Sage Journals: Discover world-class research

Abstract

The present investigation deals with the study of effect of change in angle of inclined forces at an interface of a viscous fluid/generalized thermoelastic micropolar honeycomb medium. The inclined load is assumed to be a linear combination of normal load and tangential load. The method of potential function, together with the application of integral transforms, has been applied to obtain the expressions of stresses and temperature distribution in the transformed domain. A particular type of boundary condition has been taken to illustrate the utility of the approach in three different cases, namely, time domain, frequency domain, and steady state, with the appropriate change of variables. A numerical inversion technique to invert the integral transforms is used on the transformed solution. The effect of micropolarity and change in angle of inclination is shown graphically owing to the response of different forces. Some particular cases of interest are also discussed.

Keywords

viscous fluid generalized thermoelastic medium inclined load time harmonic steady state

Get full access to this article

View all access options for this article.

References

Eringen

A. C.

Theory of micropolar elasticity. In Fracture II (Ed. Liebowitz

), 1968, Ch. 7, p. 621 (Academic Press, New York).

Wang

X. L.

Stronge

W. J.

Micropolar theory for two-dimensional stresses in elastic honeycomb

Proc. R. Soc. Lond. 455 (1999 2091–2116

Triplett

M. H.

Schonberg

W. P.

Static and dynamic finite element analysis of honeycomb structure

J. Struct. Engng Mech. 6 (1998 95–113

Chung

Waas

A. M.

Elastic imperfection sensitivity of hexagonally packed circular-cell honeycombs

Proc. R. Soc. Lond. 458 (2002 2851–2868

Huang

F. Y.

Yan

B. H.

Yang

D. U.

The effects of material elastic honeycomb structure with negative Poisson's ratio using the finite element method

Engng Computations 19 (7) (2002 742–763

Liang

Chen

H. L.

Investigation on the square cell honeycomb structure under axial loading

J. Composite Structs 42 (4) (2006 446–454

10.

Chung

Waas

A. M.

The micropolar elasticity constants of circular cell honeycombs

Proc. R. Soc. Lond. 465 (2101) (2009 25–39

11.

Yang

D. U.

Huang

F. Y.

Analysis of Poisson's ratio for a micropolar elastic rectangular plate using the finite element method

J. Engng Computations 18 (7–8) (2001 1012–1030

12.

Green

A. E.

Lindsay

K. A.

Themoelasticity

J. Elasticity 2 (1972 1–5

13.

Fehler

Interactions of seismic waves with a viscous liquid layer

Bull. Seismol. Soc. America 72 (1982 55–72

14.

15.

Kumar

Ailawalia

Elastodynamics of inclined loads in a micropolar cubic crystal

Mechanics and Mech. Engng 9 (2) (2005 57–75

16.

Gauthier

R. D.

Mechanics of micropolar media. In Experimental investigations on micropolar media (Eds Brulin

Hsieh

R. K. T.

), 1982 (World Scientific, Singapore).

17.

The response owing to inclined forces at an interface of a viscous fluid and a generalized thermoelastic micropolar honeycomb medium

Abstract

Keywords

Get full access to this article

References