High-order sandwich beam theory is used to model the local deformation unde
r the central indentor for sandwich beams loaded under three-point bending.
'High-order' refers to the non-linear variations of in-plane and vertical
displacements through the height of the core which the model incorporates.
The analysis is elastic, which is appropriate to describe the beam response
up to peak load for the material combination of GFRP skins and Nomex honey
comb core which is the focus of this paper. Reasonable agreement is found b
etween theoretical predictions of the displacement field under the indentor
and experimental measurements using a beam with GFRP skins and Nomex honey
comb core. By using the model to consider the way in which different wavele
ngths of sinusoidal pressure loading on the top skin are transmitted to the
core, a spreading length scale lambda is introduced. lambda, which is a fu
nction of the beam material and geometric properties, characterises the len
gth over which a load on the top surface of a beam is spread out by the ski
n. Calculations of the effect of roller diameter on indentation behaviour i
llustrate the importance of this length scale. When lambda is small compare
d with the roller radius R, corresponding to a flexible skin, the contact l
oad at the roller-skin interface is transmitted relatively unchanged to the
core. Conversely, when lambda/R is greater than about 0.25, corresponding
to a relatively rigid skin, the load from the roller is spread out by the s
kin and the pressure in the core is distributed over a length of the order
of lambda. (C) 1999 Elsevier Science Ltd. All rights reserved.