I'm not a big fan of this and other flexural test methods (ASTM or otherwise); they're pretty much only good for quality control or as in intermediate step for validating an FEA modelling approach before going to larger scale tests. I've performed this test and other similar tests as a student, and continue to come across students using tests like these on composite sandwich panels who want to know why they don't see the results/behaviour they expected. As an example of one of the many issues with such tests that I reckon will be of particular note (based on what you've said about your panel):
1. Assuming a standard prepreg ply thickness of 0.125mm; you've got a pretty thin skin on a comparatively thick core. Consequently, the rollers on your test rig will readily indent into you panels; this is particularly problematic for four point bending as at a fairly low load, the indentation of the rollers will be sufficient for them to constrain the deformation of your panel. At this point you will see your panel become a lot stiffer.
To check this for yourself; put a strain gauge on the top and bottom surface between the two central rollers. Initially, they will both record increasing strain with load/displacement. Once the the rollers start to indent into the panel you will see the reading in the strain gauge on the compressive surface drop towards zero while the tensile gauge continues to record increasing strain. When the rollers start to interact with the panel in this way, the compressive skin in the panel essentially becomes the neutral axis of bending; hence the apparent (and artificial) increase in panel stiffness.
Back to your specific points
trish129 said:
1.what information do these three properties convey about a particular sandwich PREPARED by given fabrication process(oven,autoclaceve)?
^Not much.
trish129 said:
1.what information do these three properties convey about a particular sandwich PREPARED by given fabrication process(oven,autoclaeve)?
Once again; not much.
I appreciate that my above two comments are not particularly helpful, so:
If you're looking to compare the performance of panel made in an autoclave vs out-of-'clave then I'd suggest that starting with a sandwich panel test is not the way to go. Assuming you're using the same prepreg processed with, and without, an autoclave then there are a number of differences to consider, including:
1) Volume fraction (Vf); this will be higher in the autoclaved panel. This will increase the moduli and strength of the laminate, but the laminate will be a bit thinner. Potential for reduction in fatigue life and or strain to transverse tensile failure in resin.
2) Increased porosity in out-of-clave samples; probably won't make much difference in one-off tests of your laminate but can be very significant when it comes to fatigue/damage.
3) Fibres in your laminate will bend/curve slightly inwards between cells in your honeycomb. This will knock down laminate performance with the result that laminates produced on a caul plate without a honeycomb core will outperform the laminates that make up the skin of your sandwich panel. In order to get an idea of the effect of this you could start by curing a laminate (not necessarily the one you've described) by itself and also cure the same laminate on the honeycomb core but with a layer of peel ply between the skin and core so that you can remove the skin from the core for testing; then do some of the standard battery of test methods for composite laminates to get an idea of the knockdown in performance the laminate will exhibit. Compressive failure of laminates with misalignment is a non-trivial matter and there are almost as many opinions on this as there are academic papers on the subject....caveat emptor.
Anyway, ^a few points to consider.... composite materials make things much more complicated on the experimental side as well as the numerical side.
