In recent years, fiber-reinforced composites have become more accepted for aerospace applications. Specifically, during NASA s recent efforts to develop new launch vehicles, composite materials were considered and baselined for a number of structures. Because of mass and stiffness requirements, sandwich composites are often selected for many applications. However, there are a number of manufacturing and in-service concerns associated with traditional honeycomb-core sandwich composites that in certain instances may be alleviated through the use of other core materials or construction methods. Fluted-core, which consists of integral angled web members with structural radius fillers spaced between laminate face sheets, is one such construction alternative and is considered herein. Two different fluted-core designs were considered: a subscale design and a full-scale design sized for a heavy-lift-launch-vehicle interstage. In particular, axial compression of fluted-core composites was evaluated with experiments and finite-element analyses (FEA); axial compression is the primary loading condition in dry launch-vehicle barrel sections. Detailed finite-element models were developed to represent all components of the fluted-core construction, and geometrically nonlinear analyses were conducted to predict both buckling and material failures. Good agreement was obtained between test data and analyses, for both local buckling and ultimate material failure. Though the local buckling events are not catastrophic, the resulting deformations contribute to material failures. Consequently, an important observation is that the material failure loads and modes would not be captured by either linear analyses or nonlinear smeared-shell analyses. Compression-after-impact (CAI) performance of fluted core composites was also investigated by experimentally testing samples impacted with 6 ft.-lb. impact energies. It was found that such impacts reduced the ultimate load carrying capability by approximately 40% on the subscale test articles and by less than 20% on the full-scale test articles. Nondestructive inspection of the damage zones indicated that the detectable damage was limited to no more than one flute on either side of any given impact. More study is needed, but this may indicate that an inherent damage-arrest capability of fluted core could provide benefits over traditional sandwich designs in certain weight-critical applications.
[1]
D. Jegley.
A study of the structural efficiency of fluted core graphite-epoxy panels
,
1990
.
[2]
Raphael T. Haftka,et al.
Micromechanical Analysis of Composite Corrugated-Core Sandwich Panels for Integral Thermal Protection Systems
,
2007
.
[3]
Tat-Seng Lok,et al.
Elastic Stiffness Properties and Behavior of Truss-Core Sandwich Panel
,
2000
.
[4]
M. Robinson,et al.
COMPOSITE MATERIAL COMPATIBILITY WITH LIQUID AND GASEOUS OXYGEN
,
2001
.
[5]
Raphael T. Haftka,et al.
Homogenization of Plates with Microsctructure and Application to Corrugated Core Sandwich Panels
,
2010
.
[6]
J. Craig McArthur.
Ares I Crew Launch Vehicle Upper Stage Element Overview
,
2008
.
[7]
P. Seide.
The stability under longitudinal compression of flat symmetric corrugated-core sandwich plates with simply supported loaded edges and simply supported or clamped unloaded edges
,
1952
.
[8]
C. Libove,et al.
Elastic Constants for Corrugated-Core Sandwich Plates
,
1951
.
[9]
Ajay P. Kothari,et al.
A Reusable, Rocket and Airbreathing Combined Cycle Hypersonic Vehicle Design for Access-to-Space
,
2010
.
[10]
Wan-Shu Chang,et al.
Bending behavior of corrugated-core sandwich plates
,
2005
.
[11]
Maureen Hand,et al.
Trade Study Results for a Second-Generation Reusable Launch Vehicle Composite Hydrogen Tank
,
2004
.
[12]
Steve Creech,et al.
Ares V: Overview and Status
,
2009
.
[13]
Kirtland Afb,et al.
Experiment Overview and Flight Results Summary From The Vibro Acoustic Launch Protection Experiment (VALPE)
,
2004
.