effect of Spinal Level and Loading Conditions on the Production of Vertebral Burst Fractures in a Porcine Model

Journal of Biomechanical Engineering ◽

10.1115/1.4004917 ◽

2011 ◽

Vol 133 (9) ◽

Cited By ~ 5

Author(s):

Dominic Boisclair ◽

Jean-Marc Mac-Thiong ◽

Stefan Parent ◽

Yvan Petit

Keyword(s):

Porcine Model ◽

Loading Rate ◽

Burst Fracture ◽

Flexion Angle ◽

Spinal Level ◽

Compressive Stiffness ◽

Burst Fractures ◽

Load To Failure ◽

Canal Encroachment ◽

Full Factorial

Vertebral burst fractures are commonly studied with experimental animal models. There is however a lack of consensus as to what parameters are important to create an unstable burst fracture with a significant canal encroachment on such model. This study aims to assess the effect of the loading rate, flexion angle, spinal level, and their interactions on the production of a vertebral thoracolumbar burst fracture on a porcine model. Sixteen functional spinal units composed of three vertebrae were harvested from mature Yucatan minipigs. Two loading rates (0.01 and 500 mm/s), two flexion angles (0° and 15°), and two spinal levels (T11-T13 and T14-L2) were studied, following a full factorial experimental plan with one repetition. Compression was applied to each functional unit to create a vertebral fracture. The load-to-failure, loss of compressive stiffness, final canal encroachment, and fracture type were used as criteria to evaluate the resulting fracture. All specimens compressed without flexion resulted in burst fractures. Half of the specimens compressed with the 15° flexion angle resulted in compression fractures. Specimens positioned without flexion lost more of their compressive stiffness and had more significant canal encroachment. Fractured units compressed with a higher loading rate resulted in a greater loss of compressive stiffness. The spinal level had no significant effect on the resulting fractures. The main parameters which affect the resulting fracture are the loading rate and the flexion angle. A higher loading rate and the absence of flexion favors the production of burst fractures with a greater canal encroachment.

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Nucleus Implant Parameters Significantly Change the Compressive Stiffness of the Human Lumbar Intervertebral Disc

Journal of Biomechanical Engineering ◽

10.1115/1.1894369 ◽

2005 ◽

Vol 127 (3) ◽

pp. 536-540 ◽

Cited By ~ 19

Author(s):

Abhijeet Joshi ◽

Samir Mehta ◽

Edward Vresilovic ◽

Andrew Karduna ◽

Michele Marcolongo

Keyword(s):

Back Pain ◽

Intervertebral Disc ◽

Lower Back Pain ◽

Recent Trend ◽

Intervertebral Discs ◽

Geometric Parameters ◽

Synthetic Material ◽

Lumbar Intervertebral Disc ◽

Compressive Stiffness ◽

Lower Back

Nucleus replacement by a synthetic material is a recent trend for treatment of lower back pain. Hydrogel nucleus implants were prepared with variations in implant modulus, height, and diameter. Human lumbar intervertebral discs (IVDs) were tested in compression for intact, denucleated, and implanted condition. Implantation of nucleus implants with different material and geometric parameters into a denucleated IVD significantly altered the IVD compressive stiffness. Variations in the nucleus implant parameters significantly change the compressive stiffness of the human lumbar IVD. Implant geometrical variations were more effective than those of implant modulus variations in the range examined.

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Aging does not change the compressive stiffness of mandibular condylar cartilage in horses

Osteoarthritis and Cartilage ◽

10.1016/j.joca.2018.08.007 ◽

2018 ◽

Vol 26 (12) ◽

pp. 1744-1752 ◽

Cited By ~ 1

Author(s):

F. Mirahmadi ◽

J.H. Koolstra ◽

S. Fazaeli ◽

F. Lobbezoo ◽

G.H. van Lenthe ◽

...

