Hi Robert
You’re welcome.
Doing this in my spare time over Christmas and New Year has been a bit problematic, so bear with me as I try to answer your questions in part.
As I am working with data generated on the other side of “The Pond” from you, there may be differences in approach and possibly conservatism in some areas and optimism in others wherever their testing and analysis has led them to reach different conclusions. The data that I’m using comes from a long-established and very experienced “Methods Group” that pools their information with others across this continent, very much like the US, but perhaps on a more formal level. Like you, I have been raised on US data and methods and when I find anomalies in others’ work I chase after them until I’m satisfied with their validity. However, in this case, I have not had the time to chase the lug analysis differences yet, but will get there eventually. I can only assume that the variance in the Kty line originates from different test data. I did notice the discrepancy between my data and that of Bruhn and, when in doubt, would use the more conservative one.
Lugs located in critical locations, and loaded up to the theoretical limit of their strength, are usually thoroughly tested for static strength and fatigue endurance before they go into service. From the description of your application, it sounds like you have a once-off crash case condition on a cabin interior structure or similar, so your approach is good.
I do know that the Methods Group (that generated the data I used) works very closely with a neighbouring university and related research centre that is world renowned for their testing of fastener joints, including single pin-jointed ones. In addition, my recent experience in determining fastener joint yield values from tests has been scattered, to say the least, and may account for the discrepancies between the D1.15 curve and the one I have. The local tendency is to use yield values and factor them up by 1.5, but also check the ultimate allowable value and then use the lesser of the two. This works particularly well when determining allowables for fastened joints.
Lugs work at their best when they only carry axial load and often designs try to align the structure to ensure that the lug works as close to this condition as possible. Recent sustaining work experience has shown that some aircraft designs go so far as to align separate axial lugs side by side with one another to carry what would have been the axial and transverse loads on a single lug. This allows for fail-safe DT design of the joint and also allows the lugs to work together optimally when intact.
In all the company manuals I have seen, only one actually produces guidelines for setting up the cantilever analysis of one side of the lug. From the quadratic shape of the curve I suspect that the Ftu curve has been based on a single cantilever beam analysis using fixed relationships between ultimate, yield and bearing values. The transverse load analysis is a complex mixture of the classical fastener “edge distance” problem (pin shear-out) combined with various stiffness variations of 2 parallel cantilevers joined by the lug “hoop” that provides the connection at the “free end” of the cantilevers. Obviously thin hoop lugs, i.e. small e/D values cannot provide the same coupling between the upper and lower cantilevers as would a lug with a thick hoop or high e/D value.
Ed
