S.C. Shrivastava scite author profile

Nanocomposites obtained by casting a mixture of a latex and a n aqueous suspension of cellulose whiskers have been studied. Their mechanical properties (e.g. shear modulus) are found to increase by more than three orders of magnitude in the rubbery state of the polymer matrix, when the whisker content is 6 wt%. This large and unusual effect is discussed on the basis of different types of mechanical models, including semi-phenomenological and numerical finite element calculations. It is concluded that cellulose whiskers form a rigid network linked by hydrogen bonds. The formation of this network is assumed to be governed by a percolation mechanism.

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Stress Analysis of the Lumbar Disc-Body Unit in Compression A Three-Dimensional Nonlinear Finite Element Study

Shirazi-Adl

Shrivastava

Ahmed

1984

Spine

391

194

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Mechanical Response of a Lumbar Motion Segment in Axial Torque Alone and Combined with Compression

Shirazi‐Adl¹,

Ahmed²,

Shrivastava³

1986

Spine

415

186

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A finite element study of a lumbar motion segment subjected to pure sagittal plane moments

Shirazi‐Adl

Ahmed

Shrivastava

1986

Journal of Biomechanics

242

119

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Free and constrained inflation of elastic membranes in relation to thermoforming — non-axisymmetric problems

Charrier

Shrivastava

1989

The Journal of Strain Analysis for Engineering Design

130

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This paper deals with the inflation of elastic membranes of general shapes in the context of thermoforming of heated polymeric sheets against relatively cold moulding surfaces. A previous paper (1) has dealt with axisymmetric problems. As before, both theoretical and experimental investigations are reported. The theoretical part consists of a self-contained finite element formulation for large deformation, free and constrained inflation of isotropic elastic membranes. The computer program developed on the basis of presented formulation is applied to free and constrained inflation of plane elliptical membranes of aspect ratios 2 and 4. The material model adopted is that of a single constant neo-Hookean elastic material. The constrained analyses are carried out for inflation against: (a) cylindrical walls (90 degree elliptical cones), (b) 60 degree elliptical cones, and (c) horizontal plates. Separate analyses are performed by assuming the contact to be either slipless or frictionless. The theoretical results are compared with the experimental ones for free inflation and constrained inflation cases (a) and (c).

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S.C. Shrivastava

Mechanical percolation in cellulose whisker nanocomposites

Stress Analysis of the Lumbar Disc-Body Unit in Compression A Three-Dimensional Nonlinear Finite Element Study

Mechanical Response of a Lumbar Motion Segment in Axial Torque Alone and Combined with Compression

A finite element study of a lumbar motion segment subjected to pure sagittal plane moments

Free and constrained inflation of elastic membranes in relation to thermoforming — non-axisymmetric problems

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