Keyword(s):

Condylar Cartilage ◽

Compressive Stiffness ◽

Mandibular Condylar Cartilage

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Compressive stiffness of the cancellous bone of the canine proximal tibia

Journal of Biomechanics ◽

10.1016/0021-9290(93)90372-l ◽

1993 ◽

Vol 26 (3) ◽

pp. 287

Author(s):

Theodore L. Willke ◽

Dale R. Sumner ◽

Thomas M. Turner

Keyword(s):

Cancellous Bone ◽

Proximal Tibia ◽

Compressive Stiffness

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Mechanical behavior of walnut (Juglans regia L.) and cherry (Prunus avium L.) wood in tension and compression in all anatomical directions. Revisiting the tensile/compressive stiffness ratios of wood

Holzforschung ◽

10.1515/hf-2017-0053 ◽

2017 ◽

Vol 72 (1) ◽

pp. 71-80 ◽

Cited By ~ 2

Author(s):

Erik V. Bachtiar ◽

Markus Rüggeberg ◽

Peter Niemz

Keyword(s):

Prunus Avium ◽

Raw Materials ◽

Juglans Regia ◽

Longitudinal Direction ◽

Compressive Stiffness ◽

High Data ◽

Compression Properties ◽

Long Time ◽

Tension And Compression ◽

Cultural Heritage Objects

AbstractThe mechanical properties of walnut (Juglans regiaL.) and cherry (Prunus aviumL.) woods, as frequent raw materials in cultural heritage objects, have been investigated as a function of the anatomical directions and the moisture content (MC). The strength data are decreasing with increasing MC, whereas the tensile strength in the longitudinal direction is higher by factors of 1.5–2 compared to the compression strength. Moreover, the inequality of tensile and compressive stiffness is discussed, which is a matter of debate since a long time. This so-called bimodular behavior is difficult to describe in a generalized mode due to the high data variability if tension and compression properties are analyzed on different samples. If tensile and compressive stiffness tests are performed on the same samples of walnut and cherry wood, the ratio between these properties is significantly higher than 1.

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Electrostatic Contribution of the Proteoglycans to the In-Plane Shear and Compressive Stiffness of Corneal Stroma

ASME 2010 Summer Bioengineering Conference, Parts A and B ◽

10.1115/sbc2010-19191 ◽

2010 ◽

Author(s):

Hamed Hatami-Marbini ◽

Peter M. Pinsky

Keyword(s):

Extracellular Matrix ◽

Articular Cartilage ◽

Electrostatic Interactions ◽

Corneal Stroma ◽

Collagen Fibers ◽

Connective Tissues ◽

Compressive Stiffness ◽

Electrostatic Contribution ◽

Repulsive Forces

The extracellular matrix (ECM) is a fibrous structure embedded in an aqueous gel. The mechanical and electrostatic interactions of the ECM constituents, i.e. collagen fibers and proteoglycans (PGs), define the structure and mechanical response of connective tissues (CTs) such as cornea and articular cartilage. Proteoglycans are complex macromolecules consisting of linear chains of repeating gylcosaminoglycans (GAGs) which are covalently attached to a core protein. PGs can be as simple as decorin with a single GAG side chain or as complex as aggrecan with many GAGs. Decorin is the simplest small leucine-rich PG and is the main PG inside the corneal stroma. It has an arch shape and links non-covalently at its concave surface to the collagen fibrils. It has been shown that while collagen fibers inside the extracellular matrix resist the tensile forces, the negatively charged glycosaminoglycans and their interaction with water give compressive stiffness to the tissue. The role of PGs in biomechanical properties of the connective tissues has mainly been studied in order to explore the behavior of articular cartilage [1], which is a CT with large and highly negatively charged PGs, aggrecans. In order to explain the role of PGs in this tissue, it is commonly assumed that their contribution to the CT elasticity is because of both the repulsive forces between negatively charged GAGs and GAG interactions with free mobile charges in the ionic bath. The electrostatic contribution to the shear and compressive stiffness of cartilage is modeled by approximating GAGs as charged rods [1]. The Poisson-Boltzmann equation is used to compute the change in electrical potential and mobile ion distributions which are caused by the macroscopic deformation.

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