The approach in the presentation for addressing fuselage bending effects is certainly a valid one but very conservative and I believe was only presented as a simple approach. It does obviously meet the FAA requirements but generally results in very very short inspection intervals which is not very good for the operators.
As always, you get what you pay for. If a conservative, short and inexpensive FAA compliant DTA is required, then certainly one could use the approach. However, the operator ends up paying in the end when he ends up doing a LFEC every 1500 hours on a simple antenna installation. So its really "Pay me now, or pay me later". This approach may be acceptable for GA but on an airliner, this would be tough indeed on the operators where aircraft accumulate 2000 to 3000 hours a year. The typical goal for an inspection interval for a commercial airliner should be at the very least a C check. Not sure the method presented can ever achieve this.
Just for example, consider a fuselage barrel with 2024 skin, 8.6 psi internal pressure, 74 inch fuselage radius and 0.05 inch thick skin. Per the presentation, here is the resulting 1G stress = 14.8 ksi. Now, assume a typical delta Nz of 0.25(very typical for a once per flight basis) and add in pressure. The total stress is now 24.85 ksi! How many cycles does one think this will really last at 24.85 ksi per flight? Particularly when a normal DSG is around at least 30,000 cycles.
The best approach that I have found is also the tougher one but the proper one. If one is to embark on performing DTA's, they should also be experienced in developing fatigue loads as well as performing crack growth and this should be expected of them. One without the other results in a lobsided approach. In this vain, I have seen many good engineers go to great lengths to select their crack growth methodology, the specific material data used, speciliazed stress intensity solutions to only end up making a globalized general assumption about the most important of all effects --- stress ---. If an antenna/repair/mod is placed in an area that is affected by fuselage bending, then a fuselage bending spectrum must be developed. This is not difficult if the engineer is an experienced DT analyst. The FAA has published many load history exceedance tables for taxi, landing, gust, maneuver, etc. for numerous commercial aircraft. In turn, any well experienced DTA engineer should be able to develop balanced aircraft fatigue loads and correlate them. With these two, a fairly representative fatigue spectrum can be developed, it only requires experience and time. No quick boot-strap solutions here. DTA is not something that is learned over nite and requires good training and mentoring from the old gray beards. As a quick aside and obviously in my own opinion, here are the key areas which an experienced DTA engineer should be experienced in:
Static Strength Analysis (strong understanding of primary structure)
Fatigue Loads Development(internal and external)
Spectrum Development (mission profiles, block spectra,flightbyflight spectra,randomization,etc.)
Stress Life and Strain Life Methods
Material Characterization (dadN,toughness,Rcurves,etc.)
Stress Concentrations and Stress Intensity Solutions
Retardation Effects
Crack Growth Rate Methodologies
Inspection Methods
Probabilities of Detection and Detectable Flaws
NDT Procedures
Ok, I am now officially stepping down from my soapbox.
Best of luck.